INTRODUCTION AND MOTIVATION
The exponential growth of scientific literature, academic papers, books, and online articles has created an information overload problem for researchers, students, and professionals. When someone wants to learn about a specific subject area such as quantum computing, generative artificial intelligence, machine learning, or even specialized topics like rose cultivation or Python programming, they face the challenge of sifting through thousands of potentially relevant resources to find the most authoritative and useful materials.
An LLM-based intelligent agent can solve this problem by automating the discovery, evaluation, and recommendation of relevant learning resources. Such an agent combines the natural language understanding capabilities of large language models with web search functionality, content analysis, and intelligent filtering to provide curated recommendations tailored to the user's specified subject area.
This article presents a comprehensive guide to building such an agent from the ground up. We will explore the architectural components, implementation details, and practical considerations necessary to create a production-ready system that can serve real users with diverse research needs.
ARCHITECTURAL OVERVIEW AND SYSTEM DESIGN
The intelligent research agent consists of several interconnected components that work together to transform a user's subject query into a curated list of recommended resources. Understanding the architecture is crucial before diving into implementation details.
The core components include a user interface layer that accepts subject queries, an LLM orchestration layer that manages the language model interactions, a web search integration layer that retrieves candidate resources from the internet, a content analysis and ranking system that evaluates the quality and relevance of discovered resources, and a presentation layer that formats and delivers recommendations to the user.
The system follows a pipeline architecture where each stage processes and enriches the data before passing it to the next stage. This design promotes modularity, testability, and maintainability while allowing for parallel processing where appropriate.
A critical design decision involves supporting both local and remote LLM deployments. Local deployment offers privacy, cost control, and reduced latency but requires significant computational resources. Remote deployment through API services provides easier setup and automatic scaling but incurs ongoing costs and potential privacy concerns. Our architecture accommodates both approaches through abstraction layers.
Supporting multiple GPU architectures including NVIDIA CUDA, AMD ROCm, Intel GPUs, and Apple Metal Performance Shaders ensures the system can run on diverse hardware configurations. This cross-platform compatibility is achieved through careful selection of underlying libraries and conditional code paths.
LLM INTEGRATION AND ABSTRACTION LAYER
The foundation of our agent is the ability to interact with large language models in a flexible, hardware-agnostic manner. We create an abstraction layer that provides a unified interface regardless of whether the LLM runs locally or remotely, and regardless of the underlying GPU architecture.
The abstraction layer defines a common interface that all LLM providers must implement. This interface includes methods for generating text completions, streaming responses, and managing conversation context. By programming against this interface rather than specific implementations, we can swap LLM backends without modifying the higher-level agent logic.
For local LLM deployment, we leverage libraries that support multiple GPU backends. The llama-cpp-python library provides bindings to llama.cpp, which has been optimized for various hardware architectures. It automatically detects available GPU acceleration and uses the appropriate backend whether that is CUDA for NVIDIA, ROCm for AMD, Metal for Apple Silicon, or Vulkan for Intel GPUs.
Here is a foundational code example showing the LLM abstraction interface:
from abc import ABC, abstractmethod
from typing import List, Dict, Optional, Iterator
from dataclasses import dataclass
@dataclass
class Message:
"""Represents a single message in a conversation."""
role: str # 'system', 'user', or 'assistant'
content: str
class LLMProvider(ABC):
"""Abstract base class for all LLM providers."""
@abstractmethod
def generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> str:
"""
Generate a completion given a list of messages.
Args:
messages: Conversation history as a list of Message objects
max_tokens: Maximum number of tokens to generate
temperature: Sampling temperature for randomness control
Returns:
Generated text as a string
"""
pass
@abstractmethod
def stream_generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> Iterator[str]:
"""
Generate a completion with streaming output.
Args:
messages: Conversation history as a list of Message objects
max_tokens: Maximum number of tokens to generate
temperature: Sampling temperature for randomness control
Yields:
Text chunks as they are generated
"""
pass
@abstractmethod
def get_model_info(self) -> Dict[str, str]:
"""
Retrieve information about the loaded model.
Returns:
Dictionary containing model name, version, and capabilities
"""
pass
This interface provides the contract that all concrete LLM implementations must fulfill. The Message dataclass encapsulates the structure of conversation turns, making it easy to build multi-turn dialogues. The generate method handles synchronous completion generation, while stream_generate enables real-time streaming of responses for better user experience with long outputs.
Now we implement a concrete provider for local LLM execution using llama-cpp-python:
from llama_cpp import Llama
import os
from typing import List, Iterator
class LocalLLMProvider(LLMProvider):
"""LLM provider for locally-hosted models using llama.cpp."""
def __init__(self, model_path: str, n_gpu_layers: int = -1,
n_ctx: int = 4096, verbose: bool = False):
"""
Initialize the local LLM provider.
Args:
model_path: Path to the GGUF model file
n_gpu_layers: Number of layers to offload to GPU (-1 for all)
n_ctx: Context window size in tokens
verbose: Whether to print detailed loading information
"""
if not os.path.exists(model_path):
raise FileNotFoundError(f"Model file not found: {model_path}")
# Initialize llama.cpp with automatic GPU detection
# It will use CUDA, ROCm, Metal, or Vulkan depending on availability
self.llm = Llama(
model_path=model_path,
n_gpu_layers=n_gpu_layers,
n_ctx=n_ctx,
verbose=verbose,
n_threads=os.cpu_count() or 4
)
self.model_path = model_path
self.context_size = n_ctx
def generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> str:
"""Generate a completion from the local model."""
# Convert Message objects to llama.cpp format
formatted_messages = [
{"role": msg.role, "content": msg.content}
for msg in messages
]
# Generate completion
response = self.llm.create_chat_completion(
messages=formatted_messages,
max_tokens=max_tokens,
temperature=temperature,
stream=False
)
# Extract the generated text
return response['choices'][0]['message']['content']
def stream_generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> Iterator[str]:
"""Generate a streaming completion from the local model."""
formatted_messages = [
{"role": msg.role, "content": msg.content}
for msg in messages
]
# Create streaming completion
stream = self.llm.create_chat_completion(
messages=formatted_messages,
max_tokens=max_tokens,
temperature=temperature,
stream=True
)
# Yield chunks as they arrive
for chunk in stream:
delta = chunk['choices'][0]['delta']
if 'content' in delta:
yield delta['content']
def get_model_info(self) -> Dict[str, str]:
"""Return information about the loaded model."""
return {
'provider': 'local_llama_cpp',
'model_path': self.model_path,
'context_size': str(self.context_size),
'gpu_layers': 'auto-detected'
}
The LocalLLMProvider implementation handles the complexity of GPU detection and model loading. The llama-cpp-python library automatically detects available GPU acceleration and configures itself accordingly. When n_gpu_layers is set to negative one, all compatible layers are offloaded to the GPU for maximum performance. The library's build system includes support for CUDA, ROCm, Metal, and Vulkan, so the same code works across different hardware platforms.
For remote LLM access, we implement a provider that communicates with API services such as OpenAI, Anthropic, or other compatible endpoints:
import requests
import json
from typing import List, Iterator, Optional
class RemoteLLMProvider(LLMProvider):
"""LLM provider for remote API-based models."""
def __init__(self, api_key: str, api_base: str = "https://api.openai.com/v1",
model_name: str = "gpt-4", timeout: int = 120):
"""
Initialize the remote LLM provider.
Args:
api_key: API authentication key
api_base: Base URL for the API endpoint
model_name: Name of the model to use
timeout: Request timeout in seconds
"""
self.api_key = api_key
self.api_base = api_base.rstrip('/')
self.model_name = model_name
self.timeout = timeout
self.session = requests.Session()
self.session.headers.update({
'Authorization': f'Bearer {api_key}',
'Content-Type': 'application/json'
})
def generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> str:
"""Generate a completion from the remote API."""
# Prepare the request payload
payload = {
'model': self.model_name,
'messages': [
{'role': msg.role, 'content': msg.content}
for msg in messages
],
'max_tokens': max_tokens,
'temperature': temperature,
'stream': False
}
# Make the API request
response = self.session.post(
f'{self.api_base}/chat/completions',
json=payload,
timeout=self.timeout
)
# Handle errors
if response.status_code != 200:
raise Exception(f"API request failed: {response.status_code} - {response.text}")
# Parse and return the response
result = response.json()
return result['choices'][0]['message']['content']
def stream_generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> Iterator[str]:
"""Generate a streaming completion from the remote API."""
payload = {
'model': self.model_name,
'messages': [
{'role': msg.role, 'content': msg.content}
for msg in messages
],
'max_tokens': max_tokens,
'temperature': temperature,
'stream': True
}
# Make streaming request
response = self.session.post(
f'{self.api_base}/chat/completions',
json=payload,
timeout=self.timeout,
stream=True
)
if response.status_code != 200:
raise Exception(f"API request failed: {response.status_code}")
# Process the streaming response
for line in response.iter_lines():
if not line:
continue
line_text = line.decode('utf-8')
if not line_text.startswith('data: '):
continue
data_str = line_text[6:] # Remove 'data: ' prefix
if data_str.strip() == '[DONE]':
break
try:
data = json.loads(data_str)
delta = data['choices'][0]['delta']
if 'content' in delta:
yield delta['content']
except json.JSONDecodeError:
continue
def get_model_info(self) -> Dict[str, str]:
"""Return information about the remote model."""
return {
'provider': 'remote_api',
'model_name': self.model_name,
'api_base': self.api_base
}
The RemoteLLMProvider handles the intricacies of HTTP communication with remote API endpoints. It manages authentication, request formatting, error handling, and streaming response parsing. The implementation uses a persistent session to reuse connections and improve performance across multiple requests.
With both local and remote providers implemented, we create a factory function that instantiates the appropriate provider based on configuration:
from typing import Union
from enum import Enum
class LLMBackend(Enum):
"""Enumeration of supported LLM backends."""
LOCAL = "local"
REMOTE = "remote"
def create_llm_provider(backend: Union[LLMBackend, str],
**kwargs) -> LLMProvider:
"""
Factory function to create the appropriate LLM provider.
Args:
backend: The backend type (LOCAL or REMOTE)
**kwargs: Backend-specific configuration parameters
Returns:
Configured LLMProvider instance
Example for local:
provider = create_llm_provider(
LLMBackend.LOCAL,
model_path="/path/to/model.gguf",
n_gpu_layers=-1
)
Example for remote:
provider = create_llm_provider(
LLMBackend.REMOTE,
api_key="sk-...",
model_name="gpt-4"
)
"""
if isinstance(backend, str):
backend = LLMBackend(backend.lower())
if backend == LLMBackend.LOCAL:
required_params = ['model_path']
for param in required_params:
if param not in kwargs:
raise ValueError(f"Missing required parameter for local backend: {param}")
return LocalLLMProvider(**kwargs)
elif backend == LLMBackend.REMOTE:
required_params = ['api_key']
for param in required_params:
if param not in kwargs:
raise ValueError(f"Missing required parameter for remote backend: {param}")
return RemoteLLMProvider(**kwargs)
else:
raise ValueError(f"Unsupported backend: {backend}")
This factory pattern provides a clean interface for creating LLM providers without exposing the implementation details to the rest of the application. The caller simply specifies the desired backend type and provides the necessary configuration parameters.
WEB SEARCH INTEGRATION AND CONTENT RETRIEVAL
The next critical component is the ability to search the internet for relevant resources. We need to query search engines, retrieve results, and extract useful information from web pages. This involves integrating with search APIs and implementing robust web scraping capabilities.
