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Add the Mixtral model. (#1437)

Browse Source 
* Add the Mixtral model.

* Add more of the mixtral layers.

* Add the final layers for mixtral.

* Sketch the expert selection.

* Add some expert routing logic.

* Hopefully finish the routing logic for mixtral.

* Add the mixtral example.

* Fix the weight filenames.

* Bugfix.

* Another fix.

* Yet another fix + remove the unused pragma.

* Shape fix.

* Add a readme.
This commit is contained in:
Laurent Mazare
2023-12-15 14:19:56 -06:00
committed by GitHub
parent 79eab519fd
commit 614842b311
4 changed files with 788 additions and 0 deletions
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25
candle-examples/examples/mixtral/README.md Normal file
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# candle-mixtral: 8x7b LLM using a sparse mixture of experts.
Mixtral-8x7B-v0.1 is a pretrained generative LLM with 56 billion parameters.
- [Blog post](https://mistral.ai/news/mixtral-of-experts/) from Mistral announcing the model release.
- [Model card](https://huggingface.co/mistralai/Mixtral-8x7B-v0.1) on the HuggingFace Hub.
## Running the example
```bash
$ cargo run --example mixtral --release -- --prompt "def print_prime(n): "
def print_prime(n): # n is the number of prime numbers to be printed
i = 2
count = 0
while (count < n):
if (isPrime(i)):
print(i)
count += 1
i += 1
def isPrime(n):
for x in range(2, int(n**0.5)+1):
if (n % x == 0):
...
```

