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from __future__ import annotations |
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import warnings |
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import logging |
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import os |
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from datetime import datetime |
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from typing import Any, Dict, Optional, Tuple |
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import gradio as gr |
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import numpy as np |
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import pandas as pd |
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import plotly.express as px |
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import plotly.graph_objects as go |
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import google.generativeai as genai |
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from analysis_modules import analyze_time_series, generate_word_cloud, perform_clustering |
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logging.basicConfig(level=logging.INFO, format='%(asctime)s - [%(levelname)s] - (%(filename)s:%(lineno)d) - %(message)s') |
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warnings.filterwarnings('ignore', category=FutureWarning) |
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class Config: |
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APP_TITLE = "π CognitiveEDA: The Adaptive Intelligence Engine" |
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GEMINI_MODEL = 'gemini-1.5-flash-latest' |
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MAX_UI_ROWS = 50000 |
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class DataAnalyzer: |
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"""The complete DataAnalyzer class, now with a fully functional AI engine.""" |
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def __init__(self, df: pd.DataFrame): |
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if not isinstance(df, pd.DataFrame): raise TypeError("Input must be a pandas DataFrame.") |
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self.df = df |
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self._metadata: Optional[Dict[str, Any]] = None |
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logging.info(f"DataAnalyzer instantiated with DataFrame of shape: {self.df.shape}") |
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@property |
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def metadata(self) -> Dict[str, Any]: |
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if self._metadata is None: self._metadata = self._extract_metadata() |
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return self._metadata |
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def _extract_metadata(self) -> Dict[str, Any]: |
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rows, cols = self.df.shape |
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numeric_cols = self.df.select_dtypes(include=np.number).columns.tolist() |
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categorical_cols = self.df.select_dtypes(include=['object', 'category']).columns.tolist() |
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datetime_cols = self.df.select_dtypes(include=['datetime64', 'datetimetz']).columns.tolist() |
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text_cols = [col for col in categorical_cols if self.df[col].dropna().str.len().mean() > 50] |
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high_corr_pairs = [] |
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if len(numeric_cols) > 1: |
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corr_matrix = self.df[numeric_cols].corr().abs() |
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upper_tri = corr_matrix.where(np.triu(np.ones(corr_matrix.shape), k=1).astype(bool)) |
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high_corr_series = upper_tri.stack() |
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high_corr_pairs = (high_corr_series[high_corr_series > 0.75].reset_index().rename(columns={'level_0': 'Feature 1', 'level_1': 'Feature 2', 0: 'Correlation'}).to_dict('records')) |
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return { |
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'shape': (rows, cols), 'columns': self.df.columns.tolist(), |
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'numeric_cols': numeric_cols, 'categorical_cols': categorical_cols, |
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'datetime_cols': datetime_cols, 'text_cols': text_cols, |
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'memory_usage_mb': f"{self.df.memory_usage(deep=True).sum() / 1e6:.2f}", |
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'total_missing': int(self.df.isnull().sum().sum()), |
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'data_quality_score': round((self.df.notna().sum().sum() / self.df.size) * 100, 2), |
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'high_corr_pairs': high_corr_pairs, |
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} |
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def get_profiling_tables(self) -> Tuple[pd.DataFrame, pd.DataFrame, pd.DataFrame]: |
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missing = self.df.isnull().sum() |
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missing_df = pd.DataFrame({'Missing Count': missing, 'Missing Percentage (%)': (missing / len(self.df) * 100).round(2)}).reset_index().rename(columns={'index': 'Column'}).sort_values('Missing Count', ascending=False) |
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numeric_stats = self.df[self.metadata['numeric_cols']].describe(percentiles=[.01, .25, .5, .75, .99]).T |
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numeric_stats_df = numeric_stats.round(3).reset_index().rename(columns={'index': 'Column'}) |
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cat_stats = self.df[self.metadata['categorical_cols']].describe(include=['object', 'category']).T |
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cat_stats_df = cat_stats.reset_index().rename(columns={'index': 'Column'}) |
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return missing_df, numeric_stats_df, cat_stats_df |
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def get_overview_visuals(self) -> Tuple[go.Figure, go.Figure, go.Figure]: |
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meta = self.metadata |
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dtype_counts = self.df.dtypes.astype(str).value_counts() |
