huggingface/candle
1
0
Fork 0
mirror of https://github.com/huggingface/candle.git synced 2025-06-15 02:16:37 +00:00
Code Issues Packages Projects Releases Wiki Activity

Qwen3 quantized implementation (#2939)

Browse Source 
* fixed quantized_phi3 implementation

* quantized_qwen3 implementation

* Update quantized_phi3.rs

* Update quantized_phi3.rs

* add quantized_qwen3 example

* Clippy fixes.

* Cleanup.

---------

Co-authored-by: Laurent <laurent.mazare@gmail.com>
This commit is contained in:
Lucien Thomas
2025-05-08 08:06:10 -05:00
committed by GitHub
parent 637473cb5e
commit 3d05f5cf3d
5 changed files with 755 additions and 1 deletions
Download Patch File Download Diff File Expand all files Collapse all files

11
candle-examples/examples/quantized-qwen3/README.md Normal file
View File

@ -0,0 +1,11 @@
# candle-quantized-qwen3
[Qwen3]((https://qwenlm.github.io/blog/qwen3/)) is an upgraded version of Qwen2.5, released by Alibaba Cloud.
## Running the example
```bash
cargo run --example quantized-qwen3 --release -- --prompt "Write a function to count prime numbers up to N."
```
0.6b is used by default, 1.7b, 4b, 8b, 14b, and 32b models are available via `--model` argument.