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candle-examples/examples/mixtral/main.rs Normal file
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#[cfg(feature = "mkl")]
extern crate intel_mkl_src;
#[cfg(feature = "accelerate")]
extern crate accelerate_src;
use anyhow::{Error as E, Result};
use clap::Parser;
use candle_transformers::models::mixtral::{Config, Model};
use candle::{DType, Device, Tensor};
use candle_examples::token_output_stream::TokenOutputStream;
use candle_nn::VarBuilder;
use candle_transformers::generation::LogitsProcessor;
use hf_hub::{api::sync::Api, Repo, RepoType};
use tokenizers::Tokenizer;
struct TextGeneration {
model: Model,
device: Device,
tokenizer: TokenOutputStream,
logits_processor: LogitsProcessor,
repeat_penalty: f32,
repeat_last_n: usize,
}
impl TextGeneration {
#[allow(clippy::too_many_arguments)]
fn new(
model: Model,
tokenizer: Tokenizer,
seed: u64,
temp: Option<f64>,
top_p: Option<f64>,
repeat_penalty: f32,
repeat_last_n: usize,
device: &Device,
) -> Self {
let logits_processor = LogitsProcessor::new(seed, temp, top_p);
Self {
model,
tokenizer: TokenOutputStream::new(tokenizer),
logits_processor,
repeat_penalty,
repeat_last_n,
device: device.clone(),
}
}
fn run(&mut self, prompt: &str, sample_len: usize) -> Result<()> {
use std::io::Write;
self.tokenizer.clear();
let mut tokens = self
.tokenizer
.tokenizer()
.encode(prompt, true)
.map_err(E::msg)?
.get_ids()
.to_vec();
for &t in tokens.iter() {
if let Some(t) = self.tokenizer.next_token(t)? {
print!("{t}")
}
}
std::io::stdout().flush()?;
let mut generated_tokens = 0usize;
let eos_token = match self.tokenizer.get_token("</s>") {
Some(token) => token,
None => anyhow::bail!("cannot find the </s> token"),
};
let start_gen = std::time::Instant::now();
for index in 0..sample_len {
let context_size = if index > 0 { 1 } else { tokens.len() };
let start_pos = tokens.len().saturating_sub(context_size);
let ctxt = &tokens[start_pos..];
let input = Tensor::new(ctxt, &self.device)?.unsqueeze(0)?;
let logits = self.model.forward(&input, start_pos)?;
let logits = logits.squeeze(0)?.squeeze(0)?.to_dtype(DType::F32)?;
let logits = if self.repeat_penalty == 1. {
logits
} else {
let start_at = tokens.len().saturating_sub(self.repeat_last_n);
candle_transformers::utils::apply_repeat_penalty(
&logits,
self.repeat_penalty,
&tokens[start_at..],
)?
};
let next_token = self.logits_processor.sample(&logits)?;
tokens.push(next_token);
generated_tokens += 1;
if next_token == eos_token {
break;
}
if let Some(t) = self.tokenizer.next_token(next_token)? {
print!("{t}");
std::io::stdout().flush()?;
}
}
let dt = start_gen.elapsed();
if let Some(rest) = self.tokenizer.decode_rest().map_err(E::msg)? {
print!("{rest}");
}
std::io::stdout().flush()?;
println!(
"\n{generated_tokens} tokens generated ({:.2} token/s)",
generated_tokens as f64 / dt.as_secs_f64(),
);
Ok(())
}
}
#[derive(Parser, Debug)]
#[command(author, version, about, long_about = None)]
struct Args {
/// Run on CPU rather than on GPU.
#[arg(long)]
cpu: bool,
/// Enable tracing (generates a trace-timestamp.json file).
#[arg(long)]
tracing: bool,
#[arg(long)]
use_flash_attn: bool,
#[arg(long)]
prompt: String,
/// The temperature used to generate samples.
#[arg(long)]
temperature: Option<f64>,
/// Nucleus sampling probability cutoff.
#[arg(long)]
top_p: 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, short = 'n', default_value_t = 100)]
sample_len: usize,
#[arg(long, default_value = "mistralai/Mixtral-8x7B-v0.1")]
model_id: String,
#[arg(long, default_value = "main")]
revision: String,
#[arg(long)]
tokenizer_file: Option<String>,
#[arg(long)]
weight_files: Option<String>,
/// 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,
}
fn main() -> 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.unwrap_or(0.),
args.repeat_penalty,
args.repeat_last_n
);
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 = match args.tokenizer_file {
Some(file) => std::path::PathBuf::from(file),
None => repo.get("tokenizer.json")?,
};
let filenames = match args.weight_files {
Some(files) => files
.split(',')
.map(std::path::PathBuf::from)
.collect::<Vec<_>>(),
None => {
vec![
repo.get("model-00001-of-00019.safetensors")?,
repo.get("model-00002-of-00019.safetensors")?,
repo.get("model-00003-of-00019.safetensors")?,
repo.get("model-00004-of-00019.safetensors")?,
repo.get("model-00005-of-00019.safetensors")?,
repo.get("model-00006-of-00019.safetensors")?,
repo.get("model-00007-of-00019.safetensors")?,
repo.get("model-00008-of-00019.safetensors")?,
repo.get("model-00009-of-00019.safetensors")?,
repo.get("model-00010-of-00019.safetensors")?,
repo.get("model-00011-of-00019.safetensors")?,
repo.get("model-00012-of-00019.safetensors")?,
repo.get("model-00013-of-00019.safetensors")?,
repo.get("model-00014-of-00019.safetensors")?,
repo.get("model-00015-of-00019.safetensors")?,
repo.get("model-00016-of-00019.safetensors")?,
repo.get("model-00017-of-00019.safetensors")?,
repo.get("model-00018-of-00019.safetensors")?,
repo.get("model-00019-of-00019.safetensors")?,
]
}
};
println!("retrieved the files in {:?}", start.elapsed());
let tokenizer = Tokenizer::from_file(tokenizer_filename).map_err(E::msg)?;
let start = std::time::Instant::now();
let config = Config::v0_1_8x7b(args.use_flash_attn);
let device = candle_examples::device(args.cpu)?;
let dtype = if device.is_cuda() {
DType::BF16
} else {
DType::F32
};
let vb = unsafe { VarBuilder::from_mmaped_safetensors(&filenames, dtype, &device)? };
let model = Model::new(&config, vb)?;
println!("loaded the model in {:?}", start.elapsed());
let mut pipeline = TextGeneration::new(
model,
tokenizer,
args.seed,
args.temperature,
args.top_p,
args.repeat_penalty,
args.repeat_last_n,
&device,
);
pipeline.run(&args.prompt, args.sample_len)?;
Ok(())
}

