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Data Interpreter Multi-Agent Pipeline #469

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# Multi-Agent Pipeline for Complex Task Solving

This example will show:

- How to decompose a complex task into manageable subtasks using a Planner Agent.
- How to iteratively solve, verify, and replan subtasks using Solver, Verifier, and Replanning Agents.
- How to synthesize subtask results into a final answer using a Synthesizer Agent.

## Background

In complex problem-solving, it's often necessary to break down tasks into smaller, more manageable subtasks. A multi-agent system can handle this by assigning specialized agents to different aspects of the problem-solving process. This example demonstrates how to implement such a pipeline using specialized agents for planning, solving, verifying, replanning, and synthesizing tasks.

The pipeline consists of the following agents:

- **PlannerAgent**: Decomposes the overall task into subtasks.
- **SolverAgent** (using `ReActAgent`): Solves each subtask.
- **VerifierAgent**: Verifies the solutions to each subtask.
- **ReplanningAgent**: Replans or decomposes subtasks if verification fails.
- **SynthesizerAgent**: Synthesizes the results of all subtasks into a final answer.

By orchestrating these agents, the system can handle complex tasks that require iterative processing and dynamic adjustment based on intermediate results.

## Tested Models

These models are tested in this example. For other models, some modifications may be needed.

- **Anthropic Claude:** `claude-3-5-sonnet-20240620`, `claude-3-5-sonnet-20241022`, `claude-3-5-haiku-20241022` (accessed via the `litellm` package configuration).
- **OpenAI:** `GPT4-o`, `GPT4-o-mini`.
- **DashScope:** `qwen-max`, `qwen-max-1201`.

## Prerequisites

To run this example, you need:

- **Agentscope** package installed:

```bash
pip install agentscope
```

- **Environment Variables**: Set up the following environment variables with your API keys. This can be done in a `.env` file or directly in your environment.

- `OPENAI_API_KEY` (if using OpenAI models)
- `DASHSCOPE_API_KEY` (if using DashScope models)
- `ANTHROPIC_API_KEY` (required for using Claude models via `litellm`)

- **Code Execution Environment**: Modify the code execution restrictions in Agentscope to allow the necessary operations for your tasks. Specifically, comment out the following `os` functions and `sys` modules in the `os_funcs_to_disable` and `sys_modules_to_disable` lists located in:

```plaintext
src/agentscope/service/execute_code/exec_python.py
```

**Comment out these `os` functions in `os_funcs_to_disable`:**

- `putenv`
- `remove`
- `unlink`
- `getcwd`
- `chdir`

**Comment out these modules in `sys_modules_to_disable`:**

- `joblib`

This step enables the executed code by the agents to perform required operations that are otherwise restricted by default. Ensure you understand the security implications of modifying these restrictions.

- Comment out the following in `src/agentscope/utils/common.py`:
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Why we have specific working directory here?

```python
@contextlib.contextmanager
def create_tempdir() -> Generator:
"""
A context manager that creates a temporary directory and changes the
current working directory to it.
The implementation of this contextmanager are borrowed from
https://github.com/openai/human-eval/blob/master/human_eval/execution.py
"""
with tempfile.TemporaryDirectory() as dirname:
with _chdir(dirname):
yield dirname
```

and add
```python
@contextlib.contextmanager
def create_tempdir() -> Generator:
"""
A context manager that uses the curreny directory.
"""
yield
```
to use the current directory for code execution.

- **Optional Packages** (if needed for specific tools or extended functionalities):

- `litellm` for interacting with the Claude model.

```bash
pip install litellm
```

- Additional Python libraries as required by your code (e.g., `csv`, `dotenv`).

Ensure that you have the necessary API access and that your environment is correctly configured to use the specified models.

## Examples

This section demonstrates the pipeline's effectiveness on two different complex tasks. For your own task, replace `"Your task description here."` with your task in `input_task` in `di_multiagent.py` script.

### Task 1: Mathematical Problem Solving

**Problem**: Solve this math problem: The greatest common divisor of positive integers m and n is 6. The least common multiple of m and n is 126. What is the least possible value of m + n?

**Solution Output**:
```
Based on the results of the subtasks, we can synthesize the solution to the overall task as follows:

1. Functions for calculating GCD and LCM were defined and saved.
2. Possible pairs of m and n that satisfy the conditions (GCD = 6 and LCM = 126) were found to be (6, 126) and (18, 42).
3. The least possible value of m + n was calculated.

The answer to the overall task is:

The least possible value of m + n is 60, where m = 18 and n = 42.

This solution satisfies all the given conditions:
- The greatest common divisor of m and n is 6.
- The least common multiple of m and n is 126.
- The sum of m and n (18 + 42 = 60) is the least possible value among the valid pairs.
```

### Task 2: Titanic Survival Prediction

**Problem**: Predict passenger survival outcomes using the Titanic dataset. Perform data analysis, preprocessing, feature engineering, and modeling. Report accuracy on the evaluation data.

**Solution Output**:
```
The Titanic passenger survival prediction task has been successfully completed. Here's a summary of the process and results:

1. Data Analysis:
- The training dataset contained 712 entries with 12 columns.
- The target variable 'Survived' had a 37.5% overall survival rate.
- Key factors influencing survival included Sex (females had a higher survival rate) and Passenger Class.

2. Data Preprocessing and Feature Engineering:
- Missing values were handled through imputation or dropping columns.
- New features were created, including 'Title' and 'FamilySize'.
- Categorical variables were encoded, and unnecessary columns were dropped.
- The final preprocessed dataset had 712 samples and 10 features.

3. Modeling:
- Three models were trained and evaluated: Logistic Regression, Random Forest, and Gradient Boosting.
- Gradient Boosting performed the best in cross-validation with an accuracy of 0.8160.

4. Final Evaluation:
- The best model (Gradient Boosting) was used to make predictions on the evaluation dataset.
- The final accuracy on the evaluation data (179 samples) was 0.8212 (82.12%).
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