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denoland-deno/cli/tools/registry/tar.rs
David Sherret ded6afccf2
fix(publish): --dry-publish should error for gitignored excluded files (#23540)
Files that were gitignored only were not included in the diagnostic.
2024-04-24 18:52:05 +00:00

180 lines
4.7 KiB
Rust

// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use bytes::Bytes;
use deno_ast::MediaType;
use deno_core::anyhow::Context;
use deno_core::error::AnyError;
use deno_core::url::Url;
use sha2::Digest;
use std::fmt::Write as FmtWrite;
use std::io::Write;
use std::path::Path;
use tar::Header;
use crate::cache::LazyGraphSourceParser;
use super::diagnostics::PublishDiagnostic;
use super::diagnostics::PublishDiagnosticsCollector;
use super::paths::CollectedPublishPath;
use super::unfurl::SpecifierUnfurler;
#[derive(Debug, Clone, PartialEq)]
pub struct PublishableTarballFile {
pub path_str: String,
pub specifier: Url,
pub hash: String,
pub size: usize,
}
#[derive(Debug, Clone, PartialEq)]
pub struct PublishableTarball {
pub files: Vec<PublishableTarballFile>,
pub hash: String,
pub bytes: Bytes,
}
pub fn create_gzipped_tarball(
publish_paths: &[CollectedPublishPath],
source_parser: LazyGraphSourceParser,
diagnostics_collector: &PublishDiagnosticsCollector,
unfurler: &SpecifierUnfurler,
) -> Result<PublishableTarball, AnyError> {
let mut tar = TarGzArchive::new();
let mut files = vec![];
for path in publish_paths {
let path_str = &path.relative_path;
let specifier = &path.specifier;
let path = &path.path;
let content = resolve_content_maybe_unfurling(
path,
specifier,
unfurler,
source_parser,
diagnostics_collector,
)?;
files.push(PublishableTarballFile {
path_str: path_str.clone(),
specifier: specifier.clone(),
// This hash string matches the checksum computed by registry
hash: format!("sha256-{:x}", sha2::Sha256::digest(&content)),
size: content.len(),
});
tar
.add_file(format!(".{}", path_str), &content)
.with_context(|| {
format!("Unable to add file to tarball '{}'", path.display())
})?;
}
let v = tar.finish().context("Unable to finish tarball")?;
let hash_bytes: Vec<u8> = sha2::Sha256::digest(&v).iter().cloned().collect();
let mut hash = "sha256-".to_string();
for byte in hash_bytes {
write!(&mut hash, "{:02x}", byte).unwrap();
}
files.sort_by(|a, b| a.specifier.cmp(&b.specifier));
Ok(PublishableTarball {
files,
hash,
bytes: Bytes::from(v),
})
}
fn resolve_content_maybe_unfurling(
path: &Path,
specifier: &Url,
unfurler: &SpecifierUnfurler,
source_parser: LazyGraphSourceParser,
diagnostics_collector: &PublishDiagnosticsCollector,
) -> Result<Vec<u8>, AnyError> {
let parsed_source = match source_parser.get_or_parse_source(specifier)? {
Some(parsed_source) => parsed_source,
None => {
let data = std::fs::read(path)
.with_context(|| format!("Unable to read file '{}'", path.display()))?;
let media_type = MediaType::from_specifier(specifier);
match media_type {
MediaType::JavaScript
| MediaType::Jsx
| MediaType::Mjs
| MediaType::Cjs
| MediaType::TypeScript
| MediaType::Mts
| MediaType::Cts
| MediaType::Dts
| MediaType::Dmts
| MediaType::Dcts
| MediaType::Tsx => {
// continue
}
MediaType::SourceMap
| MediaType::Unknown
| MediaType::Json
| MediaType::Wasm
| MediaType::TsBuildInfo => {
// not unfurlable data
return Ok(data);
}
}
let text = String::from_utf8(data)?;
deno_ast::parse_module(deno_ast::ParseParams {
specifier: specifier.clone(),
text_info: deno_ast::SourceTextInfo::from_string(text),
media_type,
capture_tokens: false,
maybe_syntax: None,
scope_analysis: false,
})?
}
};
log::debug!("Unfurling {}", specifier);
let mut reporter = |diagnostic| {
diagnostics_collector.push(PublishDiagnostic::SpecifierUnfurl(diagnostic));
};
let content = unfurler.unfurl(specifier, &parsed_source, &mut reporter);
Ok(content.into_bytes())
}
struct TarGzArchive {
builder: tar::Builder<Vec<u8>>,
}
impl TarGzArchive {
pub fn new() -> Self {
Self {
builder: tar::Builder::new(Vec::new()),
}
}
pub fn add_file(
&mut self,
path: String,
data: &[u8],
) -> Result<(), AnyError> {
let mut header = Header::new_gnu();
header.set_size(data.len() as u64);
self.builder.append_data(&mut header, &path, data)?;
Ok(())
}
fn finish(mut self) -> Result<Vec<u8>, AnyError> {
self.builder.finish()?;
let bytes = self.builder.into_inner()?;
let mut gz_bytes = Vec::new();
let mut encoder = flate2::write::GzEncoder::new(
&mut gz_bytes,
flate2::Compression::default(),
);
encoder.write_all(&bytes)?;
encoder.finish()?;
Ok(gz_bytes)
}
}