For search functionality, we can use several approaches. The most straightforward is to integrate with established search APIs such as Google Custom Search, Bing Search API, or DuckDuckGo. Each has different pricing models, rate limits, and result quality characteristics. For production systems, using multiple search providers with fallback logic improves reliability.
Here is an implementation of a search abstraction layer with support for multiple providers:
from abc import ABC, abstractmethod
from dataclasses import dataclass
from typing import List, Optional
import requests
from urllib.parse import quote_plus
@dataclass
class SearchResult:
"""Represents a single search result."""
title: str
url: str
snippet: str
source: str # The search provider that returned this result
class SearchProvider(ABC):
"""Abstract base class for search providers."""
@abstractmethod
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""
Execute a search query and return results.
Args:
query: The search query string
num_results: Maximum number of results to return
Returns:
List of SearchResult objects
"""
pass
class DuckDuckGoSearchProvider(SearchProvider):
"""Search provider using DuckDuckGo's HTML interface."""
def __init__(self, timeout: int = 30):
"""
Initialize the DuckDuckGo search provider.
Args:
timeout: Request timeout in seconds
"""
self.timeout = timeout
self.session = requests.Session()
self.session.headers.update({
'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'
})
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Execute a DuckDuckGo search."""
from bs4 import BeautifulSoup
# DuckDuckGo HTML search endpoint
url = f"https://html.duckduckgo.com/html/?q={quote_plus(query)}"
try:
response = self.session.get(url, timeout=self.timeout)
response.raise_for_status()
except requests.RequestException as e:
raise Exception(f"DuckDuckGo search failed: {str(e)}")
# Parse the HTML response
soup = BeautifulSoup(response.text, 'html.parser')
results = []
# Find all result divs
result_divs = soup.find_all('div', class_='result')
for div in result_divs[:num_results]:
# Extract title and URL
title_elem = div.find('a', class_='result__a')
if not title_elem:
continue
title = title_elem.get_text(strip=True)
url = title_elem.get('href', '')
# Extract snippet
snippet_elem = div.find('a', class_='result__snippet')
snippet = snippet_elem.get_text(strip=True) if snippet_elem else ''
if url and title:
results.append(SearchResult(
title=title,
url=url,
snippet=snippet,
source='duckduckgo'
))
return results
class BingSearchProvider(SearchProvider):
"""Search provider using Bing Search API."""
def __init__(self, api_key: str, timeout: int = 30):
"""
Initialize the Bing search provider.
Args:
api_key: Bing Search API key
timeout: Request timeout in seconds
"""
self.api_key = api_key
self.timeout = timeout
self.endpoint = "https://api.bing.microsoft.com/v7.0/search"
self.session = requests.Session()
self.session.headers.update({
'Ocp-Apim-Subscription-Key': api_key
})
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Execute a Bing search."""
params = {
'q': query,
'count': num_results,
'textDecorations': False,
'textFormat': 'Raw'
}
try:
response = self.session.get(
self.endpoint,
params=params,
timeout=self.timeout
)
response.raise_for_status()
except requests.RequestException as e:
raise Exception(f"Bing search failed: {str(e)}")
data = response.json()
results = []
# Parse web pages results
if 'webPages' in data and 'value' in data['webPages']:
for item in data['webPages']['value']:
results.append(SearchResult(
title=item.get('name', ''),
url=item.get('url', ''),
snippet=item.get('snippet', ''),
source='bing'
))
return results
The search abstraction provides a unified interface for querying different search engines. The DuckDuckGoSearchProvider uses web scraping since DuckDuckGo offers a simple HTML interface that does not require API keys. The BingSearchProvider uses the official Bing Search API which requires a subscription key but provides more reliable and structured results.
To enhance the search capabilities specifically for academic and scientific content, we implement a specialized provider that queries academic databases:
class ScholarSearchProvider(SearchProvider):
"""Search provider for academic papers and scholarly articles."""
def __init__(self, timeout: int = 30):
"""
Initialize the scholar search provider.
Args:
timeout: Request timeout in seconds
"""
self.timeout = timeout
self.session = requests.Session()
self.session.headers.update({
'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'
})
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""
Search for scholarly articles using Google Scholar.
Note: This is a simplified implementation. Production systems should
use official APIs or services like Semantic Scholar API, arXiv API, etc.
"""
from bs4 import BeautifulSoup
# Google Scholar search URL
url = f"https://scholar.google.com/scholar?q={quote_plus(query)}&hl=en&num={num_results}"
try:
response = self.session.get(url, timeout=self.timeout)
response.raise_for_status()
except requests.RequestException as e:
raise Exception(f"Scholar search failed: {str(e)}")
soup = BeautifulSoup(response.text, 'html.parser')
results = []
# Find all result divs
result_divs = soup.find_all('div', class_='gs_ri')
for div in result_divs[:num_results]:
# Extract title
title_elem = div.find('h3', class_='gs_rt')
if not title_elem:
continue
# Remove citation markers
for cite in title_elem.find_all('span', class_='gs_ct1'):
cite.decompose()
for cite in title_elem.find_all('span', class_='gs_ct2'):
cite.decompose()
title_link = title_elem.find('a')
title = title_link.get_text(strip=True) if title_link else title_elem.get_text(strip=True)
url = title_link.get('href', '') if title_link else ''
# Extract snippet
snippet_elem = div.find('div', class_='gs_rs')
snippet = snippet_elem.get_text(strip=True) if snippet_elem else ''
if title:
results.append(SearchResult(
title=title,
url=url,
snippet=snippet,
source='google_scholar'
))
return results
The ScholarSearchProvider specifically targets academic content by querying Google Scholar. This is particularly valuable when users are researching scientific or technical topics where peer-reviewed papers and academic publications are the most authoritative sources.
Now we implement a multi-provider search aggregator that queries multiple search engines and combines their results:
from typing import Set
from concurrent.futures import ThreadPoolExecutor, as_completed
class AggregatedSearchProvider(SearchProvider):
"""Aggregates results from multiple search providers."""
def __init__(self, providers: List[SearchProvider], max_workers: int = 3):
"""
Initialize the aggregated search provider.
Args:
providers: List of SearchProvider instances to query
max_workers: Maximum number of concurrent search requests
"""
self.providers = providers
self.max_workers = max_workers
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""
Execute searches across all providers and aggregate results.
Results are deduplicated by URL and ranked by frequency across providers.
"""
all_results = []
seen_urls: Set[str] = set()
# Execute searches in parallel
with ThreadPoolExecutor(max_workers=self.max_workers) as executor:
# Submit search tasks
future_to_provider = {
executor.submit(provider.search, query, num_results): provider
for provider in self.providers
}
# Collect results as they complete
for future in as_completed(future_to_provider):
provider = future_to_provider[future]
try:
results = future.result()
# Add unique results
for result in results:
if result.url and result.url not in seen_urls:
seen_urls.add(result.url)
all_results.append(result)
except Exception as e:
# Log the error but continue with other providers
print(f"Search provider {provider.__class__.__name__} failed: {str(e)}")
continue
# Return top results
return all_results[:num_results]
The AggregatedSearchProvider executes searches across multiple providers concurrently using a thread pool. This parallelization significantly reduces total search time compared to sequential execution. The results are deduplicated by URL to avoid showing the same resource multiple times.
With search capabilities in place, we need to retrieve and extract content from the discovered web pages. This involves fetching HTML content, parsing it, and extracting the main textual content while filtering out navigation, advertisements, and other non-essential elements:
from bs4 import BeautifulSoup
import requests
from typing import Optional, Dict
from urllib.parse import urlparse
class ContentExtractor:
"""Extracts main content from web pages."""
def __init__(self, timeout: int = 30, max_content_length: int = 50000):
"""
Initialize the content extractor.
Args:
timeout: Request timeout in seconds
max_content_length: Maximum content length to extract in characters
"""
self.timeout = timeout
self.max_content_length = max_content_length
self.session = requests.Session()
self.session.headers.update({
'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'
})
def extract(self, url: str) -> Optional[Dict[str, str]]:
"""
Extract main content from a URL.
Args:
url: The URL to extract content from
Returns:
Dictionary with 'title', 'content', and 'url' keys, or None if extraction fails
"""
try:
response = self.session.get(url, timeout=self.timeout)
response.raise_for_status()
except requests.RequestException as e:
print(f"Failed to fetch {url}: {str(e)}")
return None
# Parse HTML
soup = BeautifulSoup(response.text, 'html.parser')
# Remove script and style elements
for element in soup(['script', 'style', 'nav', 'footer', 'header', 'aside']):
element.decompose()
# Extract title
title = ''
title_tag = soup.find('title')
if title_tag:
title = title_tag.get_text(strip=True)
# Try to find main content area
main_content = None
# Look for common main content containers
for selector in ['main', 'article', '[role="main"]', '.content', '#content']:
main_content = soup.select_one(selector)
if main_content:
break
# If no main content found, use body
if not main_content:
main_content = soup.find('body')
if not main_content:
return None
# Extract text content
text = main_content.get_text(separator=' ', strip=True)
# Clean up whitespace
text = ' '.join(text.split())
# Truncate if too long
if len(text) > self.max_content_length:
text = text[:self.max_content_length] + '...'
return {
'title': title,
'content': text,
'url': url
}
def extract_metadata(self, url: str) -> Dict[str, str]:
"""
Extract metadata from a web page.
Args:
url: The URL to extract metadata from
Returns:
Dictionary containing available metadata fields
"""
try:
response = self.session.get(url, timeout=self.timeout)
response.raise_for_status()
except requests.RequestException:
return {}
soup = BeautifulSoup(response.text, 'html.parser')
metadata = {}
# Extract Open Graph metadata
for meta in soup.find_all('meta', property=True):
prop = meta.get('property', '')
if prop.startswith('og:'):
key = prop[3:] # Remove 'og:' prefix
metadata[key] = meta.get('content', '')
# Extract standard meta tags
for meta in soup.find_all('meta', attrs={'name': True}):
name = meta.get('name', '')
if name in ['description', 'author', 'keywords', 'published_time']:
metadata[name] = meta.get('content', '')
return metadata
The ContentExtractor class handles the complexity of retrieving web pages and extracting their main content. It removes common non-content elements like scripts, styles, and navigation components. The extraction logic looks for semantic HTML5 elements like main and article tags, which typically contain the primary content. The extract_metadata method retrieves additional information from meta tags, which can be useful for determining the type and quality of the resource.
CONTENT ANALYSIS AND RELEVANCE RANKING
Once we have retrieved search results and their content, we need to analyze and rank them based on relevance to the user's query and overall quality. This is where the LLM's natural language understanding capabilities become crucial.
The analysis process involves several steps. First, we use the LLM to assess how well each resource matches the user's specified subject area. Second, we evaluate the quality and authority of the source. Third, we categorize the resource type such as academic paper, tutorial, book, or general article. Finally, we combine these factors into an overall relevance score.
Here is an implementation of the content analyzer:
from typing import List, Dict, Tuple
from dataclasses import dataclass, field
from enum import Enum
class ResourceType(Enum):
"""Types of learning resources."""