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candle-transformers/src/models/mixtral.rs Normal file
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use crate::models::with_tracing::{linear_no_bias, Linear};
/// Mixtral Model
/// https://github.com/huggingface/transformers/blob/main/src/transformers/models/mixtral/modeling_mixtral.py
/// https://mistral.ai/news/mixtral-of-experts/
use candle::{DType, Device, Module, Result, Tensor, D};
use candle_nn::{Activation, VarBuilder};
use serde::Deserialize;
use std::sync::Arc;
/// https://github.com/huggingface/transformers/blob/1a585c1222a56bcaecc070966d558d4a9d862e83/src/transformers/models/mixtral/configuration_mixtral.py#L113
#[derive(Debug, Clone, PartialEq, Deserialize)]
pub struct Config {
pub(crate) vocab_size: usize,
pub(crate) hidden_size: usize,
pub(crate) intermediate_size: usize,
pub(crate) num_hidden_layers: usize,
pub(crate) num_attention_heads: usize,
pub(crate) num_key_value_heads: usize,
pub(crate) hidden_act: Activation,
pub(crate) max_position_embeddings: usize,
pub(crate) rms_norm_eps: f64,
pub(crate) rope_theta: f64,
pub(crate) sliding_window: usize,
pub(crate) num_experts_per_tok: usize,
pub(crate) num_local_experts: usize,
pub(crate) use_flash_attn: bool,
}
impl Config {
/// https://huggingface.co/mistralai/Mixtral-8x7B-v0.1/blob/main/config.json
pub fn v0_1_8x7b(use_flash_attn: bool) -> Self {
Self {
vocab_size: 32000,
hidden_size: 4096,
intermediate_size: 14336,
num_hidden_layers: 32,
num_attention_heads: 32,
num_key_value_heads: 8,
hidden_act: Activation::Silu,
max_position_embeddings: 32768,
rms_norm_eps: 1e-5,
rope_theta: 1e6,
sliding_window: 4096,
num_experts_per_tok: 2,
num_local_experts: 8,
use_flash_attn,
}
}
}
#[derive(Debug, Clone)]
struct RmsNorm {
inner: candle_nn::RmsNorm,
span: tracing::Span,
}
impl RmsNorm {
fn new(size: usize, eps: f64, vb: VarBuilder) -> Result<Self> {
let span = tracing::span!(tracing::Level::TRACE, "rms-norm");
let inner = candle_nn::rms_norm(size, eps, vb)?;
Ok(Self { inner, span })
}
}
impl Module for RmsNorm {
fn forward(&self, x: &Tensor) -> Result<Tensor> {
let _enter = self.span.enter();
self.inner.forward(x)
}
}
#[derive(Debug, Clone)]
struct RotaryEmbedding {
sin: Tensor,
cos: Tensor,
}
fn rotate_half(xs: &Tensor) -> Result<Tensor> {
let last_dim = xs.dim(D::Minus1)?;
let xs1 = xs.narrow(D::Minus1, 0, last_dim / 2)?;
let xs2 = xs.narrow(D::Minus1, last_dim / 2, last_dim - last_dim / 2)?;
Tensor::cat(&[&xs2.neg()?, &xs1], D::Minus1)
}
impl RotaryEmbedding {
fn new(dtype: DType, cfg: &Config, dev: &Device) -> Result<Self> {
let dim = cfg.hidden_size / cfg.num_attention_heads;
let max_seq_len = cfg.max_position_embeddings;
let inv_freq: Vec<_> = (0..dim)
.step_by(2)
.map(|i| 1f32 / (cfg.rope_theta as f32).powf(i as f32 / dim as f32))
.collect();
let inv_freq_len = inv_freq.len();
let inv_freq = Tensor::from_vec(inv_freq, (1, inv_freq_len), dev)?.to_dtype(dtype)?;
let t = Tensor::arange(0u32, max_seq_len as u32, dev)?
.to_dtype(dtype)?
