Add some Bigcode model (#260)

* Start sketching the bigcode gpt model. * Sketch the bigcode model. * Implement the attention mechanism. * Random reshaping. * Sketch more of the example. * Add some kv cache. * Properly generate the position ids. * Proper attention mask. * Bail on upcasting. * Properly apply the attention mask. * Add the smaller starcoder variants. * Update for the new hub api. * Fix a shape issue. * Fix another shape issue. * Get some logits out. * Adjust the weigth names.
2025-06-17 11:08:52 +00:00 · 2023-07-28 09:57:32 +01:00
parent 4f260ef025
commit 6a54ca115e
2 changed files with 518 additions and 0 deletions
--- a/candle-examples/examples/bigcode/main.rs
+++ b/candle-examples/examples/bigcode/main.rs
@ -0,0 +1,161 @@
 #[cfg(feature = "mkl")]
 extern crate intel_mkl_src;
 use anyhow::{Error as E, Result};
 use clap::Parser;
 mod model;
 use model::{Config, GPTBigCode};
 use candle::{DType, Device, Tensor};
 use candle_nn::VarBuilder;
 use candle_transformers::generation::LogitsProcessor;
 use hf_hub::{api::sync::Api, Repo, RepoType};
 use tokenizers::Tokenizer;
 struct TextGeneration {
    model: GPTBigCode,
    device: Device,
    tokenizer: Tokenizer,
    logits_processor: LogitsProcessor,
 }
 impl TextGeneration {
    fn new(
        model: GPTBigCode,
        tokenizer: Tokenizer,
        seed: u64,
        temp: Option<f64>,
        device: &Device,
    ) -> Self {
        let logits_processor = LogitsProcessor::new(seed, temp);
        Self {
            model,
            tokenizer,
            logits_processor,
            device: device.clone(),
        }
    }
    fn run(&mut self, prompt: &str, sample_len: usize) -> Result<()> {
        println!("starting the inference loop");
        let mut tokens = self
            .tokenizer
            .encode(prompt, true)
            .map_err(E::msg)?
            .get_ids()
            .to_vec();
        let mut new_tokens = vec![];
        let start_gen = std::time::Instant::now();
        for index in 0..sample_len {
            let start_gen = std::time::Instant::now();
            let (context_size, past_len) = if self.model.config().use_cache && index > 0 {
                (1, tokens.len().saturating_sub(1))
            } else {
                (tokens.len(), 0)
            };
            let ctxt = &tokens[tokens.len().saturating_sub(context_size)..];
            let input = Tensor::new(ctxt, &self.device)?.unsqueeze(0)?;
            let logits = self.model.forward(&input, past_len)?;
            let logits = logits.squeeze(0)?.to_dtype(DType::F32)?;
            let next_token = self.logits_processor.sample(&logits)?;
            tokens.push(next_token);
            new_tokens.push(next_token);
            println!("> {:?}", start_gen.elapsed());
            println!(
                "{} token: {} '{}'",
                index + 1,
                next_token,
                self.tokenizer
                    .decode(vec![next_token], true)
                    .map_err(E::msg)?
            );
        }
        let dt = start_gen.elapsed();
        println!(
            "{sample_len} tokens generated ({} token/s)\n----\n{}\n----",
            sample_len as f64 / dt.as_secs_f64(),
            self.tokenizer.decode(new_tokens, true).map_err(E::msg)?
        );
        Ok(())
    }
 }
 #[derive(Parser, Debug)]
 #[command(author, version, about, long_about = None)]
 struct Args {
    /// Run on CPU rather than on GPU.
    #[arg(long)]
    cpu: bool,
    #[arg(long)]
    prompt: String,
    /// The temperature used to generate samples.
    #[arg(long)]
    temperature: Option<f64>,
    /// The seed to use when generating random samples.
    #[arg(long, default_value_t = 299792458)]
    seed: u64,
    /// The length of the sample to generate (in tokens).