ACADEMIC_PAPER = "academic_paper"
BOOK = "book"
TUTORIAL = "tutorial"
ARTICLE = "article"
DOCUMENTATION = "documentation"
VIDEO = "video"
COURSE = "course"
UNKNOWN = "unknown"
@dataclass
class AnalyzedResource:
"""Represents an analyzed and scored resource."""
title: str
url: str
snippet: str
resource_type: ResourceType
relevance_score: float # 0.0 to 1.0
quality_score: float # 0.0 to 1.0
reasoning: str
metadata: Dict[str, str] = field(default_factory=dict)
@property
def overall_score(self) -> float:
"""Calculate overall score as weighted combination."""
return 0.6 * self.relevance_score + 0.4 * self.quality_score
class ContentAnalyzer:
"""Analyzes and ranks content using LLM capabilities."""
def __init__(self, llm_provider: LLMProvider):
"""
Initialize the content analyzer.
Args:
llm_provider: The LLM provider to use for analysis
"""
self.llm = llm_provider
def analyze_resource(self, search_result: SearchResult,
content: Optional[str], subject: str) -> AnalyzedResource:
"""
Analyze a single resource for relevance and quality.
Args:
search_result: The search result to analyze
content: Extracted content from the URL (if available)
subject: The subject area the user is researching
Returns:
AnalyzedResource with scores and classification
"""
# Build analysis prompt
analysis_text = f"Title: {search_result.title}\n"
analysis_text += f"URL: {search_result.url}\n"
analysis_text += f"Snippet: {search_result.snippet}\n"
if content:
# Use first 2000 characters of content for analysis
content_preview = content[:2000]
analysis_text += f"Content preview: {content_preview}\n"
prompt = self._build_analysis_prompt(analysis_text, subject)
# Get LLM analysis
messages = [
Message(role='system', content='You are an expert research assistant that evaluates the relevance and quality of learning resources.'),
Message(role='user', content=prompt)
]
try:
response = self.llm.generate(messages, max_tokens=500, temperature=0.3)
# Parse the structured response
scores = self._parse_analysis_response(response)
return AnalyzedResource(
title=search_result.title,
url=search_result.url,
snippet=search_result.snippet,
resource_type=scores['resource_type'],
relevance_score=scores['relevance_score'],
quality_score=scores['quality_score'],
reasoning=scores['reasoning']
)
except Exception as e:
# If analysis fails, return with default scores
print(f"Analysis failed for {search_result.url}: {str(e)}")
return AnalyzedResource(
title=search_result.title,
url=search_result.url,
snippet=search_result.snippet,
resource_type=ResourceType.UNKNOWN,
relevance_score=0.5,
quality_score=0.5,
reasoning="Analysis failed; using default scores"
)
def _build_analysis_prompt(self, resource_info: str, subject: str) -> str:
"""Build the prompt for resource analysis."""
prompt = f"""Analyze the following resource for a user researching "{subject}".
{resource_info}
Provide your analysis in the following structured format:
RESOURCE_TYPE: [one of: academic_paper, book, tutorial, article, documentation, video, course, unknown]
RELEVANCE_SCORE: [0.0 to 1.0, where 1.0 means highly relevant to the subject]
QUALITY_SCORE: [0.0 to 1.0, where 1.0 means high quality and authoritative]
REASONING: [brief explanation of your scores]
Consider these factors:
- How well does the resource match the subject area?
- Is it from an authoritative source?
- Is it comprehensive and well-structured?
- Is it suitable for learning about the subject?
"""
return prompt
def _parse_analysis_response(self, response: str) -> Dict:
"""Parse the structured analysis response from the LLM."""
lines = response.strip().split('\n')
result = {
'resource_type': ResourceType.UNKNOWN,
'relevance_score': 0.5,
'quality_score': 0.5,
'reasoning': ''
}
for line in lines:
line = line.strip()
if line.startswith('RESOURCE_TYPE:'):
type_str = line.split(':', 1)[1].strip().lower()
try:
result['resource_type'] = ResourceType(type_str)
except ValueError:
result['resource_type'] = ResourceType.UNKNOWN
elif line.startswith('RELEVANCE_SCORE:'):
try:
score = float(line.split(':', 1)[1].strip())
result['relevance_score'] = max(0.0, min(1.0, score))
except ValueError:
pass
elif line.startswith('QUALITY_SCORE:'):
try:
score = float(line.split(':', 1)[1].strip())
result['quality_score'] = max(0.0, min(1.0, score))
except ValueError:
pass
elif line.startswith('REASONING:'):
result['reasoning'] = line.split(':', 1)[1].strip()
return result
def batch_analyze(self, search_results: List[SearchResult],
subject: str, extractor: ContentExtractor,
max_workers: int = 5) -> List[AnalyzedResource]:
"""
Analyze multiple resources in parallel.
Args:
search_results: List of search results to analyze
subject: The subject area being researched
extractor: ContentExtractor instance for fetching page content
max_workers: Maximum number of parallel analysis tasks
Returns:
List of AnalyzedResource objects sorted by overall score
"""
from concurrent.futures import ThreadPoolExecutor, as_completed
analyzed_resources = []
with ThreadPoolExecutor(max_workers=max_workers) as executor:
# Submit analysis tasks
future_to_result = {}
for result in search_results:
# Extract content in parallel
future = executor.submit(self._analyze_with_content,
result, subject, extractor)
future_to_result[future] = result
# Collect results
for future in as_completed(future_to_result):
try:
analyzed = future.result()
analyzed_resources.append(analyzed)
except Exception as e:
result = future_to_result[future]
print(f"Failed to analyze {result.url}: {str(e)}")
# Sort by overall score
analyzed_resources.sort(key=lambda x: x.overall_score, reverse=True)
return analyzed_resources
def _analyze_with_content(self, search_result: SearchResult,
subject: str, extractor: ContentExtractor) -> AnalyzedResource:
"""Helper method to extract content and analyze."""
# Try to extract content
extracted = extractor.extract(search_result.url)
content = extracted['content'] if extracted else None
# Analyze the resource
return self.analyze_resource(search_result, content, subject)
The ContentAnalyzer leverages the LLM to perform sophisticated analysis of each resource. The analysis prompt asks the LLM to evaluate multiple dimensions including relevance to the subject, quality and authority of the source, and resource type classification. The structured output format makes it easy to parse the LLM's response and extract numerical scores.
The batch_analyze method processes multiple resources in parallel, which is crucial for performance when analyzing dozens of search results. Each resource is analyzed independently, allowing for efficient parallelization.
RECOMMENDATION GENERATION AND PRESENTATION
With analyzed and ranked resources, the final step is to generate comprehensive recommendations that help the user understand why each resource was selected and how it relates to their research topic. This involves synthesizing the analysis results into a coherent narrative.
Here is the implementation of the recommendation generator:
from typing import List, Dict
class RecommendationGenerator:
"""Generates structured recommendations from analyzed resources."""
def __init__(self, llm_provider: LLMProvider):
"""
Initialize the recommendation generator.
Args:
llm_provider: The LLM provider for generating descriptions
"""
self.llm = llm_provider
def generate_recommendations(self, analyzed_resources: List[AnalyzedResource],
subject: str, max_recommendations: int = 10) -> str:
"""
Generate a comprehensive recommendation report.
Args:
analyzed_resources: List of analyzed resources sorted by score
subject: The subject area being researched
max_recommendations: Maximum number of resources to include
Returns:
Formatted recommendation text
"""
# Take top resources
top_resources = analyzed_resources[:max_recommendations]
# Group by resource type
grouped = self._group_by_type(top_resources)
# Generate introduction
intro = self._generate_introduction(subject, len(top_resources))
# Generate sections for each resource type
sections = []
type_order = [
ResourceType.ACADEMIC_PAPER,
ResourceType.BOOK,
ResourceType.COURSE,
ResourceType.TUTORIAL,
ResourceType.DOCUMENTATION,
ResourceType.ARTICLE,
ResourceType.VIDEO,
ResourceType.UNKNOWN
]
for resource_type in type_order:
if resource_type in grouped and grouped[resource_type]:
section = self._generate_type_section(
resource_type,
grouped[resource_type],
subject
)
sections.append(section)
# Combine all parts
report = intro + '\n\n'
report += '\n\n'.join(sections)
report += '\n\n' + self._generate_conclusion(subject)
return report
def _group_by_type(self, resources: List[AnalyzedResource]) -> Dict[ResourceType, List[AnalyzedResource]]:
"""Group resources by their type."""
grouped = {}
for resource in resources:
if resource.resource_type not in grouped:
grouped[resource.resource_type] = []
grouped[resource.resource_type].append(resource)
return grouped
def _generate_introduction(self, subject: str, num_resources: int) -> str:
"""Generate an introduction for the recommendations."""
prompt = f"""Write a brief introduction (2-3 sentences) for a curated list of {num_resources} learning resources about "{subject}".
The introduction should welcome the user and explain that these resources have been carefully selected and analyzed for relevance and quality."""
messages = [
Message(role='system', content='You are a helpful research assistant.'),
Message(role='user', content=prompt)
]
return self.llm.generate(messages, max_tokens=200, temperature=0.7)
def _generate_type_section(self, resource_type: ResourceType,
resources: List[AnalyzedResource],
subject: str) -> str:
"""Generate a section for a specific resource type."""
# Section header
type_names = {
ResourceType.ACADEMIC_PAPER: 'Academic Papers and Research',
ResourceType.BOOK: 'Books',
ResourceType.COURSE: 'Online Courses',
ResourceType.TUTORIAL: 'Tutorials and Guides',
ResourceType.DOCUMENTATION: 'Documentation',
ResourceType.ARTICLE: 'Articles and Blog Posts',
ResourceType.VIDEO: 'Video Resources',
ResourceType.UNKNOWN: 'Additional Resources'
}
section = f"=== {type_names.get(resource_type, 'Resources')} ===\n\n"
# Add each resource
for i, resource in enumerate(resources, 1):
section += f"{i}. {resource.title}\n"
section += f" URL: {resource.url}\n"
section += f" Relevance: {resource.relevance_score:.2f} | Quality: {resource.quality_score:.2f}\n"
section += f" {resource.reasoning}\n\n"
return section
def _generate_conclusion(self, subject: str) -> str:
"""Generate a conclusion for the recommendations."""
prompt = f"""Write a brief conclusion (2-3 sentences) for a curated list of learning resources about "{subject}".
Encourage the user to explore these resources and mention that they can request more specific recommendations if needed."""
messages = [
Message(role='system', content='You are a helpful research assistant.'),
Message(role='user', content=prompt)
]
return self.llm.generate(messages, max_tokens=200, temperature=0.7)
The RecommendationGenerator creates a well-structured report that organizes resources by type and provides clear explanations for each recommendation. The grouping by resource type helps users quickly find the kind of material they prefer, whether that is academic papers for deep technical understanding or tutorials for hands-on learning.
ORCHESTRATING THE COMPLETE AGENT WORKFLOW
Now we bring all the components together into a cohesive agent that manages the entire workflow from receiving a user query to delivering recommendations:
from typing import Optional, List
import logging
class ResearchAgent:
"""Main agent that orchestrates the research and recommendation process."""
def __init__(self, llm_provider: LLMProvider,
search_provider: SearchProvider,
content_extractor: ContentExtractor,
content_analyzer: ContentAnalyzer,
recommendation_generator: RecommendationGenerator,
logger: Optional[logging.Logger] = None):
"""
Initialize the research agent.
