feat(tvix/tools/turbofetch): init

Change-Id: I2efa6f94f57e812c52371256a4e62d1d54ff5057 Reviewed-on: https://cl.tvl.fyi/c/depot/+/9925 Reviewed-by: flokli <flokli@flokli.de> Tested-by: BuildkiteCI
2023-11-04 10:09:20 +00:00 · 2023-11-04 10:09:20 +00:00 · bdda10a2f5
commit bdda10a2f5
parent 9cd2e92065
9 changed files with 8624 additions and 0 deletions
--- a/tvix/tools/turbofetch/Cargo.lock
+++ b/tvix/tools/turbofetch/Cargo.lock
--- a/tvix/tools/turbofetch/Cargo.nix
+++ b/tvix/tools/turbofetch/Cargo.nix
--- a/tvix/tools/turbofetch/Cargo.toml
+++ b/tvix/tools/turbofetch/Cargo.toml
@ -0,0 +1,28 @@
 [package]
 name = "turbofetch"
 version = "0.1.0"
 edition = "2021"
 # We don't join the //tvix workspace, as this is fairly cache.nixos.org-specific.
 [workspace]
 members = ["."]
 [dependencies]
 aws_lambda_events = { version = "0.11.1", default-features = false, features = ["lambda_function_urls"] }
 bytes = "1.5.0"
 data-encoding = "2.4.0"
 futures = { version = "0.3.29", default-features = false, features = ["std"] }
 httparse = "1.8.0"
 hyper = { version = "0.14.27", default-features = false }
 lambda_runtime = "0.8.2"
 magic-buffer = "0.1.0"
 rusoto_core = { version = "0.48.0", features = ["rustls"], default-features = false }
 rusoto_s3 = { version = "0.48.0", features = ["rustls"], default-features = false }
 serde_json = "1.0.108"
 serde = { version = "1.0.190", features = ["derive"] }
 tokio = { version = "1.33.0", features = ["full"] }
 tower = "0.4.13"
 # TODO(edef): zstd = "0.13.0"
 zstd = "0.9.0"
 tracing-subscriber = { version = "0.3.17", features = ["json"] }
 tracing = "0.1.40"
--- a/tvix/tools/turbofetch/OWNERS
+++ b/tvix/tools/turbofetch/OWNERS
@ -0,0 +1 @@
 edef
--- a/tvix/tools/turbofetch/default.nix
+++ b/tvix/tools/turbofetch/default.nix
@ -0,0 +1,12 @@
 { lib, pkgs, ... }:
 (pkgs.callPackage ./Cargo.nix {
  defaultCrateOverrides = pkgs.defaultCrateOverrides // {
    ring = prev: {
      # TODO(edef): implement CARGO_MANIFEST_LINKS in crate2nix
      CARGO_MANIFEST_LINKS = ''ring_core_${lib.replaceStrings ["."] ["_"] prev.version}'';
    };
  };
 }).rootCrate.build.override {
  runTests = true;
 }
--- a/tvix/tools/turbofetch/deploy.sh
+++ b/tvix/tools/turbofetch/deploy.sh
@ -0,0 +1,5 @@
 #! /usr/bin/env nix-shell
 #! nix-shell -i "bash -e"
 #! nix-shell -p cargo-lambda
 cargo lambda build --release
 cargo lambda deploy
--- a/tvix/tools/turbofetch/src/buffer.rs
+++ b/tvix/tools/turbofetch/src/buffer.rs
@ -0,0 +1,87 @@
 use magic_buffer::MagicBuffer;
 use std::cell::Cell;
 /// Buffer is a FIFO queue for bytes, built on a ring buffer.
 /// It always provides contiguous slices for both the readable and writable parts,
 /// using an underlying buffer that is "mirrored" in virtual memory.
 pub struct Buffer {
    buffer: MagicBuffer,
    /// first readable byte
    head: Cell<usize>,
    /// first writable byte
    tail: usize,
 }
 // SAFETY: MagicBuffer isn't bound to a thread, and neither are any of the other fields.
 // MagicBuffer ought to be Send+Sync itself, upstream PR at https://github.com/sklose/magic-buffer/pull/4
 unsafe impl Send for Buffer {}
 impl Buffer {
    /// Allocate a fresh buffer, with the specified capacity.
    /// The buffer can contain at most `capacity - 1` bytes.