    #[arg(long, default_value_t = 100)]
    sample_len: usize,
    #[arg(long, default_value = "bigcode/starcoderbase-1b")]
    model_id: String,
    #[arg(long, default_value = "main")]
    revision: String,
    #[arg(long)]
    weight_file: Option<String>,
 }
 fn main() -> Result<()> {
    let args = Args::parse();
    let start = std::time::Instant::now();
    let api = Api::new()?;
    let repo = api.repo(Repo::with_revision(
        args.model_id,
        RepoType::Model,
        args.revision,
    ));
    let tokenizer_filename = repo.get("tokenizer.json")?;
    let filenames = match args.weight_file {
        Some(weight_file) => vec![std::path::PathBuf::from(weight_file.clone())],
        None => {
            let repo_filenames: Vec<String> = vec![];
            repo_filenames
                .iter()
                .map(|f| repo.get(f))
                .collect::<std::result::Result<Vec<_>, _>>()?
        }
    };
    println!("retrieved the files in {:?}", start.elapsed());
    let tokenizer = Tokenizer::from_file(tokenizer_filename).map_err(E::msg)?;
    let weights = filenames
        .iter()
        .map(|f| Ok(unsafe { candle::safetensors::MmapedFile::new(f)? }))
        .collect::<Result<Vec<_>>>()?;
    let weights = weights
        .iter()
        .map(|f| Ok(f.deserialize()?))
        .collect::<Result<Vec<_>>>()?;
    let start = std::time::Instant::now();
    let device = candle_examples::device(args.cpu)?;
    let vb = VarBuilder::from_safetensors(weights, DType::F32, &device);
    let config = Config::starcoder_1b();
    let model = GPTBigCode::load(vb, config)?;
    println!("loaded the model in {:?}", start.elapsed());
    let mut pipeline = TextGeneration::new(model, tokenizer, args.seed, args.temperature, &device);
    pipeline.run(&args.prompt, args.sample_len)?;
    Ok(())
 }
--- a/candle-examples/examples/bigcode/model.rs
+++ b/candle-examples/examples/bigcode/model.rs
@ -0,0 +1,357 @@
 use candle::{DType, Device, IndexOp, Result, Tensor, D};
 use candle_nn::{Embedding, LayerNorm, Linear, VarBuilder};
 fn linear(size1: usize, size2: usize, bias: bool, vb: VarBuilder) -> Result<Linear> {
    let weight = vb.get((size2, size1), "weight")?;
    let bias = if bias {
        Some(vb.get(size2, "bias")?)
    } else {
        None
    };
    Ok(Linear::new(weight, bias))
 }
 fn embedding(vocab_size: usize, hidden_size: usize, vb: VarBuilder) -> Result<Embedding> {
    let embeddings = vb.get((vocab_size, hidden_size), "weight")?;
    Ok(Embedding::new(embeddings, hidden_size))
 }
 fn layer_norm(size: usize, eps: f64, vb: VarBuilder) -> Result<LayerNorm> {
    let weight = vb.get(size, "weight")?;
    let bias = vb.get(size, "bias")?;
    Ok(LayerNorm::new(weight, bias, eps))
 }
 fn make_causal_mask(t: usize) -> Result<Tensor> {
    let mask: Vec<_> = (0..t)
        .flat_map(|i| (0..t).map(move |j| u32::from(j > i)))
        .collect();
    let mask = Tensor::from_slice(&mask, (t, t), &Device::Cpu)?;
    Ok(mask)
 }
 #[derive(Debug)]
 pub struct Config {
    pub vocab_size: usize,
    // max_position_embeddings aka n_positions
    pub max_position_embeddings: usize,
    // num_hidden_layers aka n_layer
    pub num_hidden_layers: usize,
    // hidden_size aka n_embd
    pub hidden_size: usize,
    pub layer_norm_epsilon: f64,
    pub n_inner: Option<usize>,
    // num_attention_heads aka n_head
    pub num_attention_heads: usize,
    pub multi_query: bool,
    pub use_cache: bool,
 }
 impl Config {
    #[allow(dead_code)]
    pub fn starcoder_1b() -> Self {
        Self {
            vocab_size: 49152,
            max_position_embeddings: 8192,
            num_hidden_layers: 24,
            hidden_size: 2048,
            layer_norm_epsilon: 1e-5,
            n_inner: Some(8192),
            num_attention_heads: 16,
            multi_query: true,
            use_cache: true,
        }
    }
    #[allow(dead_code)]
    pub fn starcoder_3b() -> Self {
        Self {
            vocab_size: 49152,
            max_position_embeddings: 8192,
            num_hidden_layers: 36,
            hidden_size: 2816,
            layer_norm_epsilon: 1e-5,