Args:
llm_provider: LLM provider for language understanding
search_provider: Search provider for finding resources
content_extractor: Extractor for retrieving page content
content_analyzer: Analyzer for evaluating resources
recommendation_generator: Generator for creating recommendations
logger: Optional logger for tracking operations
"""
self.llm = llm_provider
self.search = search_provider
self.extractor = content_extractor
self.analyzer = content_analyzer
self.recommender = recommendation_generator
self.logger = logger or logging.getLogger(__name__)
def research(self, subject: str, num_results: int = 20,
max_recommendations: int = 10) -> str:
"""
Execute the complete research workflow.
Args:
subject: The subject area to research
num_results: Number of search results to retrieve
max_recommendations: Maximum recommendations to generate
Returns:
Formatted recommendation report
"""
self.logger.info(f"Starting research for subject: {subject}")
# Step 1: Enhance the search query using LLM
enhanced_query = self._enhance_query(subject)
self.logger.info(f"Enhanced query: {enhanced_query}")
# Step 2: Search for resources
self.logger.info(f"Searching for {num_results} resources...")
search_results = self.search.search(enhanced_query, num_results)
self.logger.info(f"Found {len(search_results)} search results")
if not search_results:
return f"No resources found for subject: {subject}"
# Step 3: Analyze and rank resources
self.logger.info("Analyzing resources...")
analyzed_resources = self.analyzer.batch_analyze(
search_results,
subject,
self.extractor
)
self.logger.info(f"Analyzed {len(analyzed_resources)} resources")
# Step 4: Generate recommendations
self.logger.info("Generating recommendations...")
recommendations = self.recommender.generate_recommendations(
analyzed_resources,
subject,
max_recommendations
)
self.logger.info("Research complete")
return recommendations
def _enhance_query(self, subject: str) -> str:
"""
Use LLM to enhance the search query for better results.
Args:
subject: The original subject from the user
Returns:
Enhanced search query string
"""
prompt = f"""Given the subject "{subject}", generate an optimized search query that will find high-quality learning resources including books, academic papers, tutorials, and articles.
The query should:
- Include relevant technical terms and synonyms
- Be concise but comprehensive
- Focus on authoritative and educational content
Provide only the search query, nothing else."""
messages = [
Message(role='system', content='You are an expert at formulating effective search queries.'),
Message(role='user', content=prompt)
]
enhanced = self.llm.generate(messages, max_tokens=100, temperature=0.5)
return enhanced.strip()
def interactive_research(self):
"""
Run an interactive research session where the user can make multiple queries.
"""
print("Research Agent - Interactive Mode")
print("=" * 50)
print("Enter a subject area to research, or 'quit' to exit.\n")
while True:
subject = input("Subject: ").strip()
if subject.lower() in ['quit', 'exit', 'q']:
print("Goodbye!")
break
if not subject:
print("Please enter a valid subject.\n")
continue
try:
print("\nResearching... This may take a minute.\n")
recommendations = self.research(subject)
print(recommendations)
print("\n" + "=" * 50 + "\n")
except Exception as e:
print(f"Error during research: {str(e)}\n")
self.logger.error(f"Research failed: {str(e)}", exc_info=True)
The ResearchAgent class serves as the main entry point for the system. It coordinates all the components and manages the workflow from query to recommendations. The research method implements the complete pipeline: query enhancement, search execution, content analysis, and recommendation generation. The interactive_research method provides a simple command-line interface for users to make multiple queries in a session.
CONFIGURATION MANAGEMENT AND INITIALIZATION
A production system needs robust configuration management to handle different deployment scenarios, API keys, model paths, and other settings. Here is a configuration system that supports multiple environments:
from dataclasses import dataclass
from typing import Optional
import os
import json
@dataclass
class LLMConfig:
"""Configuration for LLM provider."""
backend: str # 'local' or 'remote'
model_path: Optional[str] = None # For local models
api_key: Optional[str] = None # For remote APIs
api_base: Optional[str] = None
model_name: Optional[str] = None
n_gpu_layers: int = -1
n_ctx: int = 4096
@dataclass
class SearchConfig:
"""Configuration for search providers."""
providers: List[str] # e.g., ['duckduckgo', 'bing']
bing_api_key: Optional[str] = None
timeout: int = 30
@dataclass
class AgentConfig:
"""Main configuration for the research agent."""
llm: LLMConfig
search: SearchConfig
max_search_results: int = 20
max_recommendations: int = 10
content_timeout: int = 30
max_content_length: int = 50000
log_level: str = 'INFO'
@classmethod
def from_file(cls, config_path: str) -> 'AgentConfig':
"""Load configuration from a JSON file."""
with open(config_path, 'r') as f:
data = json.load(f)
llm_config = LLMConfig(**data['llm'])
search_config = SearchConfig(**data['search'])
return cls(
llm=llm_config,
search=search_config,
max_search_results=data.get('max_search_results', 20),
max_recommendations=data.get('max_recommendations', 10),
content_timeout=data.get('content_timeout', 30),
max_content_length=data.get('max_content_length', 50000),
log_level=data.get('log_level', 'INFO')
)
@classmethod
def from_env(cls) -> 'AgentConfig':
"""Load configuration from environment variables."""
llm_backend = os.getenv('LLM_BACKEND', 'local')
llm_config = LLMConfig(
backend=llm_backend,
model_path=os.getenv('LLM_MODEL_PATH'),
api_key=os.getenv('LLM_API_KEY'),
api_base=os.getenv('LLM_API_BASE'),
model_name=os.getenv('LLM_MODEL_NAME'),
n_gpu_layers=int(os.getenv('LLM_GPU_LAYERS', '-1')),
n_ctx=int(os.getenv('LLM_CONTEXT_SIZE', '4096'))
)
search_providers = os.getenv('SEARCH_PROVIDERS', 'duckduckgo').split(',')
search_config = SearchConfig(
providers=search_providers,
bing_api_key=os.getenv('BING_API_KEY'),
timeout=int(os.getenv('SEARCH_TIMEOUT', '30'))
)
return cls(
llm=llm_config,
search=search_config,
max_search_results=int(os.getenv('MAX_SEARCH_RESULTS', '20')),
max_recommendations=int(os.getenv('MAX_RECOMMENDATIONS', '10')),
content_timeout=int(os.getenv('CONTENT_TIMEOUT', '30')),
log_level=os.getenv('LOG_LEVEL', 'INFO')
)
def create_agent_from_config(config: AgentConfig) -> ResearchAgent:
"""
Factory function to create a fully configured ResearchAgent.
Args:
config: AgentConfig instance with all settings
Returns:
Configured ResearchAgent ready to use
"""
# Setup logging
logging.basicConfig(
level=getattr(logging, config.log_level),
format='%(asctime)s - %(name)s - %(levelname)s - %(message)s'
)
logger = logging.getLogger('ResearchAgent')
# Create LLM provider
if config.llm.backend == 'local':
llm_provider = create_llm_provider(
LLMBackend.LOCAL,
model_path=config.llm.model_path,
n_gpu_layers=config.llm.n_gpu_layers,
n_ctx=config.llm.n_ctx
)
else:
llm_provider = create_llm_provider(
LLMBackend.REMOTE,
api_key=config.llm.api_key,
api_base=config.llm.api_base,
model_name=config.llm.model_name
)
# Create search providers
search_providers = []
for provider_name in config.search.providers:
if provider_name.lower() == 'duckduckgo':
search_providers.append(DuckDuckGoSearchProvider(timeout=config.search.timeout))
elif provider_name.lower() == 'bing' and config.search.bing_api_key:
search_providers.append(BingSearchProvider(
api_key=config.search.bing_api_key,
timeout=config.search.timeout
))
elif provider_name.lower() == 'scholar':
search_providers.append(ScholarSearchProvider(timeout=config.search.timeout))
# Create aggregated search provider
search_provider = AggregatedSearchProvider(search_providers)
# Create content extractor
content_extractor = ContentExtractor(
timeout=config.content_timeout,
max_content_length=config.max_content_length
)
# Create content analyzer
content_analyzer = ContentAnalyzer(llm_provider)
# Create recommendation generator
recommendation_generator = RecommendationGenerator(llm_provider)
# Create and return the agent
return ResearchAgent(
llm_provider=llm_provider,
search_provider=search_provider,
content_extractor=content_extractor,
content_analyzer=content_analyzer,
recommendation_generator=recommendation_generator,
logger=logger
)
The configuration system supports both file-based and environment variable-based configuration, making it flexible for different deployment scenarios. The create_agent_from_config factory function handles all the complexity of instantiating and wiring together the various components based on the configuration.
ERROR HANDLING AND RESILIENCE
Production systems must handle errors gracefully and continue operating even when individual components fail. We implement comprehensive error handling and retry logic:
from functools import wraps
import time
from typing import Callable, Any
def retry_on_failure(max_attempts: int = 3, delay: float = 1.0,
backoff: float = 2.0):
"""
Decorator that retries a function on failure with exponential backoff.
Args:
max_attempts: Maximum number of retry attempts
delay: Initial delay between retries in seconds
backoff: Multiplier for delay after each attempt
"""
def decorator(func: Callable) -> Callable:
@wraps(func)
def wrapper(*args, **kwargs) -> Any:
current_delay = delay
last_exception = None
for attempt in range(max_attempts):
try:
return func(*args, **kwargs)
except Exception as e:
last_exception = e
if attempt < max_attempts - 1:
time.sleep(current_delay)
current_delay *= backoff
else:
raise last_exception
raise last_exception
return wrapper
return decorator
class ResilientSearchProvider(SearchProvider):
"""Search provider wrapper with error handling and fallback."""
def __init__(self, primary: SearchProvider,
fallback: Optional[SearchProvider] = None):
"""
Initialize resilient search provider.
Args:
primary: Primary search provider to use
fallback: Optional fallback provider if primary fails
"""
self.primary = primary
self.fallback = fallback
@retry_on_failure(max_attempts=2, delay=1.0)
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Search with automatic fallback on failure."""
try:
return self.primary.search(query, num_results)
except Exception as e:
if self.fallback:
print(f"Primary search failed, using fallback: {str(e)}")
return self.fallback.search(query, num_results)
else:
raise
The retry decorator implements exponential backoff for transient failures, which is particularly important for network operations. The ResilientSearchProvider wraps search providers with fallback logic, ensuring that the system can continue operating even if one search provider fails.
PERFORMANCE OPTIMIZATION AND CACHING
For production use, we need to optimize performance and reduce redundant operations. Implementing caching for search results and content extraction significantly improves response times for repeated queries:
from functools import lru_cache
import hashlib
import pickle
import os
from typing import Optional
class CachedContentExtractor(ContentExtractor):
"""Content extractor with disk-based caching."""
def __init__(self, cache_dir: str = '.cache', **kwargs):
"""
Initialize cached content extractor.
Args:
cache_dir: Directory to store cached content
**kwargs: Arguments passed to ContentExtractor
"""
super().__init__(**kwargs)
self.cache_dir = cache_dir
os.makedirs(cache_dir, exist_ok=True)
def _get_cache_path(self, url: str) -> str:
"""Generate cache file path for a URL."""
url_hash = hashlib.md5(url.encode()).hexdigest()
return os.path.join(self.cache_dir, f"{url_hash}.pkl")
def extract(self, url: str) -> Optional[Dict[str, str]]:
"""Extract content with caching."""
cache_path = self._get_cache_path(url)
# Check cache
if os.path.exists(cache_path):
try:
with open(cache_path, 'rb') as f:
return pickle.load(f)
except Exception:
pass # Cache read failed, fetch fresh
# Fetch fresh content
content = super().extract(url)
# Cache the result
if content:
try:
with open(cache_path, 'wb') as f:
pickle.dump(content, f)
except Exception:
pass # Cache write failed, not critical
return content
class SearchResultCache:
"""Cache for search results with TTL support."""
def __init__(self, cache_dir: str = '.cache', ttl_hours: int = 24):
"""
Initialize search result cache.
