use super::{BlobService, BlobWriter}; use crate::{proto, B3Digest}; use futures::sink::{SinkExt, SinkMapErr}; use std::{collections::VecDeque, io}; use tokio::task::JoinHandle; use tokio_stream::{wrappers::ReceiverStream, StreamExt}; use tokio_util::{ io::{CopyToBytes, SinkWriter, SyncIoBridge}, sync::{PollSendError, PollSender}, }; use tonic::{transport::Channel, Code, Status, Streaming}; use tracing::instrument; /// Connects to a (remote) tvix-store BlobService over gRPC. #[derive(Clone)] pub struct GRPCBlobService { /// A handle into the active tokio runtime. Necessary to spawn tasks. tokio_handle: tokio::runtime::Handle, /// The internal reference to a gRPC client. /// Cloning it is cheap, and it internally handles concurrent requests. grpc_client: proto::blob_service_client::BlobServiceClient, } impl GRPCBlobService { /// construct a [GRPCBlobService] from a [proto::blob_service_client::BlobServiceClient], /// and a [tokio::runtime::Handle]. pub fn new( grpc_client: proto::blob_service_client::BlobServiceClient, tokio_handle: tokio::runtime::Handle, ) -> Self { Self { tokio_handle, grpc_client, } } /// construct a [GRPCBlobService] from a [proto::blob_service_client::BlobServiceClient]. /// panics if called outside the context of a tokio runtime. pub fn from_client( grpc_client: proto::blob_service_client::BlobServiceClient, ) -> Self { Self { tokio_handle: tokio::runtime::Handle::current(), grpc_client, } } } impl BlobService for GRPCBlobService { #[instrument(skip(self, digest), fields(blob.digest=%digest))] fn has(&self, digest: &B3Digest) -> Result { // Get a new handle to the gRPC client, and copy the digest. let mut grpc_client = self.grpc_client.clone(); let digest = digest.clone(); let task: tokio::task::JoinHandle> = self.tokio_handle.spawn(async move { Ok(grpc_client .stat(proto::StatBlobRequest { digest: digest.to_vec(), ..Default::default() }) .await? .into_inner()) }); match self.tokio_handle.block_on(task)? { Ok(_blob_meta) => Ok(true), Err(e) if e.code() == Code::NotFound => Ok(false), Err(e) => Err(crate::Error::StorageError(e.to_string())), } } // On success, this returns a Ok(Some(io::Read)), which can be used to read // the contents of the Blob, identified by the digest. fn open_read( &self, digest: &B3Digest, ) -> Result>, crate::Error> { // Get a new handle to the gRPC client, and copy the digest. let mut grpc_client = self.grpc_client.clone(); let digest = digest.clone(); // Construct the task that'll send out the request and return the stream // the gRPC client should use to send [proto::BlobChunk], or an error if // the blob doesn't exist. let task: tokio::task::JoinHandle, Status>> = self.tokio_handle.spawn(async move { let stream = grpc_client .read(proto::ReadBlobRequest { digest: digest.to_vec(), }) .await? .into_inner(); Ok(stream) }); // This runs the task to completion, which on success will return a stream. // On reading from it, we receive individual [proto::BlobChunk], so we // massage this to a stream of bytes, // then create an [AsyncRead], which we'll turn into a [io::Read], // that's returned from the function. match self.tokio_handle.block_on(task)? { Ok(stream) => { // map the stream of proto::BlobChunk to bytes. let data_stream = stream.map(|x| { x.map(|x| VecDeque::from(x.data)) .map_err(|e| std::io::Error::new(std::io::ErrorKind::InvalidInput, e)) }); // Use StreamReader::new to convert to an AsyncRead. let data_reader = tokio_util::io::StreamReader::new(data_stream); // Use SyncIoBridge to turn it into a sync Read. let sync_reader = tokio_util::io::SyncIoBridge::new(data_reader); Ok(Some(Box::new(sync_reader))) } Err(e) if e.code() == Code::NotFound => Ok(None), Err(e) => Err(crate::Error::StorageError(e.to_string())), } } /// Returns a BlobWriter, that'll internally wrap each write in a // [proto::BlobChunk], which is send to the gRPC server. fn open_write(&self) -> Box { let mut grpc_client = self.grpc_client.clone(); // set up an mpsc channel passing around Bytes. let (tx, rx) = tokio::sync::mpsc::channel::(10); // bytes arriving on the RX side are wrapped inside a // [proto::BlobChunk], and a [ReceiverStream] is constructed. let blobchunk_stream = ReceiverStream::new(rx).map(|x| proto::BlobChunk { data: x.to_vec() }); // That receiver stream is used as a stream in the gRPC BlobService.put rpc call. let task: tokio::task::JoinHandle> = self .tokio_handle .spawn(async move { Ok(grpc_client.put(blobchunk_stream).await?.into_inner()) }); // The tx part of the channel is converted to a sink of byte chunks. // We need to make this a function pointer, not a closure. fn convert_error(_: PollSendError) -> io::Error { io::Error::from(io::ErrorKind::BrokenPipe) } let sink = PollSender::new(tx) .sink_map_err(convert_error as fn(PollSendError) -> io::Error); // We need to explicitly cast here, otherwise rustc does error with "expected fn pointer, found fn item" // … which is turned into an [tokio::io::AsyncWrite]. let async_writer = SinkWriter::new(CopyToBytes::new(sink)); // … which is then turned into a [io::Write]. let writer = SyncIoBridge::new(async_writer); Box::new(GRPCBlobWriter { tokio_handle: self.tokio_handle.clone(), // TODO: is the clone() ok here? task_and_writer: Some((task, writer)), digest: None, }) } } type BridgedWriter = SyncIoBridge< SinkWriter< CopyToBytes< SinkMapErr, fn(PollSendError) -> io::Error>, >, >, >; pub struct GRPCBlobWriter { /// A handle into the active tokio runtime. Necessary to block on the task /// containing the put request. tokio_handle: tokio::runtime::Handle, /// The task containing the put request, and the inner writer, if we're still writing. task_and_writer: Option<( JoinHandle>, BridgedWriter, )>, /// The digest that has been returned, if we successfully closed. digest: Option, } impl BlobWriter for GRPCBlobWriter { fn close(&mut self) -> Result { if self.task_and_writer.is_none() { // if we're already closed, return the b3 digest, which must exist. // If it doesn't, we already closed and failed once, and didn't handle the error. match &self.digest { Some(digest) => Ok(digest.clone()), None => Err(crate::Error::StorageError( "previously closed with error".to_string(), )), } } else { let (task, mut writer) = self.task_and_writer.take().unwrap(); // invoke shutdown, so the inner writer closes its internal tx side of // the channel. writer .shutdown() .map_err(|e| crate::Error::StorageError(e.to_string()))?; // block on the RPC call to return. // This ensures all chunks are sent out, and have been received by the // backend. match self.tokio_handle.block_on(task)? { Ok(resp) => { // return the digest from the response, and store it in self.digest for subsequent closes. let digest = B3Digest::from_vec(resp.digest).map_err(|_| { crate::Error::StorageError( "invalid root digest length in response".to_string(), ) })?; self.digest = Some(digest.clone()); Ok(digest) } Err(e) => Err(crate::Error::StorageError(e.to_string())), } } } } impl io::Write for GRPCBlobWriter { fn write(&mut self, buf: &[u8]) -> io::Result { match &mut self.task_and_writer { None => Err(io::Error::new( io::ErrorKind::NotConnected, "already closed", )), Some((_, ref mut writer)) => writer.write(buf), } } fn flush(&mut self) -> io::Result<()> { match &mut self.task_and_writer { None => Err(io::Error::new( io::ErrorKind::NotConnected, "already closed", )), Some((_, ref mut writer)) => writer.flush(), } } }