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fig_types = px.pie(values=dtype_counts.values, names=dtype_counts.index, title="<b>π Data Type Composition</b>", hole=0.4, color_discrete_sequence=px.colors.qualitative.Pastel) |
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missing_df = self.df.isnull().sum().reset_index(name='count').query('count > 0') |
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fig_missing = px.bar(missing_df, x='index', y='count', title="<b>π³οΈ Missing Values Distribution</b>", labels={'index': 'Column Name', 'count': 'Number of Missing Values'}).update_xaxes(categoryorder="total descending") |
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fig_corr = go.Figure() |
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if len(meta['numeric_cols']) > 1: |
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corr_matrix = self.df[meta['numeric_cols']].corr() |
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fig_corr = px.imshow(corr_matrix, text_auto=".2f", aspect="auto", title="<b>π Correlation Matrix</b>", color_continuous_scale='RdBu_r', zmin=-1, zmax=1) |
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return fig_types, fig_missing, fig_corr |
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def generate_ai_narrative(self, api_key: str, context: Dict[str, Any]) -> str: |
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"""Generates a context-aware AI narrative using the Gemini API.""" |
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logging.info(f"Generating AI narrative with context: {list(context.keys())}") |
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meta = self.metadata |
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data_snippet_md = self.df.head(5).to_markdown(index=False) |
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context_prompt = "**PRIMARY ANALYSIS MODES:**\n" |
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if context.get('is_timeseries'): |
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context_prompt += "- **Time-Series Detected:** Focus on trends, seasonality, and stationarity. Suggest forecasting models.\n" |
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if context.get('has_text'): |
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context_prompt += "- **Long-Form Text Detected:** Note potential for NLP tasks like sentiment analysis or topic modeling.\n" |
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if not context.get('is_timeseries') and not context.get('has_text'): |
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context_prompt += "- **General Tabular Data:** Focus on distributions, correlations, and potential for classification/regression modeling.\n" |
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prompt = f""" |
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As "Cognitive Analyst," an elite AI data scientist, your task is to generate a comprehensive, multi-part data discovery report in Markdown format. |
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{context_prompt} |
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**DATASET METADATA:** |
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- **Shape:** {meta['shape'][0]} rows, {meta['shape'][1]} columns. |
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- **Data Quality Score:** {meta['data_quality_score']}% |
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- **Total Missing Values:** {meta['total_missing']:,} |
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- **Highly Correlated Pairs:** {meta['high_corr_pairs'] if meta['high_corr_pairs'] else 'None detected.'} |
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- **Data Snippet (First 5 Rows):** |
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{data_snippet_md} |
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**REQUIRED REPORT STRUCTURE:** |
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# π AI Data Discovery Report |
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## π 1. Executive Summary |
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* **Primary Objective:** (Deduce the likely purpose of this dataset. What problem could it solve?) |
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* **Key Finding:** (State the single most interesting insight you've discovered.) |
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* **Overall State:** (Briefly comment on the data's quality and readiness for analysis.) |
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## π§ 2. Deep Dive & Quality Assessment |
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* **Structural Profile:** (Describe the dataset's composition: numeric, categorical, text, time-series features.) |
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* **Data Quality Audit:** (Elaborate on the quality score and missing values. Are they a major concern?) |
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* **Redundancy Check:** (Comment on the detected high-correlation pairs and any risks.) |
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## π‘ 3. Actionable Recommendations |
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* **Data Cleaning:** (Provide a specific recommendation for handling missing data or outliers.) |
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* **Feature Engineering:** (Suggest creating a new, valuable feature.) |
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* **Next Analytical Steps:** (Propose a specific hypothesis to test or a suitable ML model to build.) |
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""" |
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try: |
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genai.configure(api_key=api_key) |
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model = genai.GenerativeModel(Config.GEMINI_MODEL) |
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response = model.generate_content(prompt) |
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if not response.parts: |
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blocked_reason = response.prompt_feedback.block_reason.name if response.prompt_feedback else "Unknown" |
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logging.warning(f"AI response blocked. Reason: {blocked_reason}") |
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return f"β **AI Report Generation Blocked by Safety Settings**\n**Reason:** `{blocked_reason}`." |
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return response.text |
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except Exception as e: |
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logging.error(f"Gemini API call failed: {e}", exc_info=True) |
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return f"β **AI Report Generation Failed**\n**Error:** `{str(e)}`" |
