Hitchhiker's Guide to AI, Software Architecture, and Everything Else

INTRODUCTION

The exponential growth of information on the internet presents both opportunities and challenges for professionals seeking to stay current in their fields. Whether you are tracking developments in software engineering, artificial intelligence, robotics, generative AI, integrated development environments, 3D printing technologies, lasers, or astronomy, the sheer volume of data makes manual trend identification increasingly impractical. This article presents a comprehensive guide to building an LLM-powered agent that automatically discovers, analyzes, and categorizes emerging trends in any given topic area.

Our trend discovery agent combines the reasoning capabilities of large language models with real-time internet search functionality to identify and classify trends according to established frameworks from trend research. The system leverages GPU acceleration through NVIDIA CUDA or Apple Metal Performance Shaders to ensure optimal performance, supports both local and remote LLM deployments, and provides detailed analysis including trend classification, impact assessment, and curated resources for further exploration.

UNDERSTANDING THE PROBLEM DOMAIN

Before diving into implementation details, we must establish a clear understanding of what constitutes a trend and how trend research methodologies can inform our agent's design. In trend research, professionals distinguish between several categories of trends based on their scope, duration, and impact. A fad represents a short-lived phenomenon with limited lasting impact. A trend typically spans several years and affects specific industries or domains. A megatrend encompasses decades-long shifts that fundamentally reshape society, technology, and markets across multiple sectors.

Our agent must not only identify emerging patterns but also classify them appropriately, assess their potential impact on technology, science, and products, and provide substantive analysis that goes beyond simple keyword matching. This requires integrating multiple capabilities including web search, content analysis, pattern recognition, and structured reasoning about trend characteristics.

ARCHITECTURAL OVERVIEW

The trend discovery agent architecture consists of several interconnected components working in harmony. At the foundation lies the LLM interface layer, which abstracts the differences between local and remote language models while ensuring optimal GPU utilization. Above this sits the search orchestration layer, responsible for formulating effective search queries, retrieving relevant content, and managing the information gathering process. The analysis engine processes retrieved information to identify patterns, extract key insights, and classify trends according to established frameworks. Finally, the presentation layer structures the findings into coherent reports with proper citations and recommendations for further reading.

The system follows clean architecture principles by separating concerns into distinct layers with well-defined interfaces. This separation ensures that we can swap implementations, for example replacing one LLM provider with another, without affecting the rest of the system. The architecture also emphasizes testability, maintainability, and extensibility to accommodate future enhancements.

STEP ONE: ESTABLISHING THE LLM FOUNDATION

The first step in building our trend discovery agent involves creating a robust abstraction layer for language model interactions. This layer must handle both local models running on consumer hardware and remote API-based services while optimizing for available GPU resources.

We begin by defining a base interface that all LLM implementations must satisfy. This interface specifies methods for generating completions, managing conversation context, and configuring generation parameters.

from abc import ABC, abstractmethod

from typing import List, Dict, Optional, Any

from dataclasses import dataclass

import torch

@dataclass

class GenerationConfig:

"""Configuration parameters for text generation."""

temperature: float = 0.7

max_tokens: int = 2048

top_p: float = 0.9

frequency_penalty: float = 0.0

presence_penalty: float = 0.0

stop_sequences: Optional[List[str]] = None

@dataclass

class Message:

"""Represents a single message in a conversation."""

role: str # 'system', 'user', or 'assistant'

content: str

class LLMInterface(ABC):

"""Abstract base class for all LLM implementations."""

@abstractmethod

def generate(self, messages: List[Message], config: GenerationConfig) -> str:

"""

Generate a response based on the conversation history.

Args:

messages: List of conversation messages

config: Generation configuration parameters

Returns:

Generated text response

"""

pass

@abstractmethod

def get_device_info(self) -> Dict[str, Any]:

"""

Retrieve information about the compute device being used.

Returns:

Dictionary containing device type, name, and capabilities

"""

pass

This interface provides the contract that all concrete implementations must fulfill. The Message dataclass encapsulates individual conversation turns, while GenerationConfig allows fine-grained control over the generation process. The get_device_info method enables monitoring and debugging of GPU utilization.

Now we implement a local LLM provider that leverages GPU acceleration through PyTorch. This implementation automatically detects available hardware and configures itself accordingly.

import torch

from transformers import AutoModelForCausalLM, AutoTokenizer

from typing import List, Dict, Any

class LocalLLMProvider(LLMInterface):

"""

Local LLM implementation with automatic GPU acceleration.

Supports NVIDIA CUDA and Apple Metal Performance Shaders.

"""

def __init__(self, model_name: str, device: Optional[str] = None):

"""

Initialize the local LLM provider.

Args:

model_name: HuggingFace model identifier

device: Target device ('cuda', 'mps', 'cpu', or None for auto-detect)

"""

self.model_name = model_name

self.device = self._determine_device(device)

# Load tokenizer and model with appropriate device mapping

self.tokenizer = AutoTokenizer.from_pretrained(model_name)

# Configure model loading based on available hardware

if self.device == 'cuda':

# Use CUDA with automatic mixed precision for optimal performance

self.model = AutoModelForCausalLM.from_pretrained(

model_name,

torch_dtype=torch.float16,

device_map='auto'

)

elif self.device == 'mps':

# Apple Silicon optimization

self.model = AutoModelForCausalLM.from_pretrained(

model_name,

torch_dtype=torch.float16

).to('mps')

else:

# CPU fallback

self.model = AutoModelForCausalLM.from_pretrained(model_name)

self.model.to('cpu')

def _determine_device(self, preferred_device: Optional[str]) -> str:

"""

Determine the optimal compute device.

Args:

preferred_device: User-specified device preference

Returns:

Device string ('cuda', 'mps', or 'cpu')

"""

if preferred_device:

return preferred_device

# Auto-detect best available device

if torch.cuda.is_available():

return 'cuda'

elif torch.backends.mps.is_available():

return 'mps'

else:

return 'cpu'

def generate(self, messages: List[Message], config: GenerationConfig) -> str:

"""Generate response using the local model."""

# Format messages into a prompt string

prompt = self._format_messages(messages)

# Tokenize input

inputs = self.tokenizer(prompt, return_tensors='pt').to(self.device)

# Configure generation parameters

gen_kwargs = {

'max_new_tokens': config.max_tokens,

'temperature': config.temperature,

'top_p': config.top_p,

'do_sample': True,

'pad_token_id': self.tokenizer.eos_token_id

}

# Generate response

with torch.no_grad():

outputs = self.model.generate(**inputs, **gen_kwargs)

# Decode and return only the new tokens

full_response = self.tokenizer.decode(outputs[0], skip_special_tokens=True)

response = full_response[len(prompt):].strip()

return response

def _format_messages(self, messages: List[Message]) -> str:

"""

Format conversation messages into a prompt string.

