AstrAI/assets/docs/design.md

## 1. Why I Created This Project

There are many large language models on the market today, such as GPT, LLaMA, and others, with tens of billions or even hundreds of billions of parameters. But honestly, these models have extremely high hardware requirements, making them inaccessible for ordinary developers. I thought: **Can we create a model that is both useful and can run on ordinary computers?** This is also what most people currently hope for - a locally deployable AI project that achieves complete privatization while maintaining some level of intelligence.

Thus, the AstrAI project was born - 1B parameters, Chinese-English bilingual, supporting dialogue, text generation, RAG retrieval, and the training code is open source!

## 2. System Architecture

The system is divided into the following modules:

```mermaid
flowchart TB
    %% Style definitions
    classDef config fill:#e1f5fe,stroke:#01579b,stroke-width:2px;
    classDef data fill:#e8f5e8,stroke:#1b5e20,stroke-width:2px;
    classDef model fill:#fff3e0,stroke:#e65100,stroke-width:2px;
    classDef trainer fill:#f3e5f5,stroke:#4a148c,stroke-width:2px;
    classDef inference fill:#fce4ec,stroke:#880e4f,stroke-width:2px;
    classDef parallel fill:#e0f2f1,stroke:#004d40,stroke-width:2px;
    classDef scripts fill:#fffbe6,stroke:#f57f17,stroke-width:2px;

    subgraph Config["Config Module (config/)"]
        direction LR
        C1[model_config.py<br/>Model Architecture]
        C2[train_config.py<br/>Training Params]
        C3[param_config.py<br/>Hyperparameters]
        C4[schedule_config.py<br/>Scheduler Config]
    end
    
    subgraph Data["Data Module (data/)"]
        direction LR
        D1[dataset.py<br/>Dataset]
        D2[sampler.py<br/>Sampler]
        D3[serialization.py<br/>Serialization]
        D4[tokenizer.py<br/>Tokenizer]
    end
    
    subgraph Model["Model Module (model/)"]
        direction LR
        M1[transformer.py<br/>Transformer Architecture]
        M2[module.py<br/>Model Components]
    end
    
    subgraph Trainer["Trainer Module (trainer/)"]
        direction TB
        T1[trainer.py<br/>Trainer Entry]
        T2[train_context.py<br/>Training Context]
        T3[strategy.py<br/>Training Strategy]
        T4[schedule.py<br/>LR Scheduler]
        T5[train_callback.py<br/>Callbacks]
        T6[metric_util.py<br/>Metrics]
    end
    
    subgraph Inference["Inference Module (inference/)"]
        direction LR
        I1[generator.py<br/>Text Generation]
        I2[core.py<br/>Inference Core]
        I3[server.py<br/>API Service]
    end
    
    subgraph Parallel["Parallel Module (parallel/)"]
        direction LR
        P1[setup.py<br/>Parallel Init]
        P2[module.py<br/>Parallel Components]
    end
    
    subgraph Scripts["Scripts (scripts/)"]
        direction LR
        S1[tools/<br/>Train & Inference]
        S2[demo/<br/>Demos]
    end

    %% External config input
    Config --> Trainer
    
    %% Training flow
    Trainer -->|Load Model| Model
    Trainer -->|Load Data| Data
    Trainer -->|Setup| Parallel
    
    %% Inference flow
    Inference -->|Use Model| Model
    Inference -->|Use| generator
    
    %% Data dependency
    Data -->|Data Pipeline| Model
    
    %% Parallel dependency
    Parallel -->|Distributed| Trainer
    
    %% Scripts
    Scripts -->|Execute| Trainer
    Scripts -->|Execute| Inference
```

### 1. Configuration Module (config/)
- **model_config.py**: Defines model structure parameters (layers, heads, dimensions, etc.), managed through `ModelConfig`.
- **train_config.py**: Sets training parameters (batch size, training stages PT/SFT/DPO, optimizers, etc.), loaded by `TrainConfig`.
- **param_config.py**: Manages hyperparameters for training and inference.
- **schedule_config.py**: Controls learning rate strategies (cosine annealing) and training progress.

### 2. Data Module (data/)
- **dataset.py**: Dataset handling and loading.
- **sampler.py**: Data sampling for different training stages.
- **serialization.py**: Data serialization and deserialization.
- **tokenizer.py**: Text tokenization and encoding.

### 3. Model Module (model/)
- **transformer.py**: Transformer architecture implementation.
- **module.py**: Model components and layers.

### 4. Trainer Module (trainer/)
- **trainer.py**: Main training entry point.
- **train_context.py**: Training context management (model, optimizer, scheduler, metrics).
- **strategy.py**: Training strategies for PT/SFT/DPO stages.
- **schedule.py**: Learning rate scheduler.
- **train_callback.py**: Training callbacks (checkpoint, early stopping, etc.).
- **metric_util.py**: Metrics calculation and tracking.

### 5. Inference Module (inference/)
- **generator.py**: Text generation with various methods (sync, batch, streaming).
- **core.py**: Inference core with KV cache optimization.
- **server.py**: API service for inference.

### 6. Parallel Module (parallel/)
- **setup.py**: Distributed initialization for multi-GPU/multi-machine training.
- **module.py**: Parallel communication components.

### 7. Scripts (scripts/)
- **tools/**: Main scripts for training and inference (train.py, generate.py, etc.).
- **demo/**: Demo scripts for interactive chat, batch generation, etc.

## 3. Training Process

The common training process for large language models (LLM) typically includes three stages: **Pre-training (PT)**, **Supervised Fine-Tuning (SFT)**, and **Reinforcement Learning from Human Feedback (RLHF)**. This system is designed to support seamless end-to-end flow, achieving efficient switching and state management of different training stages through modular strategies, ensuring the model's capabilities gradually evolve from general language understanding to human-preference-aligned dialogue and instruction execution.

### **2.1 Pre-training Stage**

The pre-training stage aims to build the model's foundational language capabilities and general knowledge representation. This stage performs self-supervised learning on large-scale, unlabeled corpora (typically covering hundreds of GB to TB of text data). The model architecture is based on the standard Transformer Decoder, trained through masked language modeling objectives (such as causal language modeling), enabling the model to learn vocabulary, grammar, semantics, and world knowledge embedded in text.

**Core Formula: Causal Language Modeling**

$$
L_{\text{PT}} = - \sum_{t=1}^{T} \log P(x_t \mid x_{\lt t}; \theta)
$$

**Symbol Description:**

- $T$: Sequence length
- $x_t$: The $t$-th token in the sequence
- $x_{<t}$: All tokens before position $t$
- $\theta$: Model parameters
- $P(x_t \mid x_{<t}; \theta)$: The probability of the model predicting the next token given the preceding context

The core of this stage lies in utilizing distributed parallel computing resources to achieve stable optimization of model parameters. The `PTStrategy` in the trainer module is specifically responsible for managing pre-training-specific data sampling, long sequence segmentation, and gradient accumulation logic. At the same time, the hardware adaptation module automatically selects the optimal parallel communication backend (such as NCCL) based on the runtime environment (such as NVIDIA GPU cluster) and performs computation graph optimization to maximize hardware utilization and training throughput.

Additionally, the system achieves zero-copy reading of massive data through the efficient memory-mapped loader (`MmapFileHandler`) in the data module, overcoming traditional IO bottlenecks.

### **2.2 Supervised Fine-Tuning Stage**

Although pre-trained models possess powerful language generation capabilities, they are not yet aligned with following human instructions and engaging in safe, helpful dialogues. The supervised fine-tuning stage aims to bridge this gap. This stage uses high-quality instruction-response paired datasets carefully written by humans.

