use crate::{
blobservice::BlobService,
chunkservice::ChunkService,
directoryservice::DirectoryService,
proto::{self, NamedNode},
BlobReader,
};
use nix_compat::nar;
use super::RenderError;
/// A NAR renderer, using a blob_service, chunk_service and directory_service
/// to render a NAR to a writer.
#[derive(Clone)]
pub struct NARRenderer<BS: BlobService, CS: ChunkService + Clone, DS: DirectoryService> {
blob_service: BS,
chunk_service: CS,
directory_service: DS,
}
impl<BS: BlobService, CS: ChunkService + Clone, DS: DirectoryService> NARRenderer<BS, CS, DS> {
pub fn new(blob_service: BS, chunk_service: CS, directory_service: DS) -> Self {
Self {
blob_service,
chunk_service,
directory_service,
}
}
/// Consumes a [proto::node::Node] pointing to the root of a (store) path,
/// and writes the contents in NAR serialization to the passed
/// [std::io::Write].
///
/// It uses the different clients in the struct to perform the necessary
/// lookups as it traverses the structure.
pub fn write_nar<W: std::io::Write>(
&self,
w: &mut W,
proto_root_node: &proto::node::Node,
) -> Result<(), RenderError> {
// Initialize NAR writer
let nar_root_node = nar::writer::open(w).map_err(RenderError::NARWriterError)?;
self.walk_node(nar_root_node, proto_root_node)
}
/// Process an intermediate node in the structure.
/// This consumes the node.
fn walk_node(
&self,
nar_node: nar::writer::Node,
proto_node: &proto::node::Node,
) -> Result<(), RenderError> {
match proto_node {
proto::node::Node::Symlink(proto_symlink_node) => {
nar_node
.symlink(&proto_symlink_node.target)
.map_err(RenderError::NARWriterError)?;
}
proto::node::Node::File(proto_file_node) => {
// get the digest we're referring to
let digest = &proto_file_node.digest;
// query blob_service for blob_meta
let resp = self
.blob_service
.stat(&proto::StatBlobRequest {
digest: digest.to_vec(),
include_chunks: true,
..Default::default()
})
.map_err(RenderError::StoreError)?;
match resp {
// if it's None, that's an error!
None => {
return Err(RenderError::BlobNotFound(
digest.to_vec(),
proto_file_node.name.to_owned(),
));
}
Some(blob_meta) => {
// make sure the blob_meta size matches what we expect from proto_file_node
let blob_meta_size = blob_meta.chunks.iter().fold(0, |acc, e| acc + e.size);
if blob_meta_size != proto_file_node.size {
return Err(RenderError::UnexpectedBlobMeta(
digest.to_vec(),
proto_file_node.name.to_owned(),
proto_file_node.size,
blob_meta_size,
));
}
let mut blob_reader = std::io::BufReader::new(BlobReader::open(
&self.chunk_service,
blob_meta,
));
nar_node
.file(
proto_file_node.executable,
proto_file_node.size.into(),
&mut blob_reader,
)
.map_err(RenderError::NARWriterError)?;
}
}
}
proto::node::Node::Directory(proto_directory_node) => {
// get the digest we're referring to
let digest: [u8; 32] =
proto_directory_node
.digest
.to_owned()
.try_into()
.map_err(|_e| {
RenderError::StoreError(crate::Error::StorageError(
"invalid digest len in directory node".to_string(),
))
})?;
// look it up with the directory service
let resp = self
.directory_service
.get(&digest)
.map_err(RenderError::StoreError)?;
match resp {
// if it's None, that's an error!
None => {
return Err(RenderError::DirectoryNotFound(
digest.to_vec(),
proto_directory_node.name.to_owned(),
))
}
Some(proto_directory) => {
// start a directory node
let mut nar_node_directory =
nar_node.directory().map_err(RenderError::NARWriterError)?;
// for each node in the directory, create a new entry with its name,
// and then invoke walk_node on that entry.
for proto_node in proto_directory.nodes() {
let child_node = nar_node_directory
.entry(proto_node.get_name())
.map_err(RenderError::NARWriterError)?;
self.walk_node(child_node, &proto_node)?;
}
// close the directory
nar_node_directory
.close()
.map_err(RenderError::NARWriterError)?;
}
}
}
}
Ok(())
}
}
