WizardCoder LLM: Versions, Prompt Templates & Hardware Requirements

Updated: 2023-08-31 |
coding
Python

Explore all versions of the model, their file formats like GGML, GPTQ, and HF, and understand the hardware requirements for local inference.

WizardCoder is a language model designed specifically for code generation and understanding complex instructions in the coding domain. Building upon the strong foundation laid by StarCoder and CodeLlama, this model introduces a nuanced level of expertise through its ability to process and execute coding related tasks, setting it apart from other language models.

WizardCoder is using Evol-Instruct  specialized training technique. This allows the model to not only generate code but also to deeply understand and accurately follow complicated instructions. This focus on instruction comprehension makes WizardCoder highly reliable and user-friendly, enabling both experienced developers and coding novices to execute their projects more efficiently

Hardware requirements

The performance of an WizardCoder model depends heavily on the hardware it's running on. For recommendations on the best computer hardware configurations to handle WizardCoder models smoothly, check out this guide: Best Computer for Running LLaMA and LLama-2 Models.

Below are the WizardCoder hardware requirements for 4-bit quantization:

For 7B Parameter Models

If the 7B WizardCoder-Python-13B-V1.0-GGUF model is what you're after, you gotta think about hardware in two ways. First, for the GPTQ version, you'll want a decent GPU with at least 6GB VRAM. The GTX 1660 or 2060, AMD 5700 XT, or RTX 3050 or 3060 would all work nicely. But for the GGML / GGUF format, it's more about having enough RAM. You'll need around 4 gigs free to run that one smoothly.

Format RAM Requirements VRAM Requirements
GPTQ (GPU inference) 6GB (Swap to Load*) 6GB
GGML / GGUF (CPU inference) 4GB 300MB
Combination of GPTQ and GGML / GGUF (offloading) 2GB 2GB

*RAM needed to load the model initially. Not required for inference. If your system doesn't have quite enough RAM to fully load the model at startup, you can create a swap file to help with the loading.

For 13B Parameter Models

For beefier models like the WizardCoder-Python-13B-V1.0-GGUF, you'll need more powerful hardware. If you're using the GPTQ version, you'll want a strong GPU with at least 10 gigs of VRAM. AMD 6900 XT, RTX 2060 12GB, RTX 3060 12GB, or RTX 3080 would do the trick. For the CPU infgerence (GGML / GGUF) format, having enough RAM is key. You'll want your system to have around 8 gigs available to run it smoothly.

Format RAM Requirements VRAM Requirements
GPTQ (GPU inference) 12GB (Swap to Load*) 10GB
GGML / GGUF (CPU inference) 8GB 500MB
Combination of GPTQ and GGML / GGUF (offloading) 10GB 10GB

*RAM needed to load the model initially. Not required for inference. If your system doesn't have quite enough RAM to fully load the model at startup, you can create a swap file to help with the loading.

For 30B, 33B, and 34B Parameter Models

If you're venturing into the realm of larger models the hardware requirements shift noticeably. GPTQ models benefit from GPUs like the RTX 3080 20GB, A4500, A5000, and the likes, demanding roughly 20GB of VRAM. Conversely, GGML formatted models will require a significant chunk of your system's RAM, nearing 20 GB.

Format RAM Requirements VRAM Requirements
GPTQ (GPU inference) 32GB (Swap to Load*) 20GB
GGML / GGUF (CPU inference) 20GB 500MB
Combination of GPTQ and GGML / GGUF (offloading) 10GB 4GB

*RAM needed to load the model initially. Not required for inference. If your system doesn't have quite enough RAM to fully load the model at startup, you can create a swap file to help with the loading.

Memory speed

When running WizardCoder AI models, you gotta pay attention to how RAM bandwidth and mdodel size impact inference speed. These large language models need to load completely into RAM or VRAM each time they generate a new token (piece of text). For example, a 4-bit 7B billion parameter WizardCoder model takes up around 4.0GB of RAM.

Suppose your have Ryzen 5 5600X processor and DDR4-3200 RAM with theoretical max bandwidth of 50 GBps. In this scenario, you can expect to generate approximately 9 tokens per second. Typically, this performance is about 70% of your theoretical maximum speed due to several limiting factors such as inference sofware, latency, system overhead, and workload characteristics, which prevent reaching the peak speed. To achieve a higher inference speed, say 16 tokens per second, you would need more bandwidth. For example, a system with DDR5-5600 offering around 90 GBps could be enough.

For comparison, high-end GPUs like the Nvidia RTX 3090 boast nearly 930 GBps of bandwidth for their VRAM. The DDR5-6400 RAM can provide up to 100 GB/s. Therefore, understanding and optimizing bandwidth is crucial for running models like WizardCoder efficiently

Recommendations:

  1. For Best Performance: Opt for a machine with a high-end GPU (like NVIDIA's latest RTX 3090 or RTX 4090) or dual GPU setup to accommodate the largest models (65B and 70B). A system with adequate RAM (minimum 16 GB, but 64 GB best) would be optimal.
  2. For Budget Constraints: If you're limited by budget, focus on WizardCoder GGML/GGUF models that fit within the sytem RAM. Remember, while you can offload some weights to the system RAM, it will come at a performance cost.

Remember, these are recommendations, and the actual performance will depend on several factors, including the specific task, model implementation, and other system processes.

CPU requirements

For best performance, a modern multi-core CPU is recommended. An Intel Core i7 from 8th gen onward or AMD Ryzen 5 from 3rd gen onward will work well. CPU with 6-core or 8-core is ideal. Higher clock speeds also improve prompt processing, so aim for 3.6GHz or more.

Having CPU instruction sets like AVX, AVX2, AVX-512 can further improve performance if available. The key is to have a reasonably modern consumer-level CPU with decent core count and clocks, along with baseline vector processing (required for CPU inference with llama.cpp) through AVX2. With those specs, the CPU should handle WizardCoder model size.