#![feature(min_specialization)] #![feature(arbitrary_self_types)] #![feature(arbitrary_self_types_pointers)] use std::{iter::once, thread::available_parallelism}; use anyhow::{Result, bail}; pub use node_entry::{NodeEntry, NodeRenderingEntries, NodeRenderingEntry}; use rustc_hash::FxHashMap; use turbo_rcstr::{RcStr, rcstr}; use turbo_tasks::{ FxIndexSet, ResolvedVc, TryJoinIterExt, Vc, graph::{AdjacencyMap, GraphTraversal}, }; use turbo_tasks_env::ProcