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block_allocator.rs
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use std::sync::Arc;
use tokio::sync::{mpsc, oneshot};
use crate::radix::RadixAllocator;
#[derive(Debug, Clone)]
pub(crate) struct BlockAllocation {
pub allocation_id: u64,
pub blocks: Vec<u32>,
pub slots: Vec<u32>,
/// Prefix that was cached and for which the KV does not have to
/// be recomputed.
pub prefix_len: u32,
pub(crate) block_allocator: Option<BlockAllocator>,
}
impl Drop for BlockAllocation {
fn drop(&mut self) {
if let Some(block_allocator) = self.block_allocator.as_mut() {
block_allocator.free(self.blocks.clone(), self.allocation_id)
}
}
}
#[derive(Debug, Clone)]
pub(crate) struct BlockAllocator {
/// Channel to communicate with the background task
block_allocator: mpsc::UnboundedSender<BlockAllocatorCommand>,
}
impl BlockAllocator {
pub(crate) fn new(
max_batch_total_tokens: u32,
block_size: u32,
prefix_caching: bool,
window_size: Option<u32>,
) -> Self {
// Create channel
let (sender, receiver) = mpsc::unbounded_channel();
// Launch background queue task
tokio::spawn(block_allocator_task(
max_batch_total_tokens / block_size,
block_size,
prefix_caching,
window_size,
receiver,
));
Self {
block_allocator: sender,
}
}
pub(crate) async fn allocate(
&self,
adapter_index: u32,
tokens: u32,
prefill_tokens: Option<Arc<Vec<u32>>>,
) -> Option<BlockAllocation> {
let (response_sender, response_receiver) = oneshot::channel();
self.block_allocator
.send(BlockAllocatorCommand::Allocate {
adapter_index,
tokens,
prefill_tokens,
response_sender,
})
.unwrap();
response_receiver.await.unwrap().map(|mut allocation| {
allocation.block_allocator = Some(self.clone());
allocation
})
}
pub(crate) fn free(&self, blocks: Vec<u32>, allocation_id: u64) {
self.block_allocator
.send(BlockAllocatorCommand::Free {
allocation_id,
blocks,
})
.unwrap();
}
}
async fn block_allocator_task(
blocks: u32,
block_size: u32,
prefix_caching: bool,
window_size: Option<u32>,
mut receiver: mpsc::UnboundedReceiver<BlockAllocatorCommand>,
) {
let mut allocator: Box<dyn Allocator + Send> = if prefix_caching {
Box::new(RadixAllocator::new(block_size, blocks, window_size))
} else {
Box::new(SimpleAllocator::new(blocks, block_size, window_size))
};
while let Some(cmd) = receiver.recv().await {
match cmd {
BlockAllocatorCommand::Free {
blocks,
allocation_id,
} => allocator.free(blocks, allocation_id),
BlockAllocatorCommand::Allocate {
adapter_index,
tokens,
prefill_tokens,
response_sender,
} => {
response_sender
.send(allocator.allocate(adapter_index, tokens, prefill_tokens))
.unwrap();
}
}
}
}
#[derive(Debug)]
enum BlockAllocatorCommand {
Free {
blocks: Vec<u32>,
allocation_id: u64,
},
Allocate {
adapter_index: u32,
tokens: u32,
prefill_tokens: Option<Arc<Vec<u32>>>,
response_sender: oneshot::Sender<Option<BlockAllocation>>,
},
}
pub(crate) trait Allocator {
fn allocate(
&mut self,
adapter_index: u32,
tokens: u32,
prefill_tokens: Option<Arc<Vec<u32>>>,
) -> Option<BlockAllocation>;
fn free(&mut self, blocks: Vec<u32>, allocation_id: u64);
}
pub struct SimpleAllocator {
free_blocks: Vec<u32>,
block_size: u32,
window_size: Option<u32>,
}
impl SimpleAllocator {
fn new(blocks: u32, block_size: u32, window_size: Option<u32>) -> Self {
SimpleAllocator {
block_size,
// Block 0 is reserved for health checks
free_blocks: (1..blocks).collect(),
window_size,
}
}
}
impl Allocator for SimpleAllocator {
fn allocate(
&mut self,
_adapter_index: u32,
tokens: u32,
_prefill_tokens: Option<Arc<Vec<u32>>>,
) -> Option<BlockAllocation> {
// Apply window size
let (required_blocks, repeats) = {
let (tokens, repeats) = match self.window_size {
None => (tokens, 1),
Some(window_size) => {
let repeats = (tokens + window_size - 1) / window_size;
let tokens = core::cmp::min(tokens, window_size);
(tokens, repeats as usize)
}
};
// Pad to a multiple of block size
let required_blocks = (tokens + self.block_size - 1) / self.block_size;
(required_blocks, repeats)
};
let tokens = tokens as usize;
if required_blocks > self.free_blocks.len() as u32 {
None
} else {
let blocks = self
.free_blocks
.split_off(self.free_blocks.len() - required_blocks as usize);
let mut slots =
Vec::with_capacity((required_blocks * self.block_size * repeats as u32) as usize);
'slots: for block_id in blocks.repeat(repeats).iter() {
for s in (block_id * self.block_size)..((block_id + 1) * self.block_size) {
slots.push(s);
if slots.len() == tokens {
break 'slots;
}
}
}
Some(BlockAllocation {
allocation_id: 0,
blocks,
slots,
prefix_len: 0,
block_allocator: None,
})
}
}
fn free(&mut self, blocks: Vec<u32>, _allocation_id: u64) {
self.free_blocks.extend(blocks)
}
}