Args:
cache_dir: Directory to store cached results
ttl_hours: Time-to-live for cached results in hours
"""
self.cache_dir = os.path.join(cache_dir, 'search')
self.ttl_seconds = ttl_hours * 3600
os.makedirs(self.cache_dir, exist_ok=True)
def _get_cache_key(self, query: str, num_results: int) -> str:
"""Generate cache key for a query."""
key_str = f"{query}:{num_results}"
return hashlib.md5(key_str.encode()).hexdigest()
def get(self, query: str, num_results: int) -> Optional[List[SearchResult]]:
"""Retrieve cached search results if available and fresh."""
cache_key = self._get_cache_key(query, num_results)
cache_path = os.path.join(self.cache_dir, f"{cache_key}.pkl")
if not os.path.exists(cache_path):
return None
# Check if cache is still fresh
cache_age = time.time() - os.path.getmtime(cache_path)
if cache_age > self.ttl_seconds:
return None
try:
with open(cache_path, 'rb') as f:
return pickle.load(f)
except Exception:
return None
def set(self, query: str, num_results: int, results: List[SearchResult]):
"""Cache search results."""
cache_key = self._get_cache_key(query, num_results)
cache_path = os.path.join(self.cache_dir, f"{cache_key}.pkl")
try:
with open(cache_path, 'wb') as f:
pickle.dump(results, f)
except Exception:
pass # Cache write failed, not critical
class CachedSearchProvider(SearchProvider):
"""Search provider wrapper with caching."""
def __init__(self, provider: SearchProvider, cache: SearchResultCache):
"""
Initialize cached search provider.
Args:
provider: Underlying search provider
cache: Cache instance to use
"""
self.provider = provider
self.cache = cache
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Search with caching."""
# Check cache first
cached = self.cache.get(query, num_results)
if cached is not None:
return cached
# Fetch fresh results
results = self.provider.search(query, num_results)
# Cache the results
self.cache.set(query, num_results, results)
return results
The caching implementations use disk-based storage to persist results across sessions. The SearchResultCache includes time-to-live functionality to ensure that cached results do not become stale. This is particularly important for rapidly changing topics where new resources are frequently published.
MONITORING AND OBSERVABILITY
Production systems require monitoring to track performance, identify issues, and understand usage patterns. We implement comprehensive logging and metrics collection:
from dataclasses import dataclass
from datetime import datetime
from typing import Dict, List
import json
@dataclass
class ResearchMetrics:
"""Metrics for a research operation."""
subject: str
start_time: datetime
end_time: Optional[datetime] = None
search_results_count: int = 0
analyzed_resources_count: int = 0
recommendations_count: int = 0
errors: List[str] = None
def __post_init__(self):
if self.errors is None:
self.errors = []
@property
def duration_seconds(self) -> float:
"""Calculate operation duration in seconds."""
if self.end_time:
return (self.end_time - self.start_time).total_seconds()
return 0.0
def to_dict(self) -> Dict:
"""Convert metrics to dictionary for serialization."""
return {
'subject': self.subject,
'start_time': self.start_time.isoformat(),
'end_time': self.end_time.isoformat() if self.end_time else None,
'duration_seconds': self.duration_seconds,
'search_results_count': self.search_results_count,
'analyzed_resources_count': self.analyzed_resources_count,
'recommendations_count': self.recommendations_count,
'errors': self.errors
}
class MetricsCollector:
"""Collects and persists metrics for research operations."""
def __init__(self, metrics_file: str = 'metrics.jsonl'):
"""
Initialize metrics collector.
Args:
metrics_file: Path to file for storing metrics
"""
self.metrics_file = metrics_file
def record(self, metrics: ResearchMetrics):
"""Record metrics to file."""
with open(self.metrics_file, 'a') as f:
f.write(json.dumps(metrics.to_dict()) + '\n')
def get_statistics(self) -> Dict:
"""Calculate aggregate statistics from recorded metrics."""
if not os.path.exists(self.metrics_file):
return {}
total_operations = 0
total_duration = 0.0
total_results = 0
total_errors = 0
with open(self.metrics_file, 'r') as f:
for line in f:
try:
data = json.loads(line)
total_operations += 1
total_duration += data.get('duration_seconds', 0)
total_results += data.get('search_results_count', 0)
total_errors += len(data.get('errors', []))
except json.JSONDecodeError:
continue
if total_operations == 0:
return {}
return {
'total_operations': total_operations,
'average_duration_seconds': total_duration / total_operations,
'average_results_per_operation': total_results / total_operations,
'total_errors': total_errors,
'error_rate': total_errors / total_operations
}
class MonitoredResearchAgent(ResearchAgent):
"""Research agent with integrated metrics collection."""
def __init__(self, metrics_collector: MetricsCollector, **kwargs):
"""
Initialize monitored research agent.
Args:
metrics_collector: MetricsCollector instance
**kwargs: Arguments passed to ResearchAgent
"""
super().__init__(**kwargs)
self.metrics = metrics_collector
def research(self, subject: str, num_results: int = 20,
max_recommendations: int = 10) -> str:
"""Execute research with metrics collection."""
# Initialize metrics
operation_metrics = ResearchMetrics(
subject=subject,
start_time=datetime.now()
)
try:
# Execute research
result = super().research(subject, num_results, max_recommendations)
# Record success metrics
operation_metrics.end_time = datetime.now()
operation_metrics.search_results_count = num_results
operation_metrics.recommendations_count = max_recommendations
return result
except Exception as e:
# Record error
operation_metrics.end_time = datetime.now()
operation_metrics.errors.append(str(e))
raise
finally:
# Always record metrics
self.metrics.record(operation_metrics)
The metrics collection system tracks key performance indicators for each research operation including duration, result counts, and errors. This data enables operators to identify performance bottlenecks, track error rates, and understand usage patterns over time.
FULL PRODUCTION-READY RUNNING EXAMPLE
Now we present a complete, production-ready implementation that integrates all the components discussed above. This example can handle any subject area query and provides a robust, scalable solution.
#!/usr/bin/env python3
"""
Research Agent - Production Implementation
A complete LLM-based agent for discovering and recommending learning resources
across any subject area. Supports local and remote LLMs with multiple GPU
architectures (NVIDIA CUDA, AMD ROCm, Intel, Apple MPS).
Usage:
python research_agent.py --config config.json
python research_agent.py --subject "Quantum Computing"
"""
import argparse
import sys
import os
import logging
from abc import ABC, abstractmethod
from dataclasses import dataclass, field
from typing import List, Dict, Optional, Iterator, Union, Set, Any, Callable
from enum import Enum
import requests
import json
import hashlib
import pickle
import time
from datetime import datetime
from functools import wraps
from concurrent.futures import ThreadPoolExecutor, as_completed
from urllib.parse import quote_plus, urlparse
# Try to import optional dependencies
try:
from llama_cpp import Llama
LLAMA_CPP_AVAILABLE = True
except ImportError:
LLAMA_CPP_AVAILABLE = False
print("Warning: llama-cpp-python not available. Local LLM support disabled.")
try:
from bs4 import BeautifulSoup
BS4_AVAILABLE = True
except ImportError:
BS4_AVAILABLE = False
print("Warning: beautifulsoup4 not available. Web scraping disabled.")
# ============================================================================
# Core Data Structures
# ============================================================================
@dataclass
class Message:
"""Represents a single message in a conversation."""
role: str # 'system', 'user', or 'assistant'
content: str
@dataclass
class SearchResult:
"""Represents a single search result."""
title: str
url: str
snippet: str
source: str
class ResourceType(Enum):
"""Types of learning resources."""
ACADEMIC_PAPER = "academic_paper"
BOOK = "book"
TUTORIAL = "tutorial"
ARTICLE = "article"
DOCUMENTATION = "documentation"
VIDEO = "video"
COURSE = "course"
UNKNOWN = "unknown"
@dataclass
class AnalyzedResource:
"""Represents an analyzed and scored resource."""
title: str
url: str
snippet: str
resource_type: ResourceType
relevance_score: float
quality_score: float
reasoning: str
metadata: Dict[str, str] = field(default_factory=dict)
@property
def overall_score(self) -> float:
"""Calculate overall score as weighted combination."""
return 0.6 * self.relevance_score + 0.4 * self.quality_score
@dataclass
class ResearchMetrics:
"""Metrics for a research operation."""
subject: str
start_time: datetime
end_time: Optional[datetime] = None
search_results_count: int = 0
analyzed_resources_count: int = 0
recommendations_count: int = 0
errors: List[str] = field(default_factory=list)
@property
def duration_seconds(self) -> float:
"""Calculate operation duration in seconds."""
if self.end_time:
return (self.end_time - self.start_time).total_seconds()
return 0.0
def to_dict(self) -> Dict:
"""Convert metrics to dictionary for serialization."""
return {
'subject': self.subject,
'start_time': self.start_time.isoformat(),
'end_time': self.end_time.isoformat() if self.end_time else None,
'duration_seconds': self.duration_seconds,
'search_results_count': self.search_results_count,
'analyzed_resources_count': self.analyzed_resources_count,
'recommendations_count': self.recommendations_count,
'errors': self.errors
}
# ============================================================================
# Configuration
# ============================================================================
@dataclass
class LLMConfig:
"""Configuration for LLM provider."""
backend: str
model_path: Optional[str] = None
api_key: Optional[str] = None
api_base: Optional[str] = None
model_name: Optional[str] = None
n_gpu_layers: int = -1
n_ctx: int = 4096
@dataclass
class SearchConfig:
"""Configuration for search providers."""
providers: List[str]
bing_api_key: Optional[str] = None
timeout: int = 30
@dataclass
class AgentConfig:
"""Main configuration for the research agent."""
llm: LLMConfig
search: SearchConfig
max_search_results: int = 20
max_recommendations: int = 10
content_timeout: int = 30
max_content_length: int = 50000
log_level: str = 'INFO'
cache_enabled: bool = True
cache_dir: str = '.cache'
cache_ttl_hours: int = 24
metrics_enabled: bool = True
metrics_file: str = 'metrics.jsonl'
@classmethod
def from_file(cls, config_path: str) -> 'AgentConfig':
"""Load configuration from a JSON file."""
with open(config_path, 'r') as f:
data = json.load(f)
llm_config = LLMConfig(**data['llm'])
search_config = SearchConfig(**data['search'])
return cls(
llm=llm_config,
search=search_config,
max_search_results=data.get('max_search_results', 20),
max_recommendations=data.get('max_recommendations', 10),
content_timeout=data.get('content_timeout', 30),
max_content_length=data.get('max_content_length', 50000),
log_level=data.get('log_level', 'INFO'),
cache_enabled=data.get('cache_enabled', True),
cache_dir=data.get('cache_dir', '.cache'),
cache_ttl_hours=data.get('cache_ttl_hours', 24),
metrics_enabled=data.get('metrics_enabled', True),
metrics_file=data.get('metrics_file', 'metrics.jsonl')
)
@classmethod
def from_env(cls) -> 'AgentConfig':
"""Load configuration from environment variables."""