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def create_ui(): |
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"""Defines the complete, integrated Gradio user interface.""" |
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def create_histogram(analyzer: DataAnalyzer, col: str) -> go.Figure: |
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if not col or not analyzer: return go.Figure() |
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return px.histogram(analyzer.df, x=col, title=f"<b>Distribution of {col}</b>", marginal="box", template="plotly_white") |
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def create_scatterplot(analyzer: DataAnalyzer, x_col: str, y_col:str, color_col:str) -> go.Figure: |
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if not all([analyzer, x_col, y_col]): return go.Figure() |
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return px.scatter(analyzer.df, x=x_col, y=y_col, color=color_col, title=f"<b>Scatter Plot: {x_col} vs. {y_col}</b>", template="plotly_white") |
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def analyze_single_column(analyzer: DataAnalyzer, col: str) -> Tuple[str, go.Figure]: |
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if not col or not analyzer: return "", go.Figure() |
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series = analyzer.df[col] |
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stats_md = f"### π **Deep Dive: `{col}`**\n- **Data Type:** `{series.dtype}`\n- **Unique Values:** `{series.nunique()}`\n- **Missing:** `{series.isnull().sum()}` ({series.isnull().mean():.2%})\n" |
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if pd.api.types.is_numeric_dtype(series): |
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stats_md += f"- **Mean:** `{series.mean():.3f}` | **Median:** `{series.median():.3f}` | **Std Dev:** `{series.std():.3f}`" |
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fig = create_histogram(analyzer, col) |
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else: |
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stats_md += f"- **Top Value:** `{series.value_counts().index[0]}`" |
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top_n = series.value_counts().nlargest(10) |
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fig = px.bar(top_n, y=top_n.index, x=top_n.values, orientation='h', title=f"<b>Top 10 Categories in `{col}`</b>").update_yaxes(categoryorder="total ascending") |
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return stats_md, fig |
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with gr.Blocks(theme=gr.themes.Soft(primary_hue="indigo", secondary_hue="blue"), title=Config.APP_TITLE) as demo: |
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state_analyzer = gr.State() |
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gr.Markdown(f"<h1>{Config.APP_TITLE}</h1>") |
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gr.Markdown("Upload your data to receive a complete standard analysis, plus specialized dashboards that unlock automatically based on your data's content.") |
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with gr.Row(): |
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upload_button = gr.File(label="1. Upload Data File (CSV, Excel)", file_types=[".csv", ".xlsx", ".xls"], scale=3) |
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api_key_input = gr.Textbox(label="2. Enter Google Gemini API Key", type="password", scale=2) |
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analyze_button = gr.Button("β¨ Build My Dashboard", variant="primary", scale=1) |
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with gr.Tabs(): |
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with gr.Tab("π€ AI Narrative"): |
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ai_report_output = gr.Markdown("### Your AI-generated report will appear here...") |
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with gr.Tab("π Profile"): |
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profile_missing_df, profile_numeric_df, profile_categorical_df = gr.DataFrame(), gr.DataFrame(), gr.DataFrame() |
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with gr.Tab("π Overview Visuals"): |
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with gr.Row(): plot_types, plot_missing = gr.Plot(), gr.Plot() |
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plot_correlation = gr.Plot() |
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with gr.Tab("π¨ Interactive Explorer"): |
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with gr.Row(): |
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with gr.Column(scale=1): dd_hist_col = gr.Dropdown(label="Select Column for Histogram", interactive=True) |
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with gr.Column(scale=2): plot_histogram = gr.Plot() |
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with gr.Row(): |
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with gr.Column(scale=1): |
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dd_scatter_x = gr.Dropdown(label="X-Axis (Numeric)", interactive=True) |
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dd_scatter_y = gr.Dropdown(label="Y-Axis (Numeric)", interactive=True) |
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dd_scatter_color = gr.Dropdown(label="Color By (Optional)", interactive=True) |
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with gr.Column(scale=2): plot_scatter = gr.Plot() |
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with gr.Tab("π Column Deep-Dive"): |
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dd_drilldown_col = gr.Dropdown(label="Select Column to Analyze", interactive=True) |
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with gr.Row(): md_drilldown_stats, plot_drilldown = gr.Markdown(), gr.Plot() |
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with gr.Tab("β Time-Series Analysis", visible=False) as tab_timeseries: |
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with gr.Row(): |
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dd_ts_date = gr.Dropdown(label="Select Date/Time Column", interactive=True) |
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dd_ts_value = gr.Dropdown(label="Select Value Column", interactive=True) |
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plot_ts_decomp, md_ts_stats = gr.Plot(), gr.Markdown() |
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with gr.Tab("π Text Analysis", visible=False) as tab_text: |
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dd_text_col = gr.Dropdown(label="Select Text Column", interactive=True) |
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html_word_cloud = gr.HTML() |
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with gr.Tab("𧩠Clustering (K-Means)", visible=False) as tab_cluster: |