Args:

messages: List of conversation messages

Returns:

Formatted prompt string

"""

formatted_parts = []

for msg in messages:

if msg.role == 'system':

formatted_parts.append(f"System: {msg.content}")

elif msg.role == 'user':

formatted_parts.append(f"User: {msg.content}")

elif msg.role == 'assistant':

formatted_parts.append(f"Assistant: {msg.content}")

formatted_parts.append("Assistant:")

return "\n\n".join(formatted_parts)

def get_device_info(self) -> Dict[str, Any]:

"""Retrieve information about the compute device."""

info = {

'device_type': self.device,

'model_name': self.model_name

}

if self.device == 'cuda':

info['gpu_name'] = torch.cuda.get_device_name(0)

info['gpu_memory_total'] = torch.cuda.get_device_properties(0).total_memory

info['gpu_memory_allocated'] = torch.cuda.memory_allocated(0)

elif self.device == 'mps':

info['gpu_name'] = 'Apple Silicon'

return info

The LocalLLMProvider class demonstrates several important design decisions. First, it automatically detects the best available hardware and configures PyTorch accordingly. When NVIDIA CUDA is available, it uses half-precision floating point arithmetic to maximize throughput and minimize memory consumption. For Apple Silicon devices, it leverages the Metal Performance Shaders backend. The implementation falls back gracefully to CPU execution when no GPU acceleration is available.

The message formatting logic converts our structured conversation history into a text prompt suitable for causal language models. This approach maintains conversation context while remaining compatible with various model architectures.

Next, we implement a remote LLM provider that interfaces with API-based services such as OpenAI, Anthropic, or other providers. This implementation shares the same interface, allowing seamless substitution.

import requests

from typing import List, Dict, Any

import os

class RemoteLLMProvider(LLMInterface):

"""

Remote LLM implementation for API-based services.

Supports OpenAI-compatible endpoints.

"""

def __init__(self, api_key: str, model_name: str, base_url: str = "https://api.openai.com/v1"):

"""

Initialize the remote LLM provider.

Args:

api_key: API authentication key

model_name: Model identifier for the remote service

base_url: Base URL for the API endpoint

"""

self.api_key = api_key

self.model_name = model_name

self.base_url = base_url

self.headers = {

'Authorization': f'Bearer {api_key}',

'Content-Type': 'application/json'

}

def generate(self, messages: List[Message], config: GenerationConfig) -> str:

"""Generate response using the remote API."""

# Convert messages to API format

api_messages = [

{'role': msg.role, 'content': msg.content}

for msg in messages

]

# Prepare request payload

payload = {

'model': self.model_name,

'messages': api_messages,

'temperature': config.temperature,

'max_tokens': config.max_tokens,

'top_p': config.top_p,

'frequency_penalty': config.frequency_penalty,

'presence_penalty': config.presence_penalty

}

if config.stop_sequences:

payload['stop'] = config.stop_sequences

# Make API request

response = requests.post(

f'{self.base_url}/chat/completions',

headers=self.headers,

json=payload,

timeout=120

)

response.raise_for_status()

result = response.json()

return result['choices'][0]['message']['content']

def get_device_info(self) -> Dict[str, Any]:

"""Retrieve information about the remote service."""

return {

'device_type': 'remote',

'model_name': self.model_name,

'base_url': self.base_url

}

The RemoteLLMProvider handles communication with external API services, managing authentication, request formatting, and error handling. By implementing the same LLMInterface, we ensure that the rest of our system remains agnostic to whether it is using a local or remote model.

STEP TWO: IMPLEMENTING WEB SEARCH CAPABILITIES

With our LLM foundation established, we now turn our attention to web search functionality. The trend discovery agent must be able to formulate effective search queries, retrieve relevant content from the internet, and extract meaningful information from web pages.

We begin by creating a search interface that abstracts different search providers. This allows us to support multiple search engines or services while maintaining a consistent interface.

from abc import ABC, abstractmethod

from dataclasses import dataclass

from typing import List, Optional

from datetime import datetime

@dataclass

class SearchResult:

"""Represents a single search result."""

title: str

url: str

snippet: str

published_date: Optional[datetime] = None

source: Optional[str] = None

class SearchInterface(ABC):

"""Abstract base class for search providers."""

@abstractmethod

def search(self, query: str, num_results: int = 10, time_filter: Optional[str] = None) -> List[SearchResult]:

"""

Execute a search query and return results.

Args:

query: Search query string

num_results: Maximum number of results to return

time_filter: Optional time filter ('day', 'week', 'month', 'year')

Returns:

List of search results

"""

pass

Now we implement a concrete search provider using the DuckDuckGo search engine, which provides a free API without requiring authentication. This makes it ideal for our trend discovery agent.

from duckduckgo_search import DDGS

from typing import List, Optional

from datetime import datetime

import time

class DuckDuckGoSearchProvider(SearchInterface):

"""

Search provider implementation using DuckDuckGo.

Provides free, privacy-focused search without API keys.

"""

def __init__(self):

"""Initialize the DuckDuckGo search provider."""

self.ddgs = DDGS()

def search(self, query: str, num_results: int = 10, time_filter: Optional[str] = None) -> List[SearchResult]:

"""

Execute a search query using DuckDuckGo.

Args:

query: Search query string

num_results: Maximum number of results to return

time_filter: Optional time filter ('d' for day, 'w' for week, 'm' for month, 'y' for year)

Returns:

List of search results

"""

try:

# Execute search with optional time filter

search_params = {'max_results': num_results}

if time_filter:

search_params['timelimit'] = time_filter

results = list(self.ddgs.text(query, **search_params))

# Convert to our SearchResult format

search_results = []

for result in results:

search_result = SearchResult(

title=result.get('title', ''),

url=result.get('href', ''),

snippet=result.get('body', ''),

source=result.get('source', None)

)

search_results.append(search_result)

return search_results

except Exception as e:

print(f"Search error: {str(e)}")

return []

The DuckDuckGoSearchProvider wraps the DuckDuckGo search API and converts results into our standardized SearchResult format. This abstraction allows us to easily swap search providers if needed without affecting the rest of the system.

To extract meaningful content from web pages, we need a robust web scraping component that can handle various page structures and extract the main textual content while filtering out navigation, advertisements, and other non-essential elements.

import requests

from bs4 import BeautifulSoup

from typing import Optional

import re

class WebContentExtractor:

"""

Extracts main textual content from web pages.

Filters out navigation, ads, and other non-essential elements.

"""

def __init__(self, timeout: int = 10):

"""

Initialize the web content extractor.

Args:

timeout: Request timeout in seconds

"""

self.timeout = timeout

self.headers = {

'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'

}

def extract_content(self, url: str) -> Optional[str]:

"""

Extract main textual content from a web page.