**Core Formula: Sequence-to-Sequence Conditional Language Modeling**

Let the complete sequence $S = [s_1, s_2, \ldots, s_{P+L}]$, where:

- The first $P$ tokens are prompts and corresponding control tokens: $X = [s_1, \ldots, s_P]$
- The last $L$ tokens are responses and corresponding control tokens: $Y = [s_{P+1}, \ldots, s_{P+L}]$

The loss function is:

$$
L_{\text{SFT}} = - \sum_{t=P+1}^{P+L} \log P(s_t \mid s_{\lt t}; \theta)
$$

The trainer module dynamically switches to the `SFTStrategy`. The core of this strategy is introducing sequence-level supervised learning objectives, such as predicting complete, correct response sequences given instructions. The training context manager (`TrainContext`) is responsible for smoothly loading model states from PT stage checkpoints and initializing new optimizers and learning rate schedulers. This stage not only optimizes model parameters but more importantly guides the model to learn the specific task paradigm of "dialogue," making its output style, content, and format conform to human expectations.

### **2.3 Reinforcement Learning from Human Feedback Stage**

To generate outputs that are more helpful, harmless, and aligned with human preferences, the system further integrates a reinforcement learning stage. The traditional RLHF process includes two core steps: **Reward Model Training** and **Policy Model Fine-tuning**. The system supports policy fine-tuning represented by the Direct Preference Optimization (DPO) algorithm, with multiple engineering optimizations for stability and convergence.

#### **2.3.1 Traditional RLHF (Reward Model Training)**

$$
L_{\text{RM}} = -\mathbb{E}_{(x, y_w, y_l) \sim D} \left[ \log \sigma\left( r_\phi(x, y_w) - r_\phi(x, y_l) \right) \right]
$$

**Symbol Description:**

- $r_\phi(x, y)$: The scalar score given by the reward model with parameters $\phi$
- $y_w, y_l$: The preferred and dispreferred responses for the same prompt $x$
- $\sigma$: Sigmoid function
- $\mathcal{D}$: Human preference dataset

#### **2.3.2 DPO Direct Preference Optimization** (Recommended)

$$
L_{\text{DPO}} = -E_{(x, y_w, y_l) \sim D} \left[ \log \sigma\left( \beta \log \frac{\pi_\theta(y_w \mid x)}{\pi_{\text{ref}}(y_w \mid x)} - \beta \log \frac{\pi_\theta(y_l \mid x)}{\pi_{\text{ref}}(y_l \mid x)} \right) \right]
$$

**Symbol Description:**

- $\pi_\theta(y \mid x)$: The probability of the current policy model generating response $y$
- $\pi_{\text{ref}}(y \mid x)$: The probability of the reference model generating response $y$
- $\beta$: Temperature parameter (typically set to 0.1-0.5)
- Note: Implicitly learning reward function $r(x, y) = \beta \log \frac{\pi_\theta(y \mid x)}{\pi_{\text{ref}}(y \mid x)}$

In this stage, the trainer module enables the `RLHFStrategy` (or similar `DPOStrategy` direct preference optimization strategy). This strategy manages a complex training loop containing the policy model (LLM to be optimized), reference model (usually an SFT model snapshot), and reward model. The system flow is as follows:

1. **Preference Data Collection and Reward Modeling**: First, by collecting human annotators' ranking preferences for multiple model-generated results for the same prompt, a separate reward model (RM) is trained. This model learns to output a scalar reward score for generated text to quantify the degree of alignment with human preferences.
2. **Policy Optimization**: Then, using the reward model as the optimization signal, the SFT model (as the policy) is fine-tuned through reinforcement learning algorithms. The goal of policy optimization is to maximize the expected cumulative reward obtained from the reward model, while constraining the output distribution of the policy model and reference model from deviating too much through a KL divergence penalty term, preventing mode collapse and maintaining generation diversity. The training context manager maintains the states of the policy model, reference model, and reward model (or value function model) simultaneously at this stage, and coordinates complex multi-stage gradient computations.

Through the above three-stage progressive training, the model completes its evolution from a general language foundation to a specialized, highly-aligned dialogue intelligence. The system, through unified `Trainer` interface and strategy pattern design, makes each stage of training highly reusable at the code level, clearly decoupled at the process level, providing an efficient, flexible, and scalable engineering foundation for large-scale language model research and iteration.