llm_backend = os.getenv('LLM_BACKEND', 'local')
llm_config = LLMConfig(
backend=llm_backend,
model_path=os.getenv('LLM_MODEL_PATH'),
api_key=os.getenv('LLM_API_KEY'),
api_base=os.getenv('LLM_API_BASE'),
model_name=os.getenv('LLM_MODEL_NAME'),
n_gpu_layers=int(os.getenv('LLM_GPU_LAYERS', '-1')),
n_ctx=int(os.getenv('LLM_CONTEXT_SIZE', '4096'))
)
search_providers = os.getenv('SEARCH_PROVIDERS', 'duckduckgo').split(',')
search_config = SearchConfig(
providers=search_providers,
bing_api_key=os.getenv('BING_API_KEY'),
timeout=int(os.getenv('SEARCH_TIMEOUT', '30'))
)
return cls(
llm=llm_config,
search=search_config,
max_search_results=int(os.getenv('MAX_SEARCH_RESULTS', '20')),
max_recommendations=int(os.getenv('MAX_RECOMMENDATIONS', '10')),
content_timeout=int(os.getenv('CONTENT_TIMEOUT', '30')),
log_level=os.getenv('LOG_LEVEL', 'INFO'),
cache_enabled=os.getenv('CACHE_ENABLED', 'true').lower() == 'true',
cache_dir=os.getenv('CACHE_DIR', '.cache'),
cache_ttl_hours=int(os.getenv('CACHE_TTL_HOURS', '24')),
metrics_enabled=os.getenv('METRICS_ENABLED', 'true').lower() == 'true',
metrics_file=os.getenv('METRICS_FILE', 'metrics.jsonl')
)
# ============================================================================
# Utility Functions and Decorators
# ============================================================================
def retry_on_failure(max_attempts: int = 3, delay: float = 1.0,
backoff: float = 2.0):
"""
Decorator that retries a function on failure with exponential backoff.
Args:
max_attempts: Maximum number of retry attempts
delay: Initial delay between retries in seconds
backoff: Multiplier for delay after each attempt
"""
def decorator(func: Callable) -> Callable:
@wraps(func)
def wrapper(*args, **kwargs) -> Any:
current_delay = delay
last_exception = None
for attempt in range(max_attempts):
try:
return func(*args, **kwargs)
except Exception as e:
last_exception = e
if attempt < max_attempts - 1:
time.sleep(current_delay)
current_delay *= backoff
raise last_exception
return wrapper
return decorator
# ============================================================================
# LLM Provider Abstraction
# ============================================================================
class LLMProvider(ABC):
"""Abstract base class for all LLM providers."""
@abstractmethod
def generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> str:
"""Generate a completion given a list of messages."""
pass
@abstractmethod
def stream_generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> Iterator[str]:
"""Generate a completion with streaming output."""
pass
@abstractmethod
def get_model_info(self) -> Dict[str, str]:
"""Retrieve information about the loaded model."""
pass
class LocalLLMProvider(LLMProvider):
"""LLM provider for locally-hosted models using llama.cpp."""
def __init__(self, model_path: str, n_gpu_layers: int = -1,
n_ctx: int = 4096, verbose: bool = False):
"""
Initialize the local LLM provider.
Args:
model_path: Path to the GGUF model file
n_gpu_layers: Number of layers to offload to GPU (-1 for all)
n_ctx: Context window size in tokens
verbose: Whether to print detailed loading information
"""
if not LLAMA_CPP_AVAILABLE:
raise ImportError("llama-cpp-python is required for local LLM support")
if not os.path.exists(model_path):
raise FileNotFoundError(f"Model file not found: {model_path}")
self.llm = Llama(
model_path=model_path,
n_gpu_layers=n_gpu_layers,
n_ctx=n_ctx,
verbose=verbose,
n_threads=os.cpu_count() or 4
)
self.model_path = model_path
self.context_size = n_ctx
def generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> str:
"""Generate a completion from the local model."""
formatted_messages = [
{"role": msg.role, "content": msg.content}
for msg in messages
]
response = self.llm.create_chat_completion(
messages=formatted_messages,
max_tokens=max_tokens,
temperature=temperature,
stream=False
)
return response['choices'][0]['message']['content']
def stream_generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> Iterator[str]:
"""Generate a streaming completion from the local model."""
formatted_messages = [
{"role": msg.role, "content": msg.content}
for msg in messages
]
stream = self.llm.create_chat_completion(
messages=formatted_messages,
max_tokens=max_tokens,
temperature=temperature,
stream=True
)
for chunk in stream:
delta = chunk['choices'][0]['delta']
if 'content' in delta:
yield delta['content']
def get_model_info(self) -> Dict[str, str]:
"""Return information about the loaded model."""
return {
'provider': 'local_llama_cpp',
'model_path': self.model_path,
'context_size': str(self.context_size),
'gpu_layers': 'auto-detected'
}
class RemoteLLMProvider(LLMProvider):
"""LLM provider for remote API-based models."""
def __init__(self, api_key: str, api_base: str = "https://api.openai.com/v1",
model_name: str = "gpt-4", timeout: int = 120):
"""
Initialize the remote LLM provider.
Args:
api_key: API authentication key
api_base: Base URL for the API endpoint
model_name: Name of the model to use
timeout: Request timeout in seconds
"""
self.api_key = api_key
self.api_base = api_base.rstrip('/')
self.model_name = model_name
self.timeout = timeout
self.session = requests.Session()
self.session.headers.update({
'Authorization': f'Bearer {api_key}',
'Content-Type': 'application/json'
})
@retry_on_failure(max_attempts=3, delay=1.0)
def generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> str:
"""Generate a completion from the remote API."""
payload = {
'model': self.model_name,
'messages': [
{'role': msg.role, 'content': msg.content}
for msg in messages
],
'max_tokens': max_tokens,
'temperature': temperature,
'stream': False
}
response = self.session.post(
f'{self.api_base}/chat/completions',
json=payload,
timeout=self.timeout
)
if response.status_code != 200:
raise Exception(f"API request failed: {response.status_code} - {response.text}")
result = response.json()
return result['choices'][0]['message']['content']
def stream_generate(self, messages: List[Message], max_tokens: int = 2048,
temperature: float = 0.7) -> Iterator[str]:
"""Generate a streaming completion from the remote API."""
payload = {
'model': self.model_name,
'messages': [
{'role': msg.role, 'content': msg.content}
for msg in messages
],
'max_tokens': max_tokens,
'temperature': temperature,
'stream': True
}
response = self.session.post(
f'{self.api_base}/chat/completions',
json=payload,
timeout=self.timeout,
stream=True
)
if response.status_code != 200:
raise Exception(f"API request failed: {response.status_code}")
for line in response.iter_lines():
if not line:
continue
line_text = line.decode('utf-8')
if not line_text.startswith('data: '):
continue
data_str = line_text[6:]
if data_str.strip() == '[DONE]':
break
try:
data = json.loads(data_str)
delta = data['choices'][0]['delta']
if 'content' in delta:
yield delta['content']
except json.JSONDecodeError:
continue
def get_model_info(self) -> Dict[str, str]:
"""Return information about the remote model."""
return {
'provider': 'remote_api',
'model_name': self.model_name,
'api_base': self.api_base
}
class LLMBackend(Enum):
"""Enumeration of supported LLM backends."""
LOCAL = "local"
REMOTE = "remote"
def create_llm_provider(backend: Union[LLMBackend, str],
**kwargs) -> LLMProvider:
"""Factory function to create the appropriate LLM provider."""
if isinstance(backend, str):
backend = LLMBackend(backend.lower())
if backend == LLMBackend.LOCAL:
required_params = ['model_path']
for param in required_params:
if param not in kwargs:
raise ValueError(f"Missing required parameter for local backend: {param}")
return LocalLLMProvider(**kwargs)
elif backend == LLMBackend.REMOTE:
required_params = ['api_key']
for param in required_params:
if param not in kwargs:
raise ValueError(f"Missing required parameter for remote backend: {param}")
return RemoteLLMProvider(**kwargs)
else:
raise ValueError(f"Unsupported backend: {backend}")
# ============================================================================
# Search Provider Abstraction
# ============================================================================
class SearchProvider(ABC):
"""Abstract base class for search providers."""
@abstractmethod
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Execute a search query and return results."""
pass
class DuckDuckGoSearchProvider(SearchProvider):
"""Search provider using DuckDuckGo's HTML interface."""
def __init__(self, timeout: int = 30):
"""Initialize the DuckDuckGo search provider."""
if not BS4_AVAILABLE:
raise ImportError("beautifulsoup4 is required for DuckDuckGo search")
self.timeout = timeout
self.session = requests.Session()
self.session.headers.update({
'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'
})
@retry_on_failure(max_attempts=2)
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Execute a DuckDuckGo search."""
url = f"https://html.duckduckgo.com/html/?q={quote_plus(query)}"
response = self.session.get(url, timeout=self.timeout)
response.raise_for_status()
soup = BeautifulSoup(response.text, 'html.parser')
results = []
result_divs = soup.find_all('div', class_='result')
for div in result_divs[:num_results]:
title_elem = div.find('a', class_='result__a')
if not title_elem:
continue
title = title_elem.get_text(strip=True)
url = title_elem.get('href', '')
snippet_elem = div.find('a', class_='result__snippet')
snippet = snippet_elem.get_text(strip=True) if snippet_elem else ''
if url and title:
results.append(SearchResult(
title=title,
url=url,
snippet=snippet,
source='duckduckgo'
))
return results
class BingSearchProvider(SearchProvider):
"""Search provider using Bing Search API."""
def __init__(self, api_key: str, timeout: int = 30):
"""Initialize the Bing search provider."""
self.api_key = api_key
self.timeout = timeout
self.endpoint = "https://api.bing.microsoft.com/v7.0/search"
self.session = requests.Session()
self.session.headers.update({
'Ocp-Apim-Subscription-Key': api_key
})
@retry_on_failure(max_attempts=2)
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Execute a Bing search."""
params = {
'q': query,
'count': num_results,
'textDecorations': False,
'textFormat': 'Raw'
}
response = self.session.get(
self.endpoint,
params=params,
timeout=self.timeout
)
response.raise_for_status()
data = response.json()
results = []
if 'webPages' in data and 'value' in data['webPages']:
for item in data['webPages']['value']:
results.append(SearchResult(
title=item.get('name', ''),
url=item.get('url', ''),
snippet=item.get('snippet', ''),
source='bing'
))
return results
class ScholarSearchProvider(SearchProvider):
"""Search provider for academic papers and scholarly articles."""
def __init__(self, timeout: int = 30):
"""Initialize the scholar search provider."""
if not BS4_AVAILABLE:
raise ImportError("beautifulsoup4 is required for Scholar search")
self.timeout = timeout
self.session = requests.Session()
self.session.headers.update({
'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'
})
@retry_on_failure(max_attempts=2)
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Search for scholarly articles using Google Scholar."""
url = f"https://scholar.google.com/scholar?q={quote_plus(query)}&hl=en&num={num_results}"
response = self.session.get(url, timeout=self.timeout)
response.raise_for_status()
soup = BeautifulSoup(response.text, 'html.parser')
results = []
result_divs = soup.find_all('div', class_='gs_ri')
for div in result_divs[:num_results]:
title_elem = div.find('h3', class_='gs_rt')
if not title_elem:
continue
for cite in title_elem.find_all('span', class_='gs_ct1'):
cite.decompose()
for cite in title_elem.find_all('span', class_='gs_ct2'):
cite.decompose()
title_link = title_elem.find('a')
title = title_link.get_text(strip=True) if title_link else title_elem.get_text(strip=True)
url = title_link.get('href', '') if title_link else ''
snippet_elem = div.find('div', class_='gs_rs')
snippet = snippet_elem.get_text(strip=True) if snippet_elem else ''
if title:
results.append(SearchResult(
title=title,
url=url,
snippet=snippet,
source='google_scholar'
))
return results
class AggregatedSearchProvider(SearchProvider):
"""Aggregates results from multiple search providers."""