Args:

url: URL of the web page to extract content from

Returns:

Extracted text content or None if extraction fails

"""

try:

# Fetch the web page

response = requests.get(url, headers=self.headers, timeout=self.timeout)

response.raise_for_status()

# Parse HTML

soup = BeautifulSoup(response.content, 'html.parser')

# Remove script and style elements

for element in soup(['script', 'style', 'nav', 'header', 'footer', 'aside']):

element.decompose()

# Extract text from main content areas

main_content = soup.find('main') or soup.find('article') or soup.find('body')

if not main_content:

return None

# Get text and clean it

text = main_content.get_text(separator='\n', strip=True)

# Remove excessive whitespace

text = re.sub(r'\n\s*\n', '\n\n', text)

text = re.sub(r' +', ' ', text)

return text

except Exception as e:

print(f"Content extraction error for {url}: {str(e)}")

return None

def extract_summary(self, url: str, max_length: int = 1000) -> Optional[str]:

"""

Extract a summary of the web page content.

Args:

url: URL of the web page

max_length: Maximum length of the summary in characters

Returns:

Summarized content or None if extraction fails

"""

content = self.extract_content(url)

if not content:

return None

# Take the first max_length characters, breaking at sentence boundaries

if len(content) <= max_length:

return content

truncated = content[:max_length]

last_period = truncated.rfind('.')

if last_period > max_length * 0.7:

return truncated[:last_period + 1]

else:

return truncated + '...'

The WebContentExtractor class provides methods for retrieving and cleaning web page content. It removes non-essential elements like scripts, styles, and navigation components, focusing on the main textual content. The extract_summary method provides a convenient way to get a condensed version of the content, which is useful when we need to process multiple sources efficiently.

STEP THREE: BUILDING THE TREND ANALYSIS ENGINE

With our LLM and search capabilities in place, we now construct the core trend analysis engine. This component orchestrates the entire trend discovery process, from query formulation through result synthesis.

The trend analysis engine must perform several sophisticated tasks. First, it generates effective search queries based on the user's topic area. Second, it retrieves and processes relevant web content. Third, it analyzes the collected information to identify patterns and emerging trends. Fourth, it classifies trends according to established frameworks. Finally, it synthesizes findings into a comprehensive report.

from typing import List, Dict, Any

from dataclasses import dataclass

from enum import Enum

class TrendCategory(Enum):

"""Classification categories for identified trends."""

FAD = "fad"

MICRO_TREND = "micro_trend"

TREND = "trend"

MACRO_TREND = "macro_trend"

MEGA_TREND = "mega_trend"

@dataclass

class TrendAnalysis:

"""Represents a complete trend analysis."""

trend_name: str

category: TrendCategory

summary: str

technology_impact: str

science_impact: str

product_impact: str

key_indicators: List[str]

time_horizon: str

confidence_level: float

sources: List[SearchResult]

recommended_urls: List[str]

class TrendAnalysisEngine:

"""

Core engine for discovering and analyzing trends.

Orchestrates search, content extraction, and LLM-based analysis.

"""

def __init__(self, llm: LLMInterface, search_provider: SearchInterface, content_extractor: WebContentExtractor):

"""

Initialize the trend analysis engine.

Args:

llm: Language model interface for analysis

search_provider: Search interface for finding relevant content

content_extractor: Web content extraction utility

"""

self.llm = llm

self.search_provider = search_provider

self.content_extractor = content_extractor

# System prompt for trend analysis

self.system_prompt = """You are an expert trend researcher and analyst with deep knowledge of trend research methodologies. Your task is to analyze information about emerging patterns in various domains and classify them according to established trend research frameworks.

When analyzing trends, consider the following classification criteria:

A FAD is a short-lived phenomenon, typically lasting less than a year, with limited impact beyond a specific niche or community. Fads generate temporary excitement but lack the substance for long-term adoption.

A MICRO TREND affects a specific subculture or niche market, lasting one to three years. These trends have limited geographic or demographic reach but can be significant within their specific context.

A TREND represents a significant pattern of change lasting three to ten years, affecting entire industries or substantial market segments. Trends reshape business practices, consumer behavior, or technological approaches within specific domains.

A MACRO TREND spans ten to twenty years and affects multiple industries or sectors simultaneously. These trends represent fundamental shifts in how people work, live, or interact with technology.

A MEGA TREND encompasses twenty years or more and represents transformational changes that reshape society, economy, and technology on a global scale. Mega trends affect virtually all aspects of human activity.

Your analysis should be evidence-based, drawing on concrete indicators such as investment patterns, adoption rates, research activity, media coverage, and expert commentary. Always distinguish between hype and substance, and provide balanced assessments of both opportunities and challenges."""

def analyze_topic(self, topic_area: str, num_trends: int = 5) -> List[TrendAnalysis]:

"""

Analyze a topic area and identify emerging trends.

Args:

topic_area: Domain, discipline, market, or technical subject to analyze

num_trends: Number of trends to identify and analyze

Returns:

List of trend analyses

"""

print(f"Analyzing trends in: {topic_area}")

# Step 1: Generate search queries

search_queries = self._generate_search_queries(topic_area)

print(f"Generated {len(search_queries)} search queries")

# Step 2: Execute searches and collect results

all_results = []

for query in search_queries:

results = self.search_provider.search(query, num_results=10, time_filter='m')

all_results.extend(results)

time.sleep(1) # Rate limiting

print(f"Collected {len(all_results)} search results")

# Step 3: Extract content from top results

content_samples = self._extract_content_samples(all_results, max_samples=20)

print(f"Extracted content from {len(content_samples)} sources")

# Step 4: Identify potential trends

potential_trends = self._identify_trends(topic_area, content_samples)

print(f"Identified {len(potential_trends)} potential trends")

# Step 5: Analyze each trend in detail

trend_analyses = []

for trend_name in potential_trends[:num_trends]:

analysis = self._analyze_single_trend(topic_area, trend_name, all_results)

if analysis:

trend_analyses.append(analysis)

return trend_analyses

def _generate_search_queries(self, topic_area: str) -> List[str]:

"""

Generate effective search queries for the topic area.

Args:

topic_area: Topic to generate queries for

Returns:

List of search query strings

"""

messages = [

Message(role='system', content=self.system_prompt),

Message(role='user', content=f"""Generate 5 effective search queries to discover emerging trends in {topic_area}.

The queries should target:

1. Recent developments and innovations

2. Industry reports and forecasts

3. Research publications and breakthroughs

4. Market analysis and adoption patterns

5. Expert commentary and thought leadership

Return only the search queries, one per line, without numbering or additional explanation.""")

]

config = GenerationConfig(temperature=0.7, max_tokens=500)

response = self.llm.generate(messages, config)

# Parse queries from response

queries = [q.strip() for q in response.strip().split('\n') if q.strip()]

return queries

def _extract_content_samples(self, results: List[SearchResult], max_samples: int = 20) -> List[Dict[str, str]]:

"""

Extract content from search results.

Args:

results: List of search results

max_samples: Maximum number of content samples to extract

Returns:

List of dictionaries containing URL and extracted content

"""

content_samples = []

for result in results[:max_samples]:

content = self.content_extractor.extract_summary(result.url, max_length=2000)

if content:

content_samples.append({

'url': result.url,

'title': result.title,

'content': content

})

return content_samples

def _identify_trends(self, topic_area: str, content_samples: List[Dict[str, str]]) -> List[str]:

"""

Identify potential trends from content samples.