    /// The capacity must be a power of two, and at least [Buffer::min_len].
    pub fn new(capacity: usize) -> Buffer {
        Buffer {
            // MagicBuffer::new verifies that `capacity` is a power of two,
            // and at least MagicBuffer::min_len().
            buffer: MagicBuffer::new(capacity).unwrap(),
            // `head == tail` means the buffer is empty.
            // In order to ensure that this remains unambiguous,
            // the buffer can only be filled with capacity-1 bytes.
            head: Cell::new(0),
            tail: 0,
        }
    }
    /// Returns the minimum buffer capacity.
    /// This depends on the operating system and architecture.
    pub fn min_capacity() -> usize {
        MagicBuffer::min_len()
    }
    /// Return the capacity of the buffer.
    /// This is equal to `self.data().len() + self.space().len() + 1`.
    pub fn capacity(&self) -> usize {
        self.buffer.len()
    }
    /// Return the valid, readable data in the buffer.
    pub fn data(&self) -> &[u8] {
        let len = self.buffer.len();
        let head = self.head.get();
        if head <= self.tail {
            &self.buffer[head..self.tail]
        } else {
            &self.buffer[head..self.tail + len]
        }
    }
    /// Mark `read_len` bytes of the readable data as consumed, freeing the space.
    pub fn consume(&self, read_len: usize) {
        debug_assert!(read_len <= self.data().len());
        let mut head = self.head.get();
        head += read_len;
        head &= self.buffer.len() - 1;
        self.head.set(head);
    }
    /// Return the empty, writable space in the buffer.
    pub fn space(&mut self) -> &mut [u8] {
        let len = self.buffer.len();
        let head = self.head.get();
        if head <= self.tail {
            &mut self.buffer[self.tail..head + len - 1]
        } else {
            &mut self.buffer[self.tail..head - 1]
        }
    }
    /// Mark `written_len` bytes of the writable space as valid, readable data.
    pub fn commit(&mut self, written_len: usize) {
        debug_assert!(written_len <= self.space().len());
        self.tail += written_len;
        self.tail &= self.buffer.len() - 1;
    }
 }
--- a/tvix/tools/turbofetch/src/lib.rs
+++ b/tvix/tools/turbofetch/src/lib.rs
@ -0,0 +1,103 @@
 use std::{mem::MaybeUninit, str};
 use tokio::io::{self, AsyncRead, AsyncReadExt};
 pub use buffer::Buffer;
 mod buffer;
 /// Read as much data into `buffer` as possible.
 /// Returns [io::ErrorKind::OutOfMemory] if the buffer is already full.
 async fn slurp(buffer: &mut Buffer, sock: &mut (impl AsyncRead + Unpin)) -> io::Result<()> {
    match buffer.space() {
        [] => Err(io::Error::new(io::ErrorKind::OutOfMemory, "buffer filled")),
        buf => {
            let n = sock.read(buf).await?;
            if n == 0 {
                return Err(io::ErrorKind::UnexpectedEof.into());
            }
            buffer.commit(n);
            Ok(())
        }
    }
 }
 fn get_content_length(headers: &[httparse::Header]) -> io::Result<u64> {
    for header in headers {
        if header.name == "Transfer-Encoding" {
            return Err(io::Error::new(
                io::ErrorKind::InvalidData,
                "Transfer-Encoding is unsupported",
            ));
        }
        if header.name == "Content-Length" {
            return str::from_utf8(header.value)
                .ok()
                .and_then(|v| v.parse().ok())
                .ok_or_else(|| {
                    io::Error::new(io::ErrorKind::InvalidData, "invalid Content-Length")
                });
        }
    }
    Err(io::Error::new(
        io::ErrorKind::InvalidData,
        "Content-Length missing",
    ))
 }
 /// Read an HTTP response from `sock` using `buffer`, returning the response body.
 /// Returns an error if anything but 200 OK is received.
 ///
 /// The buffer must have enough space to contain the entire response body.
 /// If there is not enough space, [io::ErrorKind::OutOfMemory] is returned.