            n_inner: Some(11264),
            num_attention_heads: 22,
            multi_query: true,
            use_cache: true,
        }
    }
    #[allow(dead_code)]
    pub fn starcoder_7b() -> Self {
        Self {
            vocab_size: 49152,
            max_position_embeddings: 8192,
            num_hidden_layers: 42,
            hidden_size: 4096,
            layer_norm_epsilon: 1e-5,
            n_inner: Some(16384),
            num_attention_heads: 32,
            multi_query: true,
            use_cache: true,
        }
    }
    #[allow(dead_code)]
    pub fn starcoder() -> Self {
        Self {
            vocab_size: 49152,
            max_position_embeddings: 8192,
            num_hidden_layers: 40,
            hidden_size: 6144,
            layer_norm_epsilon: 1e-5,
            n_inner: Some(24576),
            num_attention_heads: 48,
            multi_query: true,
            use_cache: true,
        }
    }
 }
 struct Attention {
    c_attn: Linear,
    c_proj: Linear,
    kv_cache: Option<Tensor>,
    use_cache: bool,
    embed_dim: usize,
    kv_dim: usize,
    num_heads: usize,
    head_dim: usize,
    multi_query: bool,
 }
 impl Attention {
    pub fn load(vb: VarBuilder, cfg: &Config) -> Result<Self> {
        let hidden_size = cfg.hidden_size;
        let head_dim = hidden_size / cfg.num_attention_heads;
        let kv_heads = if cfg.multi_query {
            1
        } else {
            cfg.num_attention_heads
        };
        let kv_dim = kv_heads * head_dim;
        let c_attn = linear(hidden_size, hidden_size + 2 * kv_dim, true, vb.pp("c_attn"))?;
        let c_proj = linear(hidden_size, hidden_size, true, vb.pp("c_proj"))?;
        Ok(Self {
            c_proj,
            c_attn,
            embed_dim: hidden_size,
            kv_cache: None,
            use_cache: cfg.use_cache,
            kv_dim,
            head_dim,
            num_heads: cfg.num_attention_heads,
            multi_query: cfg.multi_query,
        })
    }
    fn attn(
        &self,
        query: &Tensor,
        key: &Tensor,
        value: &Tensor,
        attention_mask: &Tensor,
    ) -> Result<Tensor> {
        if query.dtype() != DType::F32 {
            // If we start supporting f16 models, we may need the upcasting scaling bits.
            // https://github.com/huggingface/transformers/blob/a0042379269bea9182c1f87e6b2eee4ba4c8cce8/src/transformers/models/gpt_bigcode/modeling_gpt_bigcode.py#L133
            candle::bail!("upcasting is not supported {:?}", query.dtype())
        }
        let scale_factor = 1f64 / (self.head_dim as f64).sqrt();
        let initial_query_shape = query.shape();
        let key_len = key.dim(D::Minus1)?;
        let (query, key, attn_shape, attn_view) = if self.multi_query {
            let (b_sz, query_len, _) = query.dims3()?;
            let query = query.reshape((b_sz, query_len * self.num_heads, self.head_dim))?;
            let attn_shape = (b_sz, query_len, self.num_heads, key_len);
            let attn_view = (b_sz, query_len * self.num_heads, key_len);
            (query, key.clone(), attn_shape, attn_view)
        } else {
            let (b_sz, _num_heads, query_len, _head_dim) = query.dims4()?;
            let query = query.reshape((b_sz, query_len * self.num_heads, self.head_dim))?;
            let key = key.reshape((b_sz * self.num_heads, self.head_dim, key_len))?;
            let attn_shape = (b_sz, self.num_heads, query_len, key_len);
            let attn_view = (b_sz * self.num_heads, query_len, key_len);
            (query, key, attn_shape, attn_view)
        };
        let attn_weights = (query.matmul(&key)? * scale_factor)?.reshape(attn_shape)?;
        let attention_mask = attention_mask.broadcast_as(attn_shape)?;
        let mask_value =
            Tensor::new(f32::NEG_INFINITY, query.device())?.broadcast_as(attn_shape)?;
        let attn_weights = attention_mask.where_cond(&attn_weights, &mask_value)?;
        let attn_weights = attn_weights.softmax(D::Minus1)?;
        let attn_output = if self.multi_query {
            attn_weights
                .reshape(attn_view)?