314
candle-examples/examples/quantized-qwen3/main.rs Normal file
View File

@ -0,0 +1,314 @@
#[cfg(feature = "mkl")]
extern crate intel_mkl_src;
#[cfg(feature = "accelerate")]
extern crate accelerate_src;
use clap::{Parser, ValueEnum};
use std::io::Write;
use tokenizers::Tokenizer;
use candle::quantized::gguf_file;
use candle::Tensor;
use candle_transformers::generation::{LogitsProcessor, Sampling};
use candle_examples::token_output_stream::TokenOutputStream;
use candle_transformers::models::quantized_qwen3::ModelWeights as Qwen3;
const DEFAULT_PROMPT: &str = "Write a Rust function to calculate the factorial of a given number.";
#[derive(Clone, Debug, Copy, PartialEq, Eq, ValueEnum)]
enum Which {
#[value(name = "0.6b")]
W3_0_6b,
#[value(name = "1.7b")]
W3_1_7b,
#[value(name = "4b")]
W3_4b,
#[value(name = "8b")]
W3_8b,
#[value(name = "14b")]
W3_14b,
#[value(name = "32b")]
W3_32b,
}
#[derive(Parser, Debug)]
#[command(author, version, about, long_about = None)]
struct Args {
/// GGUF file to load, typically a .gguf file generated by the quantize command from llama.cpp
#[arg(long)]
model: Option<String>,
/// The initial prompt, use 'interactive' for entering multiple prompts in an interactive way
/// and 'chat' for an interactive model where history of previous prompts and generated tokens
/// is preserved.
#[arg(long)]
prompt: Option<String>,
/// The length of the sample to generate (in tokens).
#[arg(short = 'n', long, default_value_t = 1000)]
sample_len: usize,
/// The tokenizer config in json format.
#[arg(long)]
tokenizer: Option<String>,
/// The temperature used to generate samples, use 0 for greedy sampling.
#[arg(long, default_value_t = 0.8)]
temperature: f64,
/// Nucleus sampling probability cutoff.
#[arg(long)]
top_p: Option<f64>,
/// Only sample among the top K samples.
#[arg(long)]
top_k: Option<usize>,
/// The seed to use when generating random samples.
#[arg(long, default_value_t = 299792458)]
seed: u64,
/// Enable tracing (generates a trace-timestamp.json file).
#[arg(long)]
tracing: bool,
/// Process prompt elements separately.
#[arg(long)]
split_prompt: bool,
/// Run on CPU rather than GPU even if a GPU is available.
#[arg(long)]
cpu: bool,
/// Penalty to be applied for repeating tokens, 1. means no penalty.
#[arg(long, default_value_t = 1.1)]
repeat_penalty: f32,
/// The context size to consider for the repeat penalty.
#[arg(long, default_value_t = 64)]
repeat_last_n: usize,
/// The model size to use.
#[arg(long, default_value = "0.6b")]
which: Which,
}
impl Args {
fn tokenizer(&self) -> anyhow::Result<Tokenizer> {
let tokenizer_path = match &self.tokenizer {
Some(config) => std::path::PathBuf::from(config),
None => {
let api = hf_hub::api::sync::Api::new()?;
let repo = match self.which {
Which::W3_0_6b => "Qwen/Qwen3-0.6B",
Which::W3_1_7b => "Qwen/Qwen3-1.7B",
Which::W3_4b => "Qwen/Qwen3-4B",
Which::W3_8b => "Qwen/Qwen3-8B",
Which::W3_14b => "Qwen/Qwen3-14B",
Which::W3_32b => "Qwen/Qwen3-32B",
};
let api = api.model(repo.to_string());
api.get("tokenizer.json")?
}
};
Tokenizer::from_file(tokenizer_path).map_err(anyhow::Error::msg)
}
fn model(&self) -> anyhow::Result<std::path::PathBuf> {
let model_path = match &self.model {
Some(config) => std::path::PathBuf::from(config),
None => {
let (repo, filename, revision) = match self.which {
Which::W3_0_6b => ("unsloth/Qwen3-0.6B-GGUF", "Qwen3-0.6B-Q4_K_M.gguf", "main"),
Which::W3_1_7b => ("unsloth/Qwen3-1.7B-GGUF", "Qwen3-1.7B-Q4_K_M.gguf", "main"),
Which::W3_4b => ("unsloth/Qwen3-4B-GGUF", "Qwen3-4B-Q4_K_M.gguf", "main"),
Which::W3_8b => ("unsloth/Qwen3-8B-GGUF", "Qwen3-8B-Q4_K_M.gguf", "main"),
Which::W3_14b => ("unsloth/Qwen3-14B-GGUF", "Qwen3-14B-Q4_K_M.gguf", "main"),
Which::W3_32b => ("unsloth/Qwen3-32B-GGUF", "Qwen3-32B-Q4_K_M.gguf", "main"),
};
let api = hf_hub::api::sync::Api::new()?;
api.repo(hf_hub::Repo::with_revision(
repo.to_string(),
hf_hub::RepoType::Model,
revision.to_string(),
))
.get(filename)?
}
};
Ok(model_path)
}
}
fn format_size(size_in_bytes: usize) -> String {
if size_in_bytes < 1_000 {
format!("{}B", size_in_bytes)
} else if size_in_bytes < 1_000_000 {
format!("{:.2}KB", size_in_bytes as f64 / 1e3)
} else if size_in_bytes < 1_000_000_000 {
format!("{:.2}MB", size_in_bytes as f64 / 1e6)