 ///
 /// The HTTP response must use `Content-Length`, without `Transfer-Encoding`.
 pub async fn parse_response<'a>(
    sock: &mut (impl AsyncRead + Unpin),
    buffer: &'a mut Buffer,
 ) -> io::Result<&'a [u8]> {
    let body_len = loop {
        let mut headers = [MaybeUninit::uninit(); 16];
        let mut response = httparse::Response::new(&mut []);
        let status = httparse::ParserConfig::default()
            .parse_response_with_uninit_headers(&mut response, buffer.data(), &mut headers)
            .map_err(|e| io::Error::new(io::ErrorKind::InvalidData, e))?;
        if let httparse::Status::Complete(n) = status {
            buffer.consume(n);
            let code = response.code.unwrap();
            if code != 200 {
                return Err(io::Error::new(
                    io::ErrorKind::Other,
                    format!("HTTP response {code}"),
                ));
            }
            break get_content_length(response.headers)?;
        }
        slurp(buffer, sock).await?;
    };
    let buf_len = buffer.space().len() + buffer.data().len();
    if body_len > buf_len as u64 {
        return Err(io::Error::new(
            io::ErrorKind::OutOfMemory,
            "HTTP response body does not fit in buffer",
        ));
    }
    let body_len = body_len as usize;
    while buffer.data().len() < body_len {
        slurp(buffer, sock).await?;
    }
    let data = buffer.data();
    buffer.consume(body_len);
    Ok(&data[..body_len])
 }
--- a/tvix/tools/turbofetch/src/main.rs
+++ b/tvix/tools/turbofetch/src/main.rs
@ -0,0 +1,220 @@
 //! turbofetch is a high-performance bulk S3 object aggregator.
 //!
 //! It operates on two S3 buckets: a source bucket (nix-cache), and a
 //! work bucket defined at runtime. The work bucket contains a job file
 //! consisting of concatenated 32-character keys, representing narinfo
 //! files in the source bucket, without the `.narinfo` suffix or any
 //! other separators.
 //!
 //! Each run of turbofetch processes a half-open range of indices from the
 //! job file, and outputs a zstd stream of concatenated objects, without
 //! additional separators and in no particular order. These segment files
 //! are written into the work bucket, named for the range of indices they
 //! cover. `/narinfo.zst/000000000c380d40-000000000c385b60` covers the 20k
 //! objects `[0xc380d40, 0xc385b60) = [205000000, 205020000)`. Empirically,
 //! segment files of 20k objects achieve a compression ratio of 4.7x.
 //!
 //! Reassembly is left to narinfo2parquet, which interprets StorePath lines.
 //!
 //! TODO(edef): any retries/error handling whatsoever
 //! Currently, it fails an entire range if anything goes wrong, and doesn't
 //! write any output.
 use bytes::Bytes;
 use futures::{stream::FuturesUnordered, Stream, TryStreamExt};
 use rusoto_core::ByteStream;
 use rusoto_s3::{GetObjectRequest, PutObjectRequest, S3Client, S3};
 use serde::Deserialize;
 use std::{io::Write, mem, ops::Range, ptr};
 use tokio::{
    io::{self, AsyncReadExt, AsyncWriteExt},
    net::TcpStream,
 };
 /// Fetch a group of keys, streaming concatenated chunks as they arrive from S3.
 /// `keys` must be a slice from the job file. Any network error at all fails the
 /// entire batch, and there is no rate limiting.
 fn fetch(keys: &[[u8; 32]]) -> impl Stream<Item = io::Result<Bytes>> {
    // S3 supports only HTTP/1.1, but we can ease the pain somewhat by using
    // HTTP pipelining. It terminates the TCP connection after receiving 100
    // requests, so we chunk the keys up accordingly, and make one connection
    // for each chunk.
    keys.chunks(100)
        .map(|chunk| {
            const PREFIX: &[u8] = b"GET /nix-cache/";
            const SUFFIX: &[u8] = b".narinfo HTTP/1.1\nHost: s3.amazonaws.com\n\n";
            const LENGTH: usize = PREFIX.len() + 32 + SUFFIX.len();
            let mut request = Vec::with_capacity(LENGTH * 100);
            for key in chunk {
                request.extend_from_slice(PREFIX);
                request.extend_from_slice(key);
                request.extend_from_slice(SUFFIX);
            }
            (request, chunk.len())
        })
        .map(|(request, n)| async move {
            let (mut read, mut write) = TcpStream::connect("s3.amazonaws.com:80")
                .await?
