| --- |
| license: apache-2.0 |
| library_name: transformers |
| pipeline_tag: text-generation |
| tags: |
| - code |
| - industrial-code |
| - verilog |
| - cuda |
| - triton |
| - chip-design |
| - cad |
| --- |
| |
| # InCoder-32B: Code Foundation Model for Industrial Scenarios |
|
|
| <div align="center"> |
|
|
| [](https://huggingface.co/Multilingual-Multimodal-NLP/IndustrialCoder) |
| [](https://github.com/CSJianYang/Industrial-Coder) |
| [](https://huggingface.co/papers/2603.16790) |
| [](LICENSE) |
|
|
| </div> |
|
|
| ## Model Summary |
|
|
| **InCoder-32B** (Industrial-Coder-32B) is the first 32B-parameter code foundation model purpose-built for industrial code intelligence. While general-purpose code LLMs excel at mainstream software tasks, they often struggle with the unique demands of industrial programming — hardware semantics, specialized language constructs, strict resource constraints, and domain-specific correctness verification. |
|
|
| Presented in the paper [InCoder-32B: Code Foundation Model for Industrial Scenarios](https://huggingface.co/papers/2603.16790), InCoder-32B unifies code intelligence across five industrial domains: |
|
|
| | Domain | Languages & Frameworks | |
| |---|---| |
| | 🔧 **Chip Design** | Verilog, SystemVerilog, RTL | |
| | ⚡ **GPU Kernel Optimization** | CUDA, Triton | |
| | 🖥️ **Embedded Systems** | C/C++, ARM Cortex-M4, STM32 | |
| | 🔨 **Compiler Optimization** | x86-64 ASM, C/C++, LLVM-IR | |
| | 📐 **3D Modeling / CAD** | CadQuery, OpenCascade, Python | |
|
|
| InCoder-32B achieves highly competitive performance on general tasks while establishing the strongest open-source baselines across all evaluated industrial domains. |
|
|
| --- |
|
|
| ## Key Results |
|
|
| ### General Code Benchmarks |
|
|
| | Benchmark | InCoder-32B | |
| |---|---| |
| | SWE-bench Verified | **74.8%** | |
| | LiveCodeBench (Pass@1) | **49.14%** | |
| | BFCL v3 | **60.99%** | |
| | HumanEval+ | **89.6%** | |
| | MBPP+ | **78.3%** | |
| | BigCodeBench (Full) | **49.8%** | |
|
|
| ### Industrial Code Benchmarks |
|
|
| | Benchmark | Domain | InCoder-32B | Best Competing Open-Weight | |
| |---|---|---|---| |
| | VeriScope Score | Chip Design | **80.7** | 83.2 (GLM-5) | |
| | CAD-Coder Compile | 3D Modeling | **82.0%** | 48.0% (Kimi-K2-Thinking) | |
| | KernelBench L1 | GPU Optimization | **22.2%** | 16.2% (GLM-5) | |
| | KernelBench L2 | GPU Optimization | **36.0%** | 28.0% (KernelBench L2) | |
|
|
| > InCoder-32B leads all open-weight baselines on CAD-Coder and KernelBench (all three levels), and even surpasses proprietary models like Claude-Sonnet-4.6 on CAD-Coder IoU and KernelBench L1/L2/L3. |
|
|
| --- |
|
|
| ## Model Architecture |
|
|
| InCoder-32B adopts a standard decoder-only Transformer architecture with the following configuration: |
|
|
| | Hyperparameter | Value | |
| |---|---| |
| | Parameters | ~32B | |
| | Layers | 64 | |
| | Hidden Size | 5,120 | |
| | Max Context Length | 131,072 (128K) | |
| | Positional Encoding | RoPE (θ = 500,000) | |
| | Precision | BFloat16 | |
|
|
| --- |
|
|
| ## Training Pipeline: Code-Flow |
|
|
| InCoder-32B is trained through a three-stage **Code-Flow** pipeline: |
|
|
| ### Stage 1 — Pre-training & Annealing |
| - **Industrial Recall**: Data pipeline using rule-based filtering, FastText classifiers, and semantic retrieval for Verilog, CUDA, firmware C, and CadQuery. |
| - **Refinement**: OCR extraction from technical manuals, multi-level deduplication, and repository-level fork consolidation. |
| - **Training**: 15T total tokens using Autoregressive LM + Fill-in-the-Middle (FIM) objectives. |
|
|
| ### Stage 2 — Mid-Training (Context Extension) |
| Context window extended progressively from 8K to 128K tokens: |
| - **8K → 32K**: Targets file-level tasks like completing RTL modules or kernel functions. |
| - **32K → 128K**: Unlocks long-context capabilities for extended debugging and cross-module projects. |
|
|
| ### Stage 3 — Post-Training |
| 2.5M supervised fine-tuning (SFT) samples constructed from real industrial tasks with execution-grounded verification using toolchains like Icarus Verilog, `nvcc`, and Renode (STM32 simulator). |
|
|
| --- |
|
|
| ## Usage |
|
|
| ### Installation |
|
|
| ```bash |
| pip install transformers accelerate |
| ``` |
|
|
| ### Basic Inference |
|
|
| ```python |
| from transformers import AutoTokenizer, AutoModelForCausalLM |
| import torch |
| |
| model_id = "Multilingual-Multimodal-NLP/IndustrialCoder" |
| |
| tokenizer = AutoTokenizer.from_pretrained(model_id) |
| model = AutoModelForCausalLM.from_pretrained( |
| model_id, |
| torch_dtype=torch.bfloat16, |
| device_map="auto" |
| ) |
| |
| prompt = """Write a synthesizable Verilog module for a UART transmitter (8N1 protocol). |
| The module should accept 8-bit parallel data and serialize it onto a TX line.""" |
| |
| inputs = tokenizer(prompt, return_tensors="pt").to(model.device) |
| outputs = model.generate( |
| **inputs, |
| max_new_tokens=1024, |
| temperature=0.2, |
| do_sample=True, |
| ) |
| print(tokenizer.decode(outputs[0], skip_special_tokens=True)) |
| ``` |
|
|
| ### Fill-in-the-Middle (FIM) |
|
|
| InCoder-32B supports FIM completion for code infilling tasks: |
|
|
| ```python |
| prefix = """// CUDA kernel for RMS Normalization |
| __global__ void rms_norm_kernel(float* output, const float* input, |
| const float* weight, int N, float eps) { |
| int idx = blockIdx.x; |
| """ |
| suffix = """ |
| output[idx * N + tid] = normalized * weight[tid]; |
| }""" |
| |
| fim_prompt = f"<fim_prefix>{prefix}<fim_suffix>{suffix}<fim_middle>" |
| inputs = tokenizer(fim_prompt, return_tensors="pt").to(model.device) |
| outputs = model.generate(**inputs, max_new_tokens=256) |
| print(tokenizer.decode(outputs[0], skip_special_tokens=True)) |
| ``` |
|
|
| --- |
|
|
| ## Limitations & Disclaimers |
|
|
| Based on failure analysis, the model may struggle with: |
| - **API Knowledge**: Linker errors from undefined HAL/CMSIS functions in embedded C. |
| - **Functional Semantics**: Producing compilable but functionally incorrect RTL under complex logic scenarios. |
| - **Optimization**: Correct but sub-optimal GPU kernel performance. |
|
|
| Always review and test generated code in a sandboxed environment. Industrial code (RTL, embedded firmware) requires expert review before deployment. |
|
|
| --- |
|
|
| ## Citation |
|
|
| ```bibtex |
| @article{yang2026incoder, |
| title={InCoder-32B: Code Foundation Model for Industrial Scenarios}, |
| author={Yang, Jian and Zhang, Wei and Wu, Jiajun and Cheng, Junhang and Guo, Shawn |
| and Wang, Haowen and Gu, Weicheng and Du, Yaxin and Li, Joseph and Xu, Fanglin |
| and others}, |
| journal={arXiv preprint arXiv:2603.16790}, |
| year={2026} |
| } |
| ``` |