.reshape((max_seq_len, 1))?;
let freqs = t.matmul(&inv_freq)?;
let freqs = Tensor::cat(&[&freqs, &freqs], D::Minus1)?;
Ok(Self {
sin: freqs.sin()?,
cos: freqs.cos()?,
})
}
fn apply_rotary_emb_qkv(
&self,
q: &Tensor,
k: &Tensor,
seqlen_offset: usize,
) -> Result<(Tensor, Tensor)> {
let (_b_sz, _h, seq_len, _n_embd) = q.dims4()?;
let cos = self.cos.narrow(0, seqlen_offset, seq_len)?;
let sin = self.sin.narrow(0, seqlen_offset, seq_len)?;
let cos = cos.unsqueeze(0)?.unsqueeze(0)?; // (1, 1, seq_len, dim)
let sin = sin.unsqueeze(0)?.unsqueeze(0)?; // (1, 1, seq_len, dim)
let q_embed = (q.broadcast_mul(&cos)? + rotate_half(q)?.broadcast_mul(&sin))?;
let k_embed = (k.broadcast_mul(&cos)? + rotate_half(k)?.broadcast_mul(&sin))?;
Ok((q_embed, k_embed))
}
}
#[cfg(feature = "flash-attn")]
fn flash_attn(
q: &Tensor,
k: &Tensor,
v: &Tensor,
softmax_scale: f32,
causal: bool,
) -> Result<Tensor> {
candle_flash_attn::flash_attn(q, k, v, softmax_scale, causal)
}
#[cfg(not(feature = "flash-attn"))]
fn flash_attn(_: &Tensor, _: &Tensor, _: &Tensor, _: f32, _: bool) -> Result<Tensor> {
unimplemented!("compile with '--features flash-attn'")
}
#[derive(Debug, Clone)]
struct Attention {
q_proj: Linear,
k_proj: Linear,
v_proj: Linear,
o_proj: Linear,
num_heads: usize,
num_kv_heads: usize,
num_kv_groups: usize,
head_dim: usize,
hidden_size: usize,
rotary_emb: Arc<RotaryEmbedding>,
kv_cache: Option<(Tensor, Tensor)>,
use_flash_attn: bool,
}
impl Attention {
fn new(rotary_emb: Arc<RotaryEmbedding>, cfg: &Config, vb: VarBuilder) -> Result<Self> {
let hidden_sz = cfg.hidden_size;
let num_heads = cfg.num_attention_heads;
let num_kv_heads = cfg.num_key_value_heads;
let num_kv_groups = num_heads / num_kv_heads;
let head_dim = hidden_sz / num_heads;
let q_proj = linear_no_bias(hidden_sz, num_heads * head_dim, vb.pp("q_proj"))?;
let k_proj = linear_no_bias(hidden_sz, num_kv_heads * head_dim, vb.pp("k_proj"))?;
let v_proj = linear_no_bias(hidden_sz, num_kv_heads * head_dim, vb.pp("v_proj"))?;
let o_proj = linear_no_bias(num_heads * head_dim, hidden_sz, vb.pp("o_proj"))?;
Ok(Self {
q_proj,
k_proj,
v_proj,
o_proj,
num_heads,
num_kv_heads,
num_kv_groups,
head_dim,
hidden_size: hidden_sz,
rotary_emb,
kv_cache: None,
use_flash_attn: cfg.use_flash_attn,
})
}
fn repeat_kv(&self, xs: Tensor) -> Result<Tensor> {
let n_rep = self.num_kv_groups;
if n_rep == 1 {
Ok(xs)
} else {
let (b_sz, num_kv_heads, seq_len, head_dim) = xs.dims4()?;
xs.unsqueeze(2)?
.expand((b_sz, num_kv_heads, n_rep, seq_len, head_dim))?
.reshape((b_sz, num_kv_heads * n_rep, seq_len, head_dim))
}
}
fn forward(
&mut self,
xs: &Tensor,
attention_mask: Option<&Tensor>,
seqlen_offset: usize,
) -> Result<Tensor> {
let (b_sz, q_len, _) = xs.dims3()?;
let query_states = self.q_proj.forward(xs)?;
let key_states = self.k_proj.forward(xs)?;
let value_states = self.v_proj.forward(xs)?;
let query_states = query_states
.reshape((b_sz, q_len, self.num_heads, self.head_dim))?
.transpose(1, 2)?;
let key_states = key_states