                .into_split();
            let _handle = tokio::spawn(async move {
                let request = request;
                write.write_all(&request).await
            });
            let mut buffer = turbofetch::Buffer::new(512 * 1024);
            let mut bodies = vec![];
            for _ in 0..n {
                let body = turbofetch::parse_response(&mut read, &mut buffer).await?;
                bodies.extend_from_slice(body);
            }
            Ok::<_, io::Error>(Bytes::from(bodies))
        })
        .collect::<FuturesUnordered<_>>()
 }
 /// Retrieve a range of keys from the job file.
 async fn get_range(
    s3: &'static S3Client,
    bucket: String,
    key: String,
    range: Range<u64>,
 ) -> io::Result<Box<[[u8; 32]]>> {
    let resp = s3
        .get_object(GetObjectRequest {
            bucket,
            key,
            range: Some(format!("bytes={}-{}", range.start * 32, range.end * 32 - 1)),
            ..GetObjectRequest::default()
        })
        .await
        .map_err(|e| io::Error::new(io::ErrorKind::Other, e))?;
    let mut body = vec![];
    resp.body
        .ok_or(io::ErrorKind::InvalidData)?
        .into_async_read()
        .read_to_end(&mut body)
        .await?;
    let body = exact_chunks(body.into_boxed_slice()).ok_or(io::ErrorKind::InvalidData)?;
    Ok(body)
 }
 fn exact_chunks(mut buf: Box<[u8]>) -> Option<Box<[[u8; 32]]>> {
    // SAFETY: We ensure that `buf.len()` is a multiple of 32, and there are no alignment requirements.
    unsafe {
        let ptr = buf.as_mut_ptr();
        let len = buf.len();
        if len % 32 != 0 {
            return None;
        }
        let ptr = ptr as *mut [u8; 32];
        let len = len / 32;
        mem::forget(buf);
        Some(Box::from_raw(ptr::slice_from_raw_parts_mut(ptr, len)))
    }
 }
 // TODO(edef): factor this out into a separate entry point
 #[tokio::main(flavor = "current_thread")]
 async fn main() -> Result<(), lambda_runtime::Error> {
    let s3 = S3Client::new(rusoto_core::Region::UsEast1);
    let s3 = &*Box::leak(Box::new(s3));
    tracing_subscriber::fmt()
        .json()
        .with_max_level(tracing::Level::INFO)
        // this needs to be set to remove duplicated information in the log.
        .with_current_span(false)
        // this needs to be set to false, otherwise ANSI color codes will
        // show up in a confusing manner in CloudWatch logs.
        .with_ansi(false)
        // disabling time is handy because CloudWatch will add the ingestion time.
        .without_time()
        // remove the name of the function from every log entry
        .with_target(false)
        .init();
    lambda_runtime::run(lambda_runtime::service_fn(|event| func(s3, event))).await
 }
 /// Lambda request body
 #[derive(Debug, Deserialize)]
 struct Params {
    work_bucket: String,
    job_file: String,
    start: u64,
    end: u64,
 }
 #[tracing::instrument(skip(s3, event), fields(req_id = %event.context.request_id))]
 async fn func(
    s3: &'static S3Client,
    event: lambda_runtime::LambdaEvent<
        aws_lambda_events::lambda_function_urls::LambdaFunctionUrlRequest,
    >,
 ) -> Result<&'static str, lambda_runtime::Error> {
    let mut params = event.payload.body.ok_or("no body")?;
    if event.payload.is_base64_encoded {
        params = String::from_utf8(data_encoding::BASE64.decode(params.as_bytes())?)?;
    }
    let params: Params = serde_json::from_str(&params)?;
    if params.start >= params.end {
        return Err("nope".into());
    }
    let keys = get_range(
        s3,
        params.work_bucket.clone(),
        params.job_file.to_owned(),
        params.start..params.end,
    )
    .await?;
    let zchunks = fetch(&keys)
        .try_fold(
            Box::new(zstd::Encoder::new(vec![], zstd::DEFAULT_COMPRESSION_LEVEL).unwrap()),
            |mut w, buf| {
                w.write_all(&buf).unwrap();
                async { Ok(w) }
            },
        )
        .await?;
    let zchunks = to_byte_stream(zchunks.finish().unwrap());
    tracing::info!("we got to put_object");
    s3.put_object(PutObjectRequest {
        bucket: params.work_bucket,
        key: format!("narinfo.zst/{:016x}-{:016x}", params.start, params.end),
        body: Some(zchunks),
        ..Default::default()
    })
    .await
    .map_err(|e| io::Error::new(io::ErrorKind::Other, e))?;
    tracing::info!("… and it worked!");
    Ok("OK")
 }
 fn to_byte_stream(buffer: Vec<u8>) -> ByteStream {
    let size_hint = buffer.len();
    ByteStream::new_with_size(
        futures::stream::once(async { Ok(buffer.into()) }),
        size_hint,
    )
 }