Args:

topic_area: Topic area being analyzed

content_samples: Extracted content from web sources

Returns:

List of trend names

"""

# Compile content summaries

content_summary = "\n\n".join([

f"Source: {sample['title']}\n{sample['content'][:500]}"

for sample in content_samples[:10]

])

messages = [

Message(role='system', content=self.system_prompt),

Message(role='user', content=f"""Based on the following content about {topic_area}, identify 5-7 distinct emerging trends or patterns.

Content samples:

{content_summary}

List the trend names only, one per line. Each trend name should be concise (2-5 words) and descriptive.""")

]

config = GenerationConfig(temperature=0.7, max_tokens=500)

response = self.llm.generate(messages, config)

# Parse trend names

trends = [t.strip() for t in response.strip().split('\n') if t.strip()]

return trends

def _analyze_single_trend(self, topic_area: str, trend_name: str, all_results: List[SearchResult]) -> Optional[TrendAnalysis]:

"""

Perform detailed analysis of a single trend.

Args:

topic_area: Topic area being analyzed

trend_name: Name of the trend to analyze

all_results: All search results for reference

Returns:

TrendAnalysis object or None if analysis fails

"""

# Find relevant sources for this specific trend

relevant_sources = self._find_relevant_sources(trend_name, all_results)

# Extract detailed content

detailed_content = []

for source in relevant_sources[:5]:

content = self.content_extractor.extract_summary(source.url, max_length=1500)

if content:

detailed_content.append({

'url': source.url,

'title': source.title,

'content': content

})

if not detailed_content:

return None

# Compile context for analysis

context = "\n\n".join([

f"Source: {item['title']}\nURL: {item['url']}\n{item['content']}"

for item in detailed_content

])

# Request comprehensive analysis

messages = [

Message(role='system', content=self.system_prompt),

Message(role='user', content=f"""Analyze the trend "{trend_name}" in the context of {topic_area}.

Based on the following sources, provide a comprehensive analysis:

{context}

Your analysis must include:

1. TREND CLASSIFICATION: Classify this as a fad, micro trend, trend, macro trend, or mega trend based on the criteria provided in your instructions.

2. SUMMARY: A concise 2-3 sentence summary of what this trend represents.

3. TECHNOLOGY IMPACT: How this trend affects or will affect technology development, including specific technologies, platforms, or approaches.

4. SCIENCE IMPACT: How this trend influences scientific research, methodologies, or understanding in relevant fields.

5. PRODUCT IMPACT: How this trend affects or will affect products, services, and market offerings.

6. KEY INDICATORS: List 3-5 specific, observable indicators that demonstrate this is a genuine trend rather than speculation.

7. TIME HORIZON: Estimated timeframe for significant impact (e.g., "1-2 years", "5-10 years").

8. CONFIDENCE LEVEL: Your confidence in this analysis on a scale of 0.0 to 1.0, with justification.

Format your response as follows:

CLASSIFICATION: [category]

SUMMARY: [summary text]

TECHNOLOGY_IMPACT: [impact description]

SCIENCE_IMPACT: [impact description]

PRODUCT_IMPACT: [impact description]

KEY_INDICATORS: [indicator 1] | [indicator 2] | [indicator 3]

TIME_HORIZON: [timeframe]

CONFIDENCE: [0.0-1.0]""")

]

config = GenerationConfig(temperature=0.3, max_tokens=2000)

response = self.llm.generate(messages, config)

# Parse the structured response

analysis_dict = self._parse_analysis_response(response)

if not analysis_dict:

return None

# Select recommended URLs

recommended_urls = [item['url'] for item in detailed_content[:3]]

# Create TrendAnalysis object

return TrendAnalysis(

trend_name=trend_name,

category=self._parse_category(analysis_dict.get('CLASSIFICATION', 'trend')),

summary=analysis_dict.get('SUMMARY', ''),

technology_impact=analysis_dict.get('TECHNOLOGY_IMPACT', ''),

science_impact=analysis_dict.get('SCIENCE_IMPACT', ''),

product_impact=analysis_dict.get('PRODUCT_IMPACT', ''),

key_indicators=analysis_dict.get('KEY_INDICATORS', '').split('|'),

time_horizon=analysis_dict.get('TIME_HORIZON', ''),

confidence_level=float(analysis_dict.get('CONFIDENCE', '0.5')),

sources=relevant_sources[:5],

recommended_urls=recommended_urls

)

def _find_relevant_sources(self, trend_name: str, all_results: List[SearchResult]) -> List[SearchResult]:

"""

Find search results most relevant to a specific trend.

Args:

trend_name: Name of the trend

all_results: All available search results

Returns:

Filtered and sorted list of relevant results

"""

# Simple relevance scoring based on keyword matching

scored_results = []

trend_keywords = set(trend_name.lower().split())

for result in all_results:

text = f"{result.title} {result.snippet}".lower()

score = sum(1 for keyword in trend_keywords if keyword in text)

if score > 0:

scored_results.append((score, result))

# Sort by relevance score

scored_results.sort(reverse=True, key=lambda x: x[0])

return [result for score, result in scored_results]

def _parse_analysis_response(self, response: str) -> Dict[str, str]:

"""

Parse structured analysis response from LLM.

Args:

response: LLM response text

Returns:

Dictionary of parsed fields

"""

result = {}

current_field = None

current_value = []

for line in response.split('\n'):

line = line.strip()

if not line:

continue

# Check if this is a field header

if ':' in line:

parts = line.split(':', 1)

field_name = parts[0].strip().upper()

# Save previous field if exists

if current_field:

result[current_field] = ' '.join(current_value).strip()

# Start new field

current_field = field_name

current_value = [parts[1].strip()] if len(parts) > 1 else []

elif current_field:

# Continue current field

current_value.append(line)

# Save last field

if current_field:

result[current_field] = ' '.join(current_value).strip()

return result

def _parse_category(self, category_str: str) -> TrendCategory:

"""

Parse trend category from string.

Args:

category_str: Category string from analysis

Returns:

TrendCategory enum value

"""

category_lower = category_str.lower().replace(' ', '_').replace('-', '_')

for category in TrendCategory:

if category.value in category_lower or category_lower in category.value:

return category

return TrendCategory.TREND # Default fallback

The TrendAnalysisEngine represents the heart of our system. It orchestrates the entire trend discovery workflow, from generating search queries through producing comprehensive trend analyses. The engine breaks down the complex task into manageable steps, each with a specific responsibility.

The query generation phase leverages the LLM to create targeted search queries that explore different facets of the topic area. Rather than using generic searches, the system generates queries designed to uncover recent developments, industry reports, research publications, market analyses, and expert commentary.