.reshape((b_sz, q_len, self.num_kv_heads, self.head_dim))?
.transpose(1, 2)?;
let value_states = value_states
.reshape((b_sz, q_len, self.num_kv_heads, self.head_dim))?
.transpose(1, 2)?;
let (query_states, key_states) =
self.rotary_emb
.apply_rotary_emb_qkv(&query_states, &key_states, seqlen_offset)?;
let (key_states, value_states) = match &self.kv_cache {
None => (key_states, value_states),
Some((prev_k, prev_v)) => {
let key_states = Tensor::cat(&[prev_k, &key_states], 2)?;
let value_states = Tensor::cat(&[prev_v, &value_states], 2)?;
(key_states, value_states)
}
};
self.kv_cache = Some((key_states.clone(), value_states.clone()));
let key_states = self.repeat_kv(key_states)?;
let value_states = self.repeat_kv(value_states)?;
let attn_output = if self.use_flash_attn {
// flash-attn expects (b_sz, seq_len, nheads, head_dim)
let q = query_states.transpose(1, 2)?;
let k = key_states.transpose(1, 2)?;
let v = value_states.transpose(1, 2)?;
let softmax_scale = 1f32 / (self.head_dim as f32).sqrt();
flash_attn(&q, &k, &v, softmax_scale, q_len > 1)?.transpose(1, 2)?
} else {
let scale = 1f64 / f64::sqrt(self.head_dim as f64);
let attn_weights = (query_states.matmul(&key_states.transpose(2, 3)?)? * scale)?;
let attn_weights = match attention_mask {
None => attn_weights,
Some(mask) => attn_weights.broadcast_add(mask)?,
};
let attn_weights = candle_nn::ops::softmax_last_dim(&attn_weights)?;
attn_weights.matmul(&value_states)?
};
attn_output
.transpose(1, 2)?
.reshape((b_sz, q_len, self.hidden_size))?
.apply(&self.o_proj)
}
}
#[derive(Debug, Clone)]
struct BlockSparseTop2MLP {
w1: Linear,
w2: Linear,
w3: Linear,
act_fn: Activation,
}
impl BlockSparseTop2MLP {
fn new(cfg: &Config, vb: VarBuilder) -> Result<Self> {
let hidden_sz = cfg.hidden_size;
let intermediate_sz = cfg.intermediate_size;
let w1 = linear_no_bias(hidden_sz, intermediate_sz, vb.pp("w1"))?;
let w2 = linear_no_bias(intermediate_sz, hidden_sz, vb.pp("w2"))?;
let w3 = linear_no_bias(hidden_sz, intermediate_sz, vb.pp("w3"))?;
Ok(Self {
w1,
w2,
w3,
act_fn: cfg.hidden_act,
})
}
}
impl Module for BlockSparseTop2MLP {
fn forward(&self, xs: &Tensor) -> Result<Tensor> {
let lhs = xs.apply(&self.w1)?.apply(&self.act_fn)?;
let rhs = xs.apply(&self.w3)?;
(lhs * rhs)?.apply(&self.w2)
}
}
#[derive(Debug, Clone)]
struct SparseMoeBlock {
gate: Linear,
experts: Vec<BlockSparseTop2MLP>,
num_experts_per_tok: usize,
}
impl SparseMoeBlock {
fn new(cfg: &Config, vb: VarBuilder) -> Result<Self> {
let gate = linear_no_bias(cfg.hidden_size, cfg.num_local_experts, vb.pp("gate"))?;
let mut experts = Vec::with_capacity(cfg.num_local_experts);
let vb = vb.pp("experts");
for idx in 0..cfg.num_local_experts {
let expert = BlockSparseTop2MLP::new(cfg, vb.pp(idx))?;
experts.push(expert)
}
Ok(SparseMoeBlock {
gate,
experts,
num_experts_per_tok: cfg.num_experts_per_tok,
})
}
}
impl Module for SparseMoeBlock {
fn forward(&self, xs: &Tensor) -> Result<Tensor> {
let (b_size, seq_len, hidden_dim) = xs.dims3()?;
let xs = xs.reshape(((), hidden_dim))?;