def __init__(self, providers: List[SearchProvider], max_workers: int = 3):
"""Initialize the aggregated search provider."""
self.providers = providers
self.max_workers = max_workers
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Execute searches across all providers and aggregate results."""
all_results = []
seen_urls: Set[str] = set()
with ThreadPoolExecutor(max_workers=self.max_workers) as executor:
future_to_provider = {
executor.submit(provider.search, query, num_results): provider
for provider in self.providers
}
for future in as_completed(future_to_provider):
provider = future_to_provider[future]
try:
results = future.result()
for result in results:
if result.url and result.url not in seen_urls:
seen_urls.add(result.url)
all_results.append(result)
except Exception as e:
logging.warning(f"Search provider {provider.__class__.__name__} failed: {str(e)}")
continue
return all_results[:num_results]
# ============================================================================
# Content Extraction
# ============================================================================
class ContentExtractor:
"""Extracts main content from web pages."""
def __init__(self, timeout: int = 30, max_content_length: int = 50000):
"""Initialize the content extractor."""
if not BS4_AVAILABLE:
raise ImportError("beautifulsoup4 is required for content extraction")
self.timeout = timeout
self.max_content_length = max_content_length
self.session = requests.Session()
self.session.headers.update({
'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'
})
@retry_on_failure(max_attempts=2)
def extract(self, url: str) -> Optional[Dict[str, str]]:
"""Extract main content from a URL."""
try:
response = self.session.get(url, timeout=self.timeout)
response.raise_for_status()
except requests.RequestException as e:
logging.warning(f"Failed to fetch {url}: {str(e)}")
return None
soup = BeautifulSoup(response.text, 'html.parser')
for element in soup(['script', 'style', 'nav', 'footer', 'header', 'aside']):
element.decompose()
title = ''
title_tag = soup.find('title')
if title_tag:
title = title_tag.get_text(strip=True)
main_content = None
for selector in ['main', 'article', '[role="main"]', '.content', '#content']:
main_content = soup.select_one(selector)
if main_content:
break
if not main_content:
main_content = soup.find('body')
if not main_content:
return None
text = main_content.get_text(separator=' ', strip=True)
text = ' '.join(text.split())
if len(text) > self.max_content_length:
text = text[:self.max_content_length] + '...'
return {
'title': title,
'content': text,
'url': url
}
class CachedContentExtractor(ContentExtractor):
"""Content extractor with disk-based caching."""
def __init__(self, cache_dir: str = '.cache', **kwargs):
"""Initialize cached content extractor."""
super().__init__(**kwargs)
self.cache_dir = cache_dir
os.makedirs(cache_dir, exist_ok=True)
def _get_cache_path(self, url: str) -> str:
"""Generate cache file path for a URL."""
url_hash = hashlib.md5(url.encode()).hexdigest()
return os.path.join(self.cache_dir, f"{url_hash}.pkl")
def extract(self, url: str) -> Optional[Dict[str, str]]:
"""Extract content with caching."""
cache_path = self._get_cache_path(url)
if os.path.exists(cache_path):
try:
with open(cache_path, 'rb') as f:
return pickle.load(f)
except Exception:
pass
content = super().extract(url)
if content:
try:
with open(cache_path, 'wb') as f:
pickle.dump(content, f)
except Exception:
pass
return content
# ============================================================================
# Search Result Caching
# ============================================================================
class SearchResultCache:
"""Cache for search results with TTL support."""
def __init__(self, cache_dir: str = '.cache', ttl_hours: int = 24):
"""Initialize search result cache."""
self.cache_dir = os.path.join(cache_dir, 'search')
self.ttl_seconds = ttl_hours * 3600
os.makedirs(self.cache_dir, exist_ok=True)
def _get_cache_key(self, query: str, num_results: int) -> str:
"""Generate cache key for a query."""
key_str = f"{query}:{num_results}"
return hashlib.md5(key_str.encode()).hexdigest()
def get(self, query: str, num_results: int) -> Optional[List[SearchResult]]:
"""Retrieve cached search results if available and fresh."""
cache_key = self._get_cache_key(query, num_results)
cache_path = os.path.join(self.cache_dir, f"{cache_key}.pkl")
if not os.path.exists(cache_path):
return None
cache_age = time.time() - os.path.getmtime(cache_path)
if cache_age > self.ttl_seconds:
return None
try:
with open(cache_path, 'rb') as f:
return pickle.load(f)
except Exception:
return None
def set(self, query: str, num_results: int, results: List[SearchResult]):
"""Cache search results."""
cache_key = self._get_cache_key(query, num_results)
cache_path = os.path.join(self.cache_dir, f"{cache_key}.pkl")
try:
with open(cache_path, 'wb') as f:
pickle.dump(results, f)
except Exception:
pass
class CachedSearchProvider(SearchProvider):
"""Search provider wrapper with caching."""
def __init__(self, provider: SearchProvider, cache: SearchResultCache):
"""Initialize cached search provider."""
self.provider = provider
self.cache = cache
def search(self, query: str, num_results: int = 10) -> List[SearchResult]:
"""Search with caching."""
cached = self.cache.get(query, num_results)
if cached is not None:
logging.info(f"Using cached search results for: {query}")
return cached
results = self.provider.search(query, num_results)
self.cache.set(query, num_results, results)
return results
# ============================================================================
# Content Analysis
# ============================================================================
class ContentAnalyzer:
"""Analyzes and ranks content using LLM capabilities."""
def __init__(self, llm_provider: LLMProvider):
"""Initialize the content analyzer."""
self.llm = llm_provider
def analyze_resource(self, search_result: SearchResult,
content: Optional[str], subject: str) -> AnalyzedResource:
"""Analyze a single resource for relevance and quality."""
analysis_text = f"Title: {search_result.title}\n"
analysis_text += f"URL: {search_result.url}\n"
analysis_text += f"Snippet: {search_result.snippet}\n"
if content:
content_preview = content[:2000]
analysis_text += f"Content preview: {content_preview}\n"
prompt = self._build_analysis_prompt(analysis_text, subject)
messages = [
Message(role='system', content='You are an expert research assistant that evaluates the relevance and quality of learning resources.'),
Message(role='user', content=prompt)
]
try:
response = self.llm.generate(messages, max_tokens=500, temperature=0.3)
scores = self._parse_analysis_response(response)
return AnalyzedResource(
title=search_result.title,
url=search_result.url,
snippet=search_result.snippet,
resource_type=scores['resource_type'],
relevance_score=scores['relevance_score'],
quality_score=scores['quality_score'],
reasoning=scores['reasoning']
)
except Exception as e:
logging.warning(f"Analysis failed for {search_result.url}: {str(e)}")
return AnalyzedResource(
title=search_result.title,
url=search_result.url,
snippet=search_result.snippet,
resource_type=ResourceType.UNKNOWN,
relevance_score=0.5,
quality_score=0.5,
reasoning="Analysis failed; using default scores"
)
def _build_analysis_prompt(self, resource_info: str, subject: str) -> str:
"""Build the prompt for resource analysis."""
prompt = f"""Analyze the following resource for a user researching "{subject}".
{resource_info}
Provide your analysis in the following structured format:
RESOURCE_TYPE: [one of: academic_paper, book, tutorial, article, documentation, video, course, unknown]
RELEVANCE_SCORE: [0.0 to 1.0, where 1.0 means highly relevant to the subject]
QUALITY_SCORE: [0.0 to 1.0, where 1.0 means high quality and authoritative]
REASONING: [brief explanation of your scores]
Consider these factors:
- How well does the resource match the subject area?
- Is it from an authoritative source?
- Is it comprehensive and well-structured?
- Is it suitable for learning about the subject?
"""
return prompt
def _parse_analysis_response(self, response: str) -> Dict:
"""Parse the structured analysis response from the LLM."""
lines = response.strip().split('\n')
result = {
'resource_type': ResourceType.UNKNOWN,
'relevance_score': 0.5,
'quality_score': 0.5,
'reasoning': ''
}
for line in lines:
line = line.strip()
if line.startswith('RESOURCE_TYPE:'):
type_str = line.split(':', 1)[1].strip().lower()
try:
result['resource_type'] = ResourceType(type_str)
except ValueError:
result['resource_type'] = ResourceType.UNKNOWN
elif line.startswith('RELEVANCE_SCORE:'):
try:
score = float(line.split(':', 1)[1].strip())
result['relevance_score'] = max(0.0, min(1.0, score))
except ValueError:
pass
elif line.startswith('QUALITY_SCORE:'):
try:
score = float(line.split(':', 1)[1].strip())
result['quality_score'] = max(0.0, min(1.0, score))
except ValueError:
pass
elif line.startswith('REASONING:'):
result['reasoning'] = line.split(':', 1)[1].strip()
return result
def batch_analyze(self, search_results: List[SearchResult],
subject: str, extractor: ContentExtractor,
max_workers: int = 5) -> List[AnalyzedResource]:
"""Analyze multiple resources in parallel."""
analyzed_resources = []
with ThreadPoolExecutor(max_workers=max_workers) as executor:
future_to_result = {}
for result in search_results:
future = executor.submit(self._analyze_with_content,
result, subject, extractor)
future_to_result[future] = result
for future in as_completed(future_to_result):
try:
analyzed = future.result()
analyzed_resources.append(analyzed)
except Exception as e:
result = future_to_result[future]
logging.error(f"Failed to analyze {result.url}: {str(e)}")
analyzed_resources.sort(key=lambda x: x.overall_score, reverse=True)
return analyzed_resources
def _analyze_with_content(self, search_result: SearchResult,
subject: str, extractor: ContentExtractor) -> AnalyzedResource:
"""Helper method to extract content and analyze."""
extracted = extractor.extract(search_result.url)
content = extracted['content'] if extracted else None
return self.analyze_resource(search_result, content, subject)
# ============================================================================
# Recommendation Generation
# ============================================================================
class RecommendationGenerator:
"""Generates structured recommendations from analyzed resources."""
def __init__(self, llm_provider: LLMProvider):
"""Initialize the recommendation generator."""
self.llm = llm_provider
def generate_recommendations(self, analyzed_resources: List[AnalyzedResource],
subject: str, max_recommendations: int = 10) -> str:
"""Generate a comprehensive recommendation report."""
top_resources = analyzed_resources[:max_recommendations]
grouped = self._group_by_type(top_resources)
intro = self._generate_introduction(subject, len(top_resources))
sections = []
type_order = [
ResourceType.ACADEMIC_PAPER,
ResourceType.BOOK,
ResourceType.COURSE,
ResourceType.TUTORIAL,
ResourceType.DOCUMENTATION,
ResourceType.ARTICLE,
ResourceType.VIDEO,
ResourceType.UNKNOWN
]
for resource_type in type_order:
if resource_type in grouped and grouped[resource_type]:
section = self._generate_type_section(
resource_type,
grouped[resource_type],
subject
)
sections.append(section)
report = intro + '\n\n'
report += '\n\n'.join(sections)
report += '\n\n' + self._generate_conclusion(subject)
return report
def _group_by_type(self, resources: List[AnalyzedResource]) -> Dict[ResourceType, List[AnalyzedResource]]:
"""Group resources by their type."""
grouped = {}
for resource in resources:
if resource.resource_type not in grouped:
grouped[resource.resource_type] = []
grouped[resource.resource_type].append(resource)
return grouped
def _generate_introduction(self, subject: str, num_resources: int) -> str:
"""Generate an introduction for the recommendations."""
prompt = f"""Write a brief introduction (2-3 sentences) for a curated list of {num_resources} learning resources about "{subject}".
The introduction should welcome the user and explain that these resources have been carefully selected and analyzed for relevance and quality."""
messages = [
Message(role='system', content='You are a helpful research assistant.'),
Message(role='user', content=prompt)
]
return self.llm.generate(messages, max_tokens=200, temperature=0.7)
def _generate_type_section(self, resource_type: ResourceType,
resources: List[AnalyzedResource],
subject: str) -> str:
"""Generate a section for a specific resource type."""
type_names = {
ResourceType.ACADEMIC_PAPER: 'Academic Papers and Research',
ResourceType.BOOK: 'Books',
ResourceType.COURSE: 'Online Courses',
ResourceType.TUTORIAL: 'Tutorials and Guides',
ResourceType.DOCUMENTATION: 'Documentation',
ResourceType.ARTICLE: 'Articles and Blog Posts',
ResourceType.VIDEO: 'Video Resources',
ResourceType.UNKNOWN: 'Additional Resources'
}
section = f"=== {type_names.get(resource_type, 'Resources')} ===\n\n"
for i, resource in enumerate(resources, 1):
section += f"{i}. {resource.title}\n"
section += f" URL: {resource.url}\n"
section += f" Relevance: {resource.relevance_score:.2f} | Quality: {resource.quality_score:.2f}\n"
section += f" {resource.reasoning}\n\n"
return section
def _generate_conclusion(self, subject: str) -> str:
"""Generate a conclusion for the recommendations."""
prompt = f"""Write a brief conclusion (2-3 sentences) for a curated list of learning resources about "{subject}".
Encourage the user to explore these resources and mention that they can request more specific recommendations if needed."""
messages = [
Message(role='system', content='You are a helpful research assistant.'),
Message(role='user', content=prompt)
]
return self.llm.generate(messages, max_tokens=200, temperature=0.7)
# ============================================================================
# Metrics Collection
# ============================================================================
class MetricsCollector:
"""Collects and persists metrics for research operations."""
def __init__(self, metrics_file: str = 'metrics.jsonl'):
"""Initialize metrics collector."""
self.metrics_file = metrics_file
def record(self, metrics: ResearchMetrics):
"""Record metrics to file."""
with open(self.metrics_file, 'a') as f:
f.write(json.dumps(metrics.to_dict()) + '\n')
def get_statistics(self) -> Dict:
"""Calculate aggregate statistics from recorded metrics."""
if not os.path.exists(self.metrics_file):
return {}
total_operations = 0
total_duration = 0.0
total_results = 0
total_errors = 0
with open(self.metrics_file, 'r') as f:
for line in f:
try:
data = json.loads(line)
total_operations += 1
total_duration += data.get('duration_seconds', 0)
total_results += data.get('search_results_count', 0)
total_errors += len(data.get('errors', []))
except json.JSONDecodeError:
continue
if total_operations == 0:
return {}
return {
'total_operations': total_operations,
'average_duration_seconds': total_duration / total_operations,
'average_results_per_operation': total_results / total_operations,
'total_errors': total_errors,
'error_rate': total_errors / total_operations
}
# ============================================================================
# Main Research Agent
# ============================================================================
class ResearchAgent:
"""Main agent that orchestrates the research and recommendation process."""
def __init__(self, llm_provider: LLMProvider,
search_provider: SearchProvider,
content_extractor: ContentExtractor,
content_analyzer: ContentAnalyzer,
recommendation_generator: RecommendationGenerator,
metrics_collector: Optional[MetricsCollector] = None):
"""Initialize the research agent."""
self.llm = llm_provider
self.search = search_provider
self.extractor = content_extractor
self.analyzer = content_analyzer
self.recommender = recommendation_generator
self.metrics = metrics_collector
def research(self, subject: str, num_results: int = 20,
max_recommendations: int = 10) -> str:
"""Execute the complete research workflow."""
operation_metrics = ResearchMetrics(
subject=subject,
start_time=datetime.now()
) if self.metrics else None
try:
logging.info(f"Starting research for subject: {subject}")
enhanced_query = self._enhance_query(subject)
logging.info(f"Enhanced query: {enhanced_query}")
logging.info(f"Searching for {num_results} resources...")
search_results = self.search.search(enhanced_query, num_results)
logging.info(f"Found {len(search_results)} search results")
if operation_metrics:
operation_metrics.search_results_count = len(search_results)
if not search_results:
return f"No resources found for subject: {subject}"
logging.info("Analyzing resources...")
analyzed_resources = self.analyzer.batch_analyze(
search_results,
subject,
self.extractor
)
logging.info(f"Analyzed {len(analyzed_resources)} resources")
if operation_metrics:
operation_metrics.analyzed_resources_count = len(analyzed_resources)
logging.info("Generating recommendations...")
recommendations = self.recommender.generate_recommendations(
analyzed_resources,
subject,
max_recommendations
)
if operation_metrics:
operation_metrics.recommendations_count = max_recommendations
operation_metrics.end_time = datetime.now()
logging.info("Research complete")
return recommendations
except Exception as e:
if operation_metrics:
operation_metrics.errors.append(str(e))
operation_metrics.end_time = datetime.now()
raise
finally:
if operation_metrics and self.metrics:
self.metrics.record(operation_metrics)
def _enhance_query(self, subject: str) -> str:
"""Use LLM to enhance the search query for better results."""
prompt = f"""Given the subject "{subject}", generate an optimized search query that will find high-quality learning resources including books, academic papers, tutorials, and articles.
The query should:
- Include relevant technical terms and synonyms
- Be concise but comprehensive
- Focus on authoritative and educational content
Provide only the search query, nothing else."""
messages = [
Message(role='system', content='You are an expert at formulating effective search queries.'),
Message(role='user', content=prompt)
]
enhanced = self.llm.generate(messages, max_tokens=100, temperature=0.5)
return enhanced.strip()
def interactive_research(self):
"""Run an interactive research session."""
print("Research Agent - Interactive Mode")
print("=" * 50)
print("Enter a subject area to research, or 'quit' to exit.\n")
while True:
subject = input("Subject: ").strip()
if subject.lower() in ['quit', 'exit', 'q']:
print("Goodbye!")
break
if not subject:
print("Please enter a valid subject.\n")
continue
try:
print("\nResearching... This may take a minute.\n")
recommendations = self.research(subject)
print(recommendations)
print("\n" + "=" * 50 + "\n")
except Exception as e:
print(f"Error during research: {str(e)}\n")
logging.error(f"Research failed: {str(e)}", exc_info=True)
# ============================================================================
# Agent Factory
# ============================================================================
def create_agent_from_config(config: AgentConfig) -> ResearchAgent:
"""Factory function to create a fully configured ResearchAgent."""
logging.basicConfig(
level=getattr(logging, config.log_level),
format='%(asctime)s - %(name)s - %(levelname)s - %(message)s'
)
if config.llm.backend == 'local':
llm_provider = create_llm_provider(
LLMBackend.LOCAL,
model_path=config.llm.model_path,
n_gpu_layers=config.llm.n_gpu_layers,
n_ctx=config.llm.n_ctx
)
else:
llm_provider = create_llm_provider(
LLMBackend.REMOTE,
api_key=config.llm.api_key,
api_base=config.llm.api_base,
model_name=config.llm.model_name
)
search_providers = []
for provider_name in config.search.providers:
if provider_name.lower() == 'duckduckgo':
search_providers.append(DuckDuckGoSearchProvider(timeout=config.search.timeout))
elif provider_name.lower() == 'bing' and config.search.bing_api_key:
search_providers.append(BingSearchProvider(
api_key=config.search.bing_api_key,
timeout=config.search.timeout
))
elif provider_name.lower() == 'scholar':
search_providers.append(ScholarSearchProvider(timeout=config.search.timeout))
base_search_provider = AggregatedSearchProvider(search_providers)
if config.cache_enabled:
search_cache = SearchResultCache(
cache_dir=config.cache_dir,
ttl_hours=config.cache_ttl_hours
)
search_provider = CachedSearchProvider(base_search_provider, search_cache)
content_extractor = CachedContentExtractor(
cache_dir=config.cache_dir,
timeout=config.content_timeout,
max_content_length=config.max_content_length
)
else:
search_provider = base_search_provider
content_extractor = ContentExtractor(
timeout=config.content_timeout,
max_content_length=config.max_content_length
)
content_analyzer = ContentAnalyzer(llm_provider)
recommendation_generator = RecommendationGenerator(llm_provider)
metrics_collector = None
if config.metrics_enabled:
metrics_collector = MetricsCollector(metrics_file=config.metrics_file)
return ResearchAgent(
llm_provider=llm_provider,
search_provider=search_provider,
content_extractor=content_extractor,
content_analyzer=content_analyzer,
recommendation_generator=recommendation_generator,
metrics_collector=metrics_collector
)
# ============================================================================
# Command-Line Interface
# ============================================================================
def main():
"""Main entry point for the research agent."""
parser = argparse.ArgumentParser(
description='Research Agent - LLM-based resource discovery system'
)
parser.add_argument(
'--config',
type=str,
help='Path to configuration JSON file'
)
parser.add_argument(
'--subject',
type=str,
help='Subject area to research (for single query mode)'
)
parser.add_argument(
'--interactive',
action='store_true',
help='Run in interactive mode'
)
parser.add_argument(
'--stats',
action='store_true',
help='Display statistics from previous operations'
)
args = parser.parse_args()
try:
if args.config:
config = AgentConfig.from_file(args.config)
else:
config = AgentConfig.from_env()
agent = create_agent_from_config(config)
if args.stats and config.metrics_enabled:
metrics = MetricsCollector(config.metrics_file)
stats = metrics.get_statistics()
if stats:
print("Research Agent Statistics")
print("=" * 50)
print(f"Total operations: {stats['total_operations']}")
print(f"Average duration: {stats['average_duration_seconds']:.2f} seconds")
print(f"Average results per operation: {stats['average_results_per_operation']:.1f}")
print(f"Total errors: {stats['total_errors']}")
print(f"Error rate: {stats['error_rate']:.2%}")
else:
print("No statistics available yet.")
return
if args.subject:
recommendations = agent.research(args.subject)
print(recommendations)
elif args.interactive:
agent.interactive_research()
else:
parser.print_help()
except Exception as e:
logging.error(f"Fatal error: {str(e)}", exc_info=True)
print(f"Error: {str(e)}", file=sys.stderr)
sys.exit(1)
if __name__ == '__main__':
main()
This complete implementation provides a production-ready research agent system that can be deployed and used immediately. The code includes all necessary error handling, caching, metrics collection, and configuration management. It supports both local and remote LLM deployments with automatic GPU detection across NVIDIA CUDA, AMD ROCm, Intel, and Apple Metal architectures. The system can search multiple providers concurrently, analyze content in parallel, and generate comprehensive recommendations for any subject area a user specifies.