The content extraction phase retrieves and processes information from web sources, filtering and summarizing content to make it suitable for analysis. This step is crucial because raw web content often contains noise that can confuse the analysis process.

The trend identification phase analyzes the collected content to identify distinct patterns and emerging phenomena. The LLM examines the information holistically, looking for recurring themes, novel developments, and significant shifts in the domain.

Finally, the detailed analysis phase performs deep dives into each identified trend, classifying it according to trend research frameworks, assessing its impact across multiple dimensions, and providing evidence-based justifications for the classification.

STEP FOUR: CREATING THE USER INTERFACE AND ORCHESTRATION LAYER

With our core components in place, we need to create a user-facing interface that makes the trend discovery agent accessible and easy to use. This layer handles user input, manages the analysis workflow, and presents results in a clear, actionable format.

from typing import Optional

import json

class TrendDiscoveryAgent:

"""

Main interface for the trend discovery system.

Orchestrates all components and provides user-facing functionality.

"""

def __init__(self, llm: LLMInterface, search_provider: SearchInterface):

"""

Initialize the trend discovery agent.

Args:

llm: Language model interface

search_provider: Search provider interface

"""

self.llm = llm

self.search_provider = search_provider

self.content_extractor = WebContentExtractor()

self.analysis_engine = TrendAnalysisEngine(llm, search_provider, self.content_extractor)

def discover_trends(self, topic_area: str, num_trends: int = 5) -> str:

"""

Discover and analyze trends in a given topic area.

Args:

topic_area: Domain, discipline, market, or technical subject

num_trends: Number of trends to identify and analyze

Returns:

Formatted report of trend analyses

"""

print(f"\n{'='*80}")

print(f"TREND DISCOVERY AGENT")

print(f"Topic Area: {topic_area}")

print(f"{'='*80}\n")

# Display device information

device_info = self.llm.get_device_info()

print(f"Using {device_info['device_type'].upper()} acceleration")

if 'gpu_name' in device_info:

print(f"GPU: {device_info['gpu_name']}")

print()

# Execute trend analysis

trend_analyses = self.analysis_engine.analyze_topic(topic_area, num_trends)

# Format and return report

report = self._format_report(topic_area, trend_analyses)

return report

def _format_report(self, topic_area: str, analyses: List[TrendAnalysis]) -> str:

"""

Format trend analyses into a comprehensive report.

Args:

topic_area: Topic area analyzed

analyses: List of trend analyses

Returns:

Formatted report string

"""

report_lines = []

report_lines.append(f"\n{'='*80}")

report_lines.append(f"TREND ANALYSIS REPORT: {topic_area.upper()}")

report_lines.append(f"{'='*80}\n")

report_lines.append(f"Total Trends Identified: {len(analyses)}\n")

# Summary table

report_lines.append("TREND OVERVIEW")

report_lines.append("-" * 80)

for i, analysis in enumerate(analyses, 1):

report_lines.append(f"{i}. {analysis.trend_name}")

report_lines.append(f" Category: {analysis.category.value.replace('_', ' ').title()}")

report_lines.append(f" Confidence: {analysis.confidence_level:.2f}")

report_lines.append(f" Time Horizon: {analysis.time_horizon}")

report_lines.append("")

# Detailed analyses

for i, analysis in enumerate(analyses, 1):

report_lines.append(f"\n{'='*80}")

report_lines.append(f"TREND {i}: {analysis.trend_name.upper()}")

report_lines.append(f"{'='*80}\n")

report_lines.append(f"Classification: {analysis.category.value.replace('_', ' ').title()}")

report_lines.append(f"Confidence Level: {analysis.confidence_level:.2f}")

report_lines.append(f"Time Horizon: {analysis.time_horizon}\n")

report_lines.append("SUMMARY")

report_lines.append("-" * 80)

report_lines.append(self._wrap_text(analysis.summary, 80))

report_lines.append("")

report_lines.append("TECHNOLOGY IMPACT")

report_lines.append("-" * 80)

report_lines.append(self._wrap_text(analysis.technology_impact, 80))

report_lines.append("")

report_lines.append("SCIENCE IMPACT")

report_lines.append("-" * 80)

report_lines.append(self._wrap_text(analysis.science_impact, 80))

report_lines.append("")

report_lines.append("PRODUCT IMPACT")

report_lines.append("-" * 80)

report_lines.append(self._wrap_text(analysis.product_impact, 80))

report_lines.append("")

report_lines.append("KEY INDICATORS")

report_lines.append("-" * 80)

for indicator in analysis.key_indicators:

if indicator.strip():

report_lines.append(f" - {indicator.strip()}")

report_lines.append("")

report_lines.append("RECOMMENDED READING")

report_lines.append("-" * 80)

for url in analysis.recommended_urls:

report_lines.append(f" {url}")

report_lines.append("")

return "\n".join(report_lines)

def _wrap_text(self, text: str, width: int = 80) -> str:

"""

Wrap text to specified width while preserving words.

Args:

text: Text to wrap

width: Maximum line width

Returns:

Wrapped text

"""

words = text.split()

lines = []

current_line = []

current_length = 0

for word in words:

if current_length + len(word) + 1 <= width:

current_line.append(word)

current_length += len(word) + 1

else:

if current_line:

lines.append(' '.join(current_line))

current_line = [word]

current_length = len(word)

if current_line:

lines.append(' '.join(current_line))

return '\n'.join(lines)

def save_report(self, report: str, filename: str):

"""

Save trend report to a file.

Args:

report: Report text to save

filename: Output filename

"""

with open(filename, 'w', encoding='utf-8') as f:

f.write(report)

print(f"\nReport saved to: {filename}")

def export_json(self, analyses: List[TrendAnalysis], filename: str):

"""

Export trend analyses to JSON format.

Args:

analyses: List of trend analyses

filename: Output filename

"""

data = {

'trends': [

{

'name': a.trend_name,

'category': a.category.value,

'summary': a.summary,

'technology_impact': a.technology_impact,

'science_impact': a.science_impact,

'product_impact': a.product_impact,

'key_indicators': a.key_indicators,

'time_horizon': a.time_horizon,

'confidence_level': a.confidence_level,

'recommended_urls': a.recommended_urls

}

for a in analyses

]

}

with open(filename, 'w', encoding='utf-8') as f:

json.dump(data, f, indent=2)

print(f"\nJSON export saved to: {filename}")

The TrendDiscoveryAgent class provides the primary interface for users to interact with the system. It encapsulates all the complexity of the underlying components and presents a simple, intuitive API. Users can discover trends with a single method call, and the system handles all the orchestration automatically.

The report formatting functionality creates human-readable output that presents trend analyses in a structured, easy-to-digest format. The report includes both a high-level overview and detailed analyses for each trend, making it suitable for both quick scanning and in-depth review.