                .matmul(value)?
                .reshape(initial_query_shape)?
        } else {
            attn_weights.matmul(value)?
        };
        Ok(attn_output)
    }
    fn forward(&mut self, hidden_states: &Tensor, attention_mask: &Tensor) -> Result<Tensor> {
        let qkv = self.c_attn.forward(hidden_states)?;
        let (query, key_value) = if self.multi_query {
            let query = qkv.i((.., .., ..self.embed_dim))?;
            let key_value = qkv.i((.., .., self.embed_dim..self.embed_dim + 2 * self.kv_dim))?;
            (query, key_value)
        } else {
            let mut dims = qkv.dims().to_vec();
            dims.pop();
            dims.push(self.embed_dim);
            dims.push(self.head_dim * 3);
            let qkv = qkv.reshape(dims)?.transpose(1, 2)?;
            let query = qkv.i((.., .., .., ..self.head_dim))?;
            let key_value = qkv.i((.., .., .., self.head_dim..3 * self.head_dim))?;
            (query, key_value)
        };
        let mut key_value = key_value;
        if self.use_cache {
            if let Some(kv_cache) = &self.kv_cache {
                // TODO: we could trim the tensors to MAX_SEQ_LEN so that this would work for
                // arbitrarily large sizes.
                key_value = Tensor::cat(&[kv_cache, &key_value], D::Minus2)?.contiguous()?;
            }
            self.kv_cache = Some(key_value.clone())
        }
        let key = key_value.narrow(D::Minus1, 0, self.head_dim)?;
        let value = key_value.narrow(D::Minus1, self.head_dim, self.head_dim)?;
        let attn_output = self.attn(&query, &key.t()?, &value, attention_mask)?;
        let attn_output = if self.multi_query {
            attn_output
        } else {
            attn_output
                .transpose(1, 2)?
                .reshape(hidden_states.shape())?
        };
        let attn_output = self.c_proj.forward(&attn_output)?;
        Ok(attn_output)
    }
 }
 struct Mlp {
    c_fc: Linear,
    c_proj: Linear,
 }
 impl Mlp {
    fn load(inner_dim: usize, vb: VarBuilder, cfg: &Config) -> Result<Self> {
        let c_fc = linear(cfg.hidden_size, inner_dim, true, vb.pp("c_fc"))?;
        let c_proj = linear(inner_dim, cfg.hidden_size, true, vb.pp("c_proj"))?;
        Ok(Self { c_fc, c_proj })
    }
    fn forward(&mut self, hidden_states: &Tensor) -> Result<Tensor> {
        let hidden_states = self.c_fc.forward(hidden_states)?.gelu()?;
        let hidden_states = self.c_proj.forward(&hidden_states)?;
        Ok(hidden_states)
    }
 }
 // TODO: Add cross-attention?
 struct Block {
    ln_1: LayerNorm,
    attn: Attention,
    ln_2: LayerNorm,
    mlp: Mlp,
 }
 impl Block {
    fn load(vb: VarBuilder, cfg: &Config) -> Result<Self> {
        let hidden_size = cfg.hidden_size;
        let inner_dim = cfg.n_inner.unwrap_or(4 * hidden_size);
        let ln_1 = layer_norm(hidden_size, cfg.layer_norm_epsilon, vb.pp("ln_1"))?;
        let attn = Attention::load(vb.pp("attn"), cfg)?;
        let ln_2 = layer_norm(hidden_size, cfg.layer_norm_epsilon, vb.pp("ln_2"))?;
        let mlp = Mlp::load(inner_dim, vb.pp("mlp"), cfg)?;
        Ok(Self {
            ln_1,
            attn,
            ln_2,
            mlp,
        })
    }
    fn forward(&mut self, hidden_states: &Tensor, attention_mask: &Tensor) -> Result<Tensor> {
        let residual = hidden_states;
        let hidden_states = self.ln_1.forward(hidden_states)?;
        let attn_outputs = self.attn.forward(&hidden_states, attention_mask)?;
        let hidden_states = (&attn_outputs + residual)?;
        let residual = &hidden_states;
        let hidden_states = self.ln_2.forward(&hidden_states)?;
        let hidden_states = self.mlp.forward(&hidden_states)?;
        let hidden_states = (&hidden_states + residual)?;
        Ok(hidden_states)
    }
 }
 pub struct GPTBigCode {
    wte: Embedding,
    wpe: Embedding,
    blocks: Vec<Block>,
    ln_f: LayerNorm,
    lm_head: Linear,
    bias: Tensor,
    config: Config,
 }
 impl GPTBigCode {
    pub fn config(&self) -> &Config {
        &self.config
    }
    pub fn load(vb: VarBuilder, cfg: Config) -> Result<Self> {
        let hidden_size = cfg.hidden_size;
        let vb_t = vb.pp("transformer");
        let wte = embedding(cfg.vocab_size, hidden_size, vb_t.pp("wte"))?;
        let wpe = embedding(cfg.max_position_embeddings, hidden_size, vb_t.pp("wpe"))?;
        let blocks = (0..cfg.num_hidden_layers)
            .map(|i| Block::load(vb_t.pp(&format!("h.{i}")), &cfg))
            .collect::<Result<Vec<_>>>()?;
        let ln_f = layer_norm(hidden_size, cfg.layer_norm_epsilon, vb_t.pp("ln_f"))?;
        let lm_head = linear(hidden_size, cfg.vocab_size, false, vb.pp("lm_head"))?;
        let bias = make_causal_mask(cfg.max_position_embeddings)?;
        Ok(Self {
            wte,
            wpe,
            blocks,
            lm_head,
            ln_f,
            bias,
            config: cfg,
        })
    }
    pub fn forward(&mut self, input_ids: &Tensor, past_len: usize) -> Result<Tensor> {
        let dev = input_ids.device();
        let (b_sz, seq_len) = input_ids.dims2()?;
        let key_len = past_len + seq_len;
        let attention_mask = self.bias.i((past_len..key_len, ..key_len))?.unsqueeze(0)?;
        // MQA models: (batch_size, query_length, n_heads, key_length)
        // MHA models: (batch_size, n_heads, query_length, key_length)
        let seq_len_dim = if self.config.multi_query { 2 } else { 1 };
        let attention_mask = attention_mask.unsqueeze(seq_len_dim)?;
        let position_ids = Tensor::arange(past_len as u32, (past_len + seq_len) as u32, dev)?;
        let position_ids = position_ids.unsqueeze(0)?.broadcast_as((b_sz, seq_len))?;
        let input_embeds = self.wte.forward(input_ids)?;
        let position_embeds = self.wpe.forward(&position_ids)?;
        let mut hidden_states = (&input_embeds + &position_embeds)?;
        for block in self.blocks.iter_mut() {
            hidden_states = block.forward(&hidden_states, &attention_mask)?;
        }
        let hidden_states = self.ln_f.forward(&hidden_states)?;
        let hidden_states = hidden_states
            .reshape((b_sz, seq_len, self.config.hidden_size))?
            .narrow(1, seq_len - 1, 1)?;
        let logits = self.lm_head.forward(&hidden_states)?.squeeze(1)?;
        Ok(logits)
    }
 }