let router_logits = xs.apply(&self.gate)?;
let routing_weights = candle_nn::ops::softmax_last_dim(&router_logits)?;
// In order to extract topk, we extract the data from the tensor and manipulate it
// directly. Maybe we will want to use some custom ops instead at some point.
let routing_weights = routing_weights.to_dtype(DType::F32)?.to_vec2::<f32>()?;
// routing_weights, selected_experts = torch.topk(routing_weights, self.top_k, dim=-1)
// top_x contains the row indexes to evaluate for each expert.
let mut top_x = vec![vec![]; self.experts.len()];
let mut selected_rws = vec![vec![]; self.experts.len()];
for (row_idx, rw) in routing_weights.iter().enumerate() {
let mut dst = (0..rw.len() as u32).collect::<Vec<u32>>();
dst.sort_by(|&i, &j| rw[j as usize].total_cmp(&rw[i as usize]));
let mut sum_routing_weights = 0f32;
for &expert_idx in dst.iter().take(self.num_experts_per_tok) {
let expert_idx = expert_idx as usize;
let routing_weight = rw[expert_idx];
sum_routing_weights += routing_weight;
top_x[expert_idx].push(row_idx as u32);
}
for &expert_idx in dst.iter().take(self.num_experts_per_tok) {
let expert_idx = expert_idx as usize;
let routing_weight = rw[expert_idx];
selected_rws[expert_idx].push(routing_weight / sum_routing_weights)
}
}
// routing_weights /= routing_weights.sum(dim=-1, keepdim=True)
// expert_mask = torch.nn.functional.one_hot(selected_experts, num_classes=self.num_experts).permute(2, 1, 0)
let mut ys = xs.zeros_like()?;
for (expert_idx, expert_layer) in self.experts.iter().enumerate() {
let top_x = &top_x[expert_idx];
if top_x.is_empty() {
continue;
}
let top_x = Tensor::new(top_x.as_slice(), xs.device())?;
let selected_rws =
Tensor::new(selected_rws[expert_idx].as_slice(), xs.device())?.reshape(((), 1))?;
// Index the correct hidden states and compute the expert hidden state for
// the current expert. We need to make sure to multiply the output hidden
// states by `routing_weights` on the corresponding tokens (top-1 and top-2)
let current_state = xs.index_select(&top_x, 0)?.reshape(((), hidden_dim))?;
// current_hidden_states = expert_layer(current_state, routing_weights[top_x_list, idx_list, None])
let current_hidden_states = expert_layer.forward(&current_state)?;
let current_hidden_states = current_hidden_states.broadcast_mul(&selected_rws)?;
ys = ys.index_add(&top_x, &current_hidden_states, 0)?;
}
let ys = ys.reshape((b_size, seq_len, hidden_dim))?;
Ok(ys)
}
}
#[derive(Debug, Clone)]
struct DecoderLayer {
self_attn: Attention,
block_sparse_moe: SparseMoeBlock,
input_layernorm: RmsNorm,
post_attention_layernorm: RmsNorm,
}
impl DecoderLayer {
fn new(rotary_emb: Arc<RotaryEmbedding>, cfg: &Config, vb: VarBuilder) -> Result<Self> {
let self_attn = Attention::new(rotary_emb, cfg, vb.pp("self_attn"))?;
let block_sparse_moe = SparseMoeBlock::new(cfg, vb.pp("block_sparse_moe"))?;
let input_layernorm =
RmsNorm::new(cfg.hidden_size, cfg.rms_norm_eps, vb.pp("input_layernorm"))?;
let post_attention_layernorm = RmsNorm::new(
cfg.hidden_size,
cfg.rms_norm_eps,