} else {
format!("{:.2}GB", size_in_bytes as f64 / 1e9)
}
}
fn main() -> anyhow::Result<()> {
use tracing_chrome::ChromeLayerBuilder;
use tracing_subscriber::prelude::*;
let args = Args::parse();
let _guard = if args.tracing {
let (chrome_layer, guard) = ChromeLayerBuilder::new().build();
tracing_subscriber::registry().with(chrome_layer).init();
Some(guard)
} else {
None
};
println!(
"avx: {}, neon: {}, simd128: {}, f16c: {}",
candle::utils::with_avx(),
candle::utils::with_neon(),
candle::utils::with_simd128(),
candle::utils::with_f16c()
);
println!(
"temp: {:.2} repeat-penalty: {:.2} repeat-last-n: {}",
args.temperature, args.repeat_penalty, args.repeat_last_n
);
let model_path = args.model()?;
let mut file = std::fs::File::open(&model_path)?;
let start = std::time::Instant::now();
let device = candle_examples::device(args.cpu)?;
let mut model = {
let model = gguf_file::Content::read(&mut file).map_err(|e| e.with_path(model_path))?;
let mut total_size_in_bytes = 0;
for (_, tensor) in model.tensor_infos.iter() {
let elem_count = tensor.shape.elem_count();
total_size_in_bytes +=
elem_count * tensor.ggml_dtype.type_size() / tensor.ggml_dtype.block_size();
}
println!(
"loaded {:?} tensors ({}) in {:.2}s",
model.tensor_infos.len(),
&format_size(total_size_in_bytes),
start.elapsed().as_secs_f32(),
);
Qwen3::from_gguf(model, &mut file, &device)?
};
println!("model built");
let tokenizer = args.tokenizer()?;
let mut tos = TokenOutputStream::new(tokenizer);
let prompt_str = args
.prompt
.clone()
.unwrap_or_else(|| DEFAULT_PROMPT.to_string());
let prompt_str = format!("<|im_start|>user\n{prompt_str}<|im_end|>\n<|im_start|>assistant\n");
print!("formatted prompt: {}", &prompt_str);
let tokens = tos
.tokenizer()
.encode(prompt_str, true)
.map_err(anyhow::Error::msg)?;
let tokens = tokens.get_ids();
let to_sample = args.sample_len.saturating_sub(1);
let mut all_tokens = vec![];
let mut logits_processor = {
let temperature = args.temperature;
let sampling = if temperature <= 0. {
Sampling::ArgMax
} else {
match (args.top_k, args.top_p) {
(None, None) => Sampling::All { temperature },
(Some(k), None) => Sampling::TopK { k, temperature },
(None, Some(p)) => Sampling::TopP { p, temperature },
(Some(k), Some(p)) => Sampling::TopKThenTopP { k, p, temperature },
}
};
LogitsProcessor::from_sampling(args.seed, sampling)
};
let start_prompt_processing = std::time::Instant::now();
let mut next_token = if !args.split_prompt {
let input = Tensor::new(tokens, &device)?.unsqueeze(0)?;
let logits = model.forward(&input, 0)?;
let logits = logits.squeeze(0)?;
logits_processor.sample(&logits)?
} else {
let mut next_token = 0;
for (pos, token) in tokens.iter().enumerate() {
let input = Tensor::new(&[*token], &device)?.unsqueeze(0)?;
let logits = model.forward(&input, pos)?;
let logits = logits.squeeze(0)?;
next_token = logits_processor.sample(&logits)?
}
next_token
};
let prompt_dt = start_prompt_processing.elapsed();
all_tokens.push(next_token);
if let Some(t) = tos.next_token(next_token)? {
print!("{t}");
std::io::stdout().flush()?;
}
let eos_token = *tos.tokenizer().get_vocab(true).get("<|im_end|>").unwrap();
let start_post_prompt = std::time::Instant::now();
let mut sampled = 0;
for index in 0..to_sample {
let input = Tensor::new(&[next_token], &device)?.unsqueeze(0)?;
let logits = model.forward(&input, tokens.len() + index)?;
let logits = logits.squeeze(0)?;
let logits = if args.repeat_penalty == 1. {
logits
} else {
let start_at = all_tokens.len().saturating_sub(args.repeat_last_n);
candle_transformers::utils::apply_repeat_penalty(
&logits,
args.repeat_penalty,
&all_tokens[start_at..],
)?
};
next_token = logits_processor.sample(&logits)?;
all_tokens.push(next_token);
if let Some(t) = tos.next_token(next_token)? {
print!("{t}");
std::io::stdout().flush()?;
}
sampled += 1;
if next_token == eos_token {
break;
};
}
if let Some(rest) = tos.decode_rest().map_err(candle::Error::msg)? {
print!("{rest}");
}
std::io::stdout().flush()?;
let dt = start_post_prompt.elapsed();
println!(
"\n\n{:4} prompt tokens processed: {:.2} token/s",
tokens.len(),
tokens.len() as f64 / prompt_dt.as_secs_f64(),
);
println!(
"{sampled:4} tokens generated: {:.2} token/s",
sampled as f64 / dt.as_secs_f64(),
);
Ok(())
}