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num_clusters = gr.Slider(minimum=2, maximum=10, value=4, step=1, label="Number of Clusters (K)", interactive=True) |
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plot_cluster, md_cluster_summary = gr.Plot(), gr.Markdown() |
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main_outputs = [ |
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state_analyzer, ai_report_output, |
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profile_missing_df, profile_numeric_df, profile_categorical_df, |
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plot_types, plot_missing, plot_correlation, |
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dd_hist_col, dd_scatter_x, dd_scatter_y, dd_scatter_color, dd_drilldown_col, |
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tab_timeseries, dd_ts_date, dd_ts_value, |
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tab_text, dd_text_col, |
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tab_cluster, num_clusters] |
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analyze_button.click(fn=run_full_analysis, inputs=[upload_button, api_key_input], outputs=main_outputs, show_progress="full") |
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dd_hist_col.change(fn=create_histogram, inputs=[state_analyzer, dd_hist_col], outputs=plot_histogram) |
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scatter_inputs = [state_analyzer, dd_scatter_x, dd_scatter_y, dd_scatter_color] |
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for dd in [dd_scatter_x, dd_scatter_y, dd_scatter_color]: dd.change(fn=create_scatterplot, inputs=scatter_inputs, outputs=plot_scatter) |
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dd_drilldown_col.change(fn=analyze_single_column, inputs=[state_analyzer, dd_drilldown_col], outputs=[md_drilldown_stats, plot_drilldown]) |
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ts_inputs = [state_analyzer, dd_ts_date, dd_ts_value] |
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for dd in [dd_ts_date, dd_ts_value]: dd.change(fn=lambda a, d, v: analyze_time_series(a.df, d, v), inputs=ts_inputs, outputs=[plot_ts_decomp, md_ts_stats]) |
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dd_text_col.change(fn=lambda a, t: generate_word_cloud(a.df, t), inputs=[state_analyzer, dd_text_col], outputs=html_word_cloud) |
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num_clusters.change(fn=lambda a, k: perform_clustering(a.df, a.metadata['numeric_cols'], k), inputs=[state_analyzer, num_clusters], outputs=[plot_cluster, md_cluster_summary]) |
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return demo |
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def run_full_analysis(file_obj: gr.File, api_key: str) -> list: |
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if file_obj is None: raise gr.Error("CRITICAL: No file uploaded.") |
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if not api_key: raise gr.Error("CRITICAL: Gemini API key is missing.") |
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try: |
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logging.info(f"Processing uploaded file: {file_obj.name}") |
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df = pd.read_csv(file_obj.name) if file_obj.name.endswith('.csv') else pd.read_excel(file_obj.name) |
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if len(df) > Config.MAX_UI_ROWS: df = df.sample(n=Config.MAX_UI_ROWS, random_state=42) |
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analyzer = DataAnalyzer(df) |
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meta = analyzer.metadata |
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ai_context = {'is_timeseries': bool(meta['datetime_cols']), 'has_text': bool(meta['text_cols'])} |
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ai_report = analyzer.generate_ai_narrative(api_key, context=ai_context) |
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missing_df, num_df, cat_df = analyzer.get_profiling_tables() |
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fig_types, fig_missing, fig_corr = analyzer.get_overview_visuals() |
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update_hist_dd = gr.Dropdown(choices=meta['numeric_cols'], value=meta['numeric_cols'][0] if meta['numeric_cols'] else None) |
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update_scatter_x = gr.Dropdown(choices=meta['numeric_cols'], value=meta['numeric_cols'][0] if meta['numeric_cols'] else None) |
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update_scatter_y = gr.Dropdown(choices=meta['numeric_cols'], value=meta['numeric_cols'][1] if len(meta['numeric_cols']) > 1 else None) |
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update_scatter_color = gr.Dropdown(choices=meta['columns']) |
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update_drill_dd = gr.Dropdown(choices=meta['columns']) |
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show_ts_tab = gr.Tab(visible=bool(meta['datetime_cols'])) |
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update_ts_date_dd, update_ts_value_dd = gr.Dropdown(choices=meta['datetime_cols']), gr.Dropdown(choices=meta['numeric_cols']) |
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show_text_tab, update_text_dd = gr.Tab(visible=bool(meta['text_cols'])), gr.Dropdown(choices=meta['text_cols']) |
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show_cluster_tab, update_cluster_slider = gr.Tab(visible=len(meta['numeric_cols']) > 1), gr.Slider(visible=len(meta['numeric_cols']) > 1) |
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return [analyzer, ai_report, missing_df, num_df, cat_df, fig_types, fig_missing, fig_corr, |
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update_hist_dd, update_scatter_x, update_scatter_y, update_scatter_color, update_drill_dd, |
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show_ts_tab, update_ts_date_dd, update_ts_value_dd, |
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show_text_tab, update_text_dd, |
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show_cluster_tab, update_cluster_slider] |
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except Exception as e: |
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logging.error(f"A critical error occurred: {e}", exc_info=True) |
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raise gr.Error(f"Analysis Failed! Error: {str(e)}") |
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if __name__ == "__main__": |
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app_instance = create_ui() |
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app_instance.launch(debug=True, server_name="0.0.0.0") |