vb.pp("post_attention_layernorm"),
)?;
Ok(Self {
self_attn,
block_sparse_moe,
input_layernorm,
post_attention_layernorm,
})
}
fn forward(
&mut self,
xs: &Tensor,
attention_mask: Option<&Tensor>,
seqlen_offset: usize,
) -> Result<Tensor> {
let residual = xs;
let xs = self.input_layernorm.forward(xs)?;
let xs = self.self_attn.forward(&xs, attention_mask, seqlen_offset)?;
let xs = (xs + residual)?;
let residual = &xs;
let xs = xs
.apply(&self.post_attention_layernorm)?
.apply(&self.block_sparse_moe)?;
residual + xs
}
}
#[derive(Debug, Clone)]
pub struct Model {
embed_tokens: candle_nn::Embedding,
layers: Vec<DecoderLayer>,
norm: RmsNorm,
lm_head: Linear,
sliding_window: usize,
device: Device,
dtype: DType,
}
impl Model {
pub fn new(cfg: &Config, vb: VarBuilder) -> Result<Self> {
let vb_m = vb.pp("model");
let embed_tokens =
candle_nn::embedding(cfg.vocab_size, cfg.hidden_size, vb_m.pp("embed_tokens"))?;
let rotary_emb = Arc::new(RotaryEmbedding::new(vb.dtype(), cfg, vb_m.device())?);
let mut layers = Vec::with_capacity(cfg.num_hidden_layers);
let vb_l = vb_m.pp("layers");
for layer_idx in 0..cfg.num_hidden_layers {
let layer = DecoderLayer::new(rotary_emb.clone(), cfg, vb_l.pp(layer_idx))?;
layers.push(layer)
}
let norm = RmsNorm::new(cfg.hidden_size, cfg.rms_norm_eps, vb_m.pp("norm"))?;
let lm_head = linear_no_bias(cfg.hidden_size, cfg.vocab_size, vb.pp("lm_head"))?;
Ok(Self {
embed_tokens,
layers,
norm,
lm_head,
sliding_window: cfg.sliding_window,
device: vb.device().clone(),
dtype: vb.dtype(),
})
}
fn prepare_decoder_attention_mask(
&self,
b_size: usize,
tgt_len: usize,
seqlen_offset: usize,
) -> Result<Tensor> {
// Sliding window mask?
let mask: Vec<_> = (0..tgt_len)
.flat_map(|i| {
(0..tgt_len).map(move |j| {
if i < j || j + self.sliding_window < i {
f32::NEG_INFINITY
} else {
0.
}
})
})
.collect();
let mask = Tensor::from_slice(&mask, (tgt_len, tgt_len), &self.device)?;
let mask = if seqlen_offset > 0 {
let mask0 = Tensor::zeros((tgt_len, seqlen_offset), DType::F32, &self.device)?;
Tensor::cat(&[&mask0, &mask], D::Minus1)?
} else {
mask
};
mask.expand((b_size, 1, tgt_len, tgt_len + seqlen_offset))?
.to_dtype(self.dtype)
}
pub fn forward(&mut self, input_ids: &Tensor, seqlen_offset: usize) -> Result<Tensor> {
let (b_size, seq_len) = input_ids.dims2()?;
let attention_mask = if seq_len <= 1 {
None
} else {
let mask = self.prepare_decoder_attention_mask(b_size, seq_len, seqlen_offset)?;
Some(mask)
};
let mut xs = self.embed_tokens.forward(input_ids)?;
for layer in self.layers.iter_mut() {
xs = layer.forward(&xs, attention_mask.as_ref(), seqlen_offset)?
}
xs.narrow(1, seq_len - 1, 1)?
.apply(&self.norm)?
.apply(&self.lm_head)
}
}

1
candle-transformers/src/models/mod.rs
View File

@ -14,6 +14,7 @@ pub mod llama2_c_weights;
pub mod marian; pub mod marian;
pub mod mistral; pub mod mistral;
pub mod mixformer; pub mod mixformer;
pub mod mixtral;
pub mod mpt; pub mod mpt;
pub mod persimmon; pub mod persimmon;
pub mod quantized_blip; pub mod quantized_blip;