STEP FIVE: ENHANCING TREND CLASSIFICATION WITH RESEARCH METHODOLOGIES

To ensure our trend classifications are rigorous and defensible, we need to incorporate established methodologies from trend research. This involves implementing scoring mechanisms that evaluate trends across multiple dimensions and apply objective criteria for classification.

from typing import Dict, List, Tuple

from dataclasses import dataclass

@dataclass

class TrendMetrics:

"""Quantitative metrics for trend evaluation."""

adoption_velocity: float # Rate of adoption (0.0 to 1.0)

market_breadth: float # Geographic and demographic reach (0.0 to 1.0)

investment_level: float # Financial investment and resources (0.0 to 1.0)

innovation_intensity: float # Degree of novelty and disruption (0.0 to 1.0)

media_attention: float # Level of media coverage and discussion (0.0 to 1.0)

expert_consensus: float # Agreement among domain experts (0.0 to 1.0)

sustainability: float # Long-term viability indicators (0.0 to 1.0)

class TrendClassifier:

"""

Advanced trend classification using multi-dimensional analysis.

Implements methodologies from academic trend research.

"""

def __init__(self, llm: LLMInterface):

"""

Initialize the trend classifier.

Args:

llm: Language model interface for metric extraction

"""

self.llm = llm

def extract_metrics(self, trend_name: str, content_samples: List[Dict[str, str]]) -> TrendMetrics:

"""

Extract quantitative metrics from content about a trend.

Args:

trend_name: Name of the trend

content_samples: Content samples discussing the trend

Returns:

TrendMetrics object with scored dimensions

"""

# Compile content for analysis

context = "\n\n".join([

f"{sample['title']}\n{sample['content'][:800]}"

for sample in content_samples[:5]

])

prompt = f"""Analyze the following content about the trend "{trend_name}" and score it across seven dimensions on a scale from 0.0 to 1.0.

Content:

{context}

Provide scores for each dimension based on evidence in the content:

1. ADOPTION_VELOCITY: How quickly is this trend being adopted? (0.0 = very slow/stagnant, 1.0 = explosive growth)

2. MARKET_BREADTH: How broad is the geographic and demographic reach? (0.0 = very narrow niche, 1.0 = global and cross-demographic)

3. INVESTMENT_LEVEL: What is the level of financial investment and resource allocation? (0.0 = minimal investment, 1.0 = massive investment from multiple sources)

4. INNOVATION_INTENSITY: How novel and disruptive is this trend? (0.0 = incremental improvement, 1.0 = paradigm-shifting innovation)

5. MEDIA_ATTENTION: What is the level of media coverage and public discussion? (0.0 = minimal coverage, 1.0 = extensive mainstream coverage)

6. EXPERT_CONSENSUS: What is the level of agreement among domain experts? (0.0 = highly controversial/disputed, 1.0 = strong expert consensus)

7. SUSTAINABILITY: What are the indicators of long-term viability? (0.0 = likely to fade quickly, 1.0 = strong fundamentals for longevity)

Format your response as:

ADOPTION_VELOCITY: [score]

MARKET_BREADTH: [score]

INVESTMENT_LEVEL: [score]

INNOVATION_INTENSITY: [score]

MEDIA_ATTENTION: [score]

EXPERT_CONSENSUS: [score]

SUSTAINABILITY: [score]"""

messages = [

Message(role='user', content=prompt)

]

config = GenerationConfig(temperature=0.2, max_tokens=500)

response = self.llm.generate(messages, config)

# Parse scores

scores = self._parse_metric_scores(response)

return TrendMetrics(

adoption_velocity=scores.get('ADOPTION_VELOCITY', 0.5),

market_breadth=scores.get('MARKET_BREADTH', 0.5),

investment_level=scores.get('INVESTMENT_LEVEL', 0.5),

innovation_intensity=scores.get('INNOVATION_INTENSITY', 0.5),

media_attention=scores.get('MEDIA_ATTENTION', 0.5),

expert_consensus=scores.get('EXPERT_CONSENSUS', 0.5),

sustainability=scores.get('SUSTAINABILITY', 0.5)

)

def _parse_metric_scores(self, response: str) -> Dict[str, float]:

"""

Parse metric scores from LLM response.

Args:

response: LLM response text

Returns:

Dictionary mapping metric names to scores

"""

scores = {}

for line in response.split('\n'):

line = line.strip()

if ':' in line:

parts = line.split(':', 1)

metric_name = parts[0].strip().upper()

try:

score_str = parts[1].strip()

score = float(score_str)

scores[metric_name] = max(0.0, min(1.0, score))

except ValueError:

continue

return scores

def classify_from_metrics(self, metrics: TrendMetrics) -> Tuple[TrendCategory, float]:

"""

Classify a trend based on its metrics.

Args:

metrics: TrendMetrics object

Returns:

Tuple of (TrendCategory, confidence_score)

"""

# Calculate composite scores for different aspects

reach_score = (metrics.market_breadth + metrics.adoption_velocity) / 2

impact_score = (metrics.innovation_intensity + metrics.investment_level) / 2

longevity_score = (metrics.sustainability + metrics.expert_consensus) / 2

# Overall trend strength

overall_strength = (reach_score + impact_score + longevity_score) / 3

# Classification logic based on research frameworks

if longevity_score < 0.3 or metrics.sustainability < 0.25:

category = TrendCategory.FAD

confidence = 0.7 + (0.3 * (1.0 - longevity_score))

elif reach_score < 0.4 and metrics.market_breadth < 0.35:

category = TrendCategory.MICRO_TREND

confidence = 0.6 + (0.3 * metrics.expert_consensus)

elif overall_strength >= 0.75 and longevity_score >= 0.7 and reach_score >= 0.7:

if metrics.market_breadth >= 0.8 and impact_score >= 0.75:

category = TrendCategory.MEGA_TREND

confidence = 0.65 + (0.35 * overall_strength)

else:

category = TrendCategory.MACRO_TREND

confidence = 0.7 + (0.25 * overall_strength)

elif overall_strength >= 0.5:

category = TrendCategory.TREND

confidence = 0.6 + (0.35 * overall_strength)

else:

category = TrendCategory.MICRO_TREND

confidence = 0.55 + (0.3 * overall_strength)

return category, confidence

The TrendClassifier implements a sophisticated multi-dimensional evaluation framework. Rather than relying solely on the LLM's judgment, it extracts quantitative metrics across seven key dimensions and applies objective classification rules based on these metrics. This approach combines the LLM's ability to understand nuanced content with rigorous analytical frameworks from trend research.

The seven dimensions capture different aspects of trend significance. Adoption velocity measures how quickly the trend is spreading. Market breadth assesses geographic and demographic reach. Investment level indicates the financial resources being allocated. Innovation intensity evaluates the degree of novelty and disruption. Media attention reflects public awareness and discussion. Expert consensus measures agreement among domain specialists. Sustainability assesses long-term viability indicators.

By scoring trends across these dimensions and applying classification rules, we ensure that our trend categorizations are defensible and grounded in observable evidence rather than subjective impressions.

STEP SIX: IMPLEMENTING CACHING AND OPTIMIZATION

To improve performance and reduce redundant computations, we implement caching mechanisms that store intermediate results and enable efficient reuse of previously analyzed content.

import hashlib

import pickle

import os

from pathlib import Path

from typing import Optional, Any

from datetime import datetime, timedelta

class CacheManager:

"""

Manages caching of search results, extracted content, and analyses.

Improves performance by avoiding redundant operations.

"""

def __init__(self, cache_dir: str = ".trend_cache", ttl_hours: int = 24):

"""

Initialize the cache manager.

Args:

cache_dir: Directory for cache storage

ttl_hours: Time-to-live for cached items in hours

"""

self.cache_dir = Path(cache_dir)

self.cache_dir.mkdir(exist_ok=True)

self.ttl = timedelta(hours=ttl_hours)

def _get_cache_key(self, key_data: str) -> str:

"""

Generate a cache key from input data.

Args:

key_data: Data to generate key from

Returns:

Cache key string

"""

return hashlib.md5(key_data.encode()).hexdigest()

def get(self, key: str) -> Optional[Any]:

"""

Retrieve an item from cache if it exists and is not expired.

Args:

key: Cache key

Returns:

Cached item or None if not found or expired

"""

cache_key = self._get_cache_key(key)

cache_file = self.cache_dir / f"{cache_key}.pkl"

if not cache_file.exists():

return None

# Check if cache has expired

file_time = datetime.fromtimestamp(cache_file.stat().st_mtime)

if datetime.now() - file_time > self.ttl:

cache_file.unlink()

return None

# Load cached data

try:

with open(cache_file, 'rb') as f:

return pickle.load(f)

except Exception as e:

print(f"Cache read error: {e}")

return None

def set(self, key: str, value: Any):

"""

Store an item in cache.

Args:

key: Cache key

value: Value to cache

"""

cache_key = self._get_cache_key(key)

cache_file = self.cache_dir / f"{cache_key}.pkl"

try:

with open(cache_file, 'wb') as f:

pickle.dump(value, f)

except Exception as e:

print(f"Cache write error: {e}")

def clear(self):

"""Clear all cached items."""

for cache_file in self.cache_dir.glob("*.pkl"):

cache_file.unlink()

The CacheManager provides a simple but effective caching layer that stores search results, extracted content, and intermediate analyses. By caching these expensive operations, we significantly reduce the time required for subsequent analyses of the same or similar topics. The time-to-live mechanism ensures that cached data remains reasonably fresh while still providing performance benefits.

PRODUCTION-READY COMPLETE IMPLEMENTATION

The following complete implementation integrates all components into a production-ready system. This code represents a fully functional trend discovery agent that can be deployed and used immediately.

#!/usr/bin/env python3

"""

Trend Discovery Agent - Production Implementation

A comprehensive LLM-powered system for discovering and analyzing emerging trends

in any topic area. Supports both local and remote LLMs with GPU acceleration.

Usage:

python trend_agent.py --topic "Artificial Intelligence" --num-trends 5

"""

import argparse

import sys

import time

import os

from abc import ABC, abstractmethod

from dataclasses import dataclass

from typing import List, Dict, Optional, Any, Tuple

from datetime import datetime, timedelta

from enum import Enum

import hashlib

import pickle

from pathlib import Path

# Third-party imports

import torch

from transformers import AutoModelForCausalLM, AutoTokenizer

import requests

from bs4 import BeautifulSoup

from duckduckgo_search import DDGS

import re

# ============================================================================

# DATA STRUCTURES

# ============================================================================

@dataclass

class GenerationConfig:

"""Configuration parameters for text generation."""

temperature: float = 0.7

max_tokens: int = 2048

top_p: float = 0.9

frequency_penalty: float = 0.0

presence_penalty: float = 0.0

stop_sequences: Optional[List[str]] = None

@dataclass

class Message:

"""Represents a single message in a conversation."""

role: str

content: str

@dataclass

class SearchResult:

"""Represents a single search result."""

title: str

url: str

snippet: str

published_date: Optional[datetime] = None

source: Optional[str] = None

class TrendCategory(Enum):

"""Classification categories for identified trends."""

FAD = "fad"

MICRO_TREND = "micro_trend"

TREND = "trend"

MACRO_TREND = "macro_trend"

MEGA_TREND = "mega_trend"

@dataclass

class TrendMetrics:

"""Quantitative metrics for trend evaluation."""

adoption_velocity: float

market_breadth: float

investment_level: float

innovation_intensity: float

media_attention: float

expert_consensus: float

sustainability: float

@dataclass

class TrendAnalysis:

"""Represents a complete trend analysis."""

trend_name: str

category: TrendCategory

summary: str

technology_impact: str

science_impact: str

product_impact: str

key_indicators: List[str]

time_horizon: str

confidence_level: float

sources: List[SearchResult]

recommended_urls: List[str]

metrics: Optional[TrendMetrics] = None

# ============================================================================

# LLM INTERFACE LAYER

# ============================================================================

class LLMInterface(ABC):

"""Abstract base class for all LLM implementations."""

@abstractmethod

def generate(self, messages: List[Message], config: GenerationConfig) -> str:

"""Generate a response based on the conversation history."""

pass

@abstractmethod

def get_device_info(self) -> Dict[str, Any]:

"""Retrieve information about the compute device being used."""

pass

class LocalLLMProvider(LLMInterface):

"""Local LLM implementation with automatic GPU acceleration."""

def __init__(self, model_name: str, device: Optional[str] = None):

"""Initialize the local LLM provider."""

self.model_name = model_name

self.device = self._determine_device(device)

print(f"Loading model {model_name} on {self.device}...")

self.tokenizer = AutoTokenizer.from_pretrained(model_name)

if self.device == 'cuda':

self.model = AutoModelForCausalLM.from_pretrained(

model_name,

torch_dtype=torch.float16,

device_map='auto'

)

elif self.device == 'mps':

self.model = AutoModelForCausalLM.from_pretrained(

model_name,

torch_dtype=torch.float16

).to('mps')

else:

self.model = AutoModelForCausalLM.from_pretrained(model_name)

self.model.to('cpu')

print(f"Model loaded successfully on {self.device}")

def _determine_device(self, preferred_device: Optional[str]) -> str:

"""Determine the optimal compute device."""

if preferred_device:

return preferred_device

if torch.cuda.is_available():

return 'cuda'

elif torch.backends.mps.is_available():

return 'mps'

else:

return 'cpu'

def generate(self, messages: List[Message], config: GenerationConfig) -> str:

"""Generate response using the local model."""

prompt = self._format_messages(messages)

inputs = self.tokenizer(prompt, return_tensors='pt').to(self.device)

gen_kwargs = {

'max_new_tokens': config.max_tokens,

'temperature': config.temperature,

'top_p': config.top_p,

'do_sample': True,

'pad_token_id': self.tokenizer.eos_token_id

}

with torch.no_grad():

outputs = self.model.generate(**inputs, **gen_kwargs)

full_response = self.tokenizer.decode(outputs[0], skip_special_tokens=True)

response = full_response[len(prompt):].strip()

return response

def _format_messages(self, messages: List[Message]) -> str:

"""Format conversation messages into a prompt string."""

formatted_parts = []

for msg in messages:

if msg.role == 'system':

formatted_parts.append(f"System: {msg.content}")

elif msg.role == 'user':

formatted_parts.append(f"User: {msg.content}")

elif msg.role == 'assistant':

formatted_parts.append(f"Assistant: {msg.content}")

formatted_parts.append("Assistant:")

return "\n\n".join(formatted_parts)

def get_device_info(self) -> Dict[str, Any]:

"""Retrieve information about the compute device."""

info = {

'device_type': self.device,

'model_name': self.model_name

}

if self.device == 'cuda':

info['gpu_name'] = torch.cuda.get_device_name(0)

info['gpu_memory_total'] = torch.cuda.get_device_properties(0).total_memory

info['gpu_memory_allocated'] = torch.cuda.memory_allocated(0)

elif self.device == 'mps':

info['gpu_name'] = 'Apple Silicon'

return info

class RemoteLLMProvider(LLMInterface):

"""Remote LLM implementation for API-based services."""

def __init__(self, api_key: str, model_name: str, base_url: str = "https://api.openai.com/v1"):

"""Initialize the remote LLM provider."""

self.api_key = api_key

self.model_name = model_name

self.base_url = base_url

self.headers = {

'Authorization': f'Bearer {api_key}',

'Content-Type': 'application/json'

}

def generate(self, messages: List[Message], config: GenerationConfig) -> str:

"""Generate response using the remote API."""

api_messages = [

{'role': msg.role, 'content': msg.content}

for msg in messages

]

payload = {

'model': self.model_name,

'messages': api_messages,

'temperature': config.temperature,

'max_tokens': config.max_tokens,

'top_p': config.top_p,

'frequency_penalty': config.frequency_penalty,

'presence_penalty': config.presence_penalty

}

if config.stop_sequences:

payload['stop'] = config.stop_sequences

response = requests.post(

f'{self.base_url}/chat/completions',

headers=self.headers,

json=payload,

timeout=120

)

response.raise_for_status()

result = response.json()

return result['choices'][0]['message']['content']

def get_device_info(self) -> Dict[str, Any]:

"""Retrieve information about the remote service."""

return {

'device_type': 'remote',

'model_name': self.model_name,

'base_url': self.base_url

}

# ============================================================================

# SEARCH INTERFACE LAYER

# ============================================================================

class SearchInterface(ABC):

"""Abstract base class for search providers."""

@abstractmethod

def search(self, query: str, num_results: int = 10, time_filter: Optional[str] = None) -> List[SearchResult]:

"""Execute a search query and return results."""

pass

class DuckDuckGoSearchProvider(SearchInterface):

"""Search provider implementation using DuckDuckGo."""

def __init__(self):

"""Initialize the DuckDuckGo search provider."""

self.ddgs = DDGS()

def search(self, query: str, num_results: int = 10, time_filter: Optional[str] = None) -> List[SearchResult]:

"""Execute a search query using DuckDuckGo."""

try:

search_params = {'max_results': num_results}

if time_filter:

search_params['timelimit'] = time_filter

results = list(self.ddgs.text(query, **search_params))

search_results = []

for result in results:

search_result = SearchResult(

title=result.get('title', ''),

url=result.get('href', ''),

snippet=result.get('body', ''),

source=result.get('source', None)

)

search_results.append(search_result)

return search_results

except Exception as e:

print(f"Search error: {str(e)}")

return []

# ============================================================================

# WEB CONTENT EXTRACTION

# ============================================================================

class WebContentExtractor:

"""Extracts main textual content from web pages."""

def __init__(self, timeout: int = 10):

"""Initialize the web content extractor."""

self.timeout = timeout

self.headers = {

'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36'

}

def extract_content(self, url: str) -> Optional[str]:

"""Extract main textual content from a web page."""

try:

response = requests.get(url, headers=self.headers, timeout=self.timeout)

response.raise_for_status()

soup = BeautifulSoup(response.content, 'html.parser')

for element in soup(['script', 'style', 'nav', 'header', 'footer', 'aside']):

element.decompose()

main_content = soup.find('main') or soup.find('article') or soup.find('body')

if not main_content:

return None

text = main_content.get_text(separator='\n', strip=True)

text = re.sub(r'\n\s*\n', '\n\n', text)

text = re.sub(r' +', ' ', text)

return text

except Exception as e:

print(f"Content extraction error for {url}: {str(e)}")

return None

def extract_summary(self, url: str, max_length: int = 1000) -> Optional[str]:

"""Extract a summary of the web page content."""

content = self.extract_content(url)

if not content:

return None

if len(content) <= max_length:

return content

truncated = content[:max_length]

last_period = truncated.rfind('.')

if last_period > max_length * 0.7:

return truncated[:last_period + 1]

else:

return truncated + '...'

# ============================================================================

# CACHE MANAGEMENT

# ============================================================================

class CacheManager:

"""Manages caching of search results and analyses."""

def __init__(self, cache_dir: str = ".trend_cache", ttl_hours: int = 24):

"""Initialize the cache manager."""

self.cache_dir = Path(cache_dir)

self.cache_dir.mkdir(exist_ok=True)

self.ttl = timedelta(hours=ttl_hours)

def _get_cache_key(self, key_data: str) -> str:

"""Generate a cache key from input data."""

return hashlib.md5(key_data.encode()).hexdigest()

def get(self, key: str) -> Optional[Any]:

"""Retrieve an item from cache if it exists and is not expired."""

cache_key = self._get_cache_key(key)

cache_file = self.cache_dir / f"{cache_key}.pkl"

if not cache_file.exists():

return None

file_time = datetime.fromtimestamp(cache_file.stat().st_mtime)

if datetime.now() - file_time > self.ttl:

cache_file.unlink()

return None

try:

with open(cache_file, 'rb') as f:

return pickle.load(f)

except Exception:

return None

def set(self, key: str, value: Any):

"""Store an item in cache."""

cache_key = self._get_cache_key(key)

cache_file = self.cache_dir / f"{cache_key}.pkl"

try:

with open(cache_file, 'wb') as f:

pickle.dump(value, f)

except Exception as e:

print(f"Cache write error: {e}")

def clear(self):

"""Clear all cached items."""

for cache_file in self.cache_dir.glob("*.pkl"):

cache_file.unlink()

# ============================================================================

# TREND CLASSIFICATION

# ============================================================================

class TrendClassifier:

"""Advanced trend classification using multi-dimensional analysis."""

def __init__(self, llm: LLMInterface):

"""Initialize the trend classifier."""

self.llm = llm

def extract_metrics(self, trend_name: str, content_samples: List[Dict[str, str]]) -> TrendMetrics:

"""Extract quantitative metrics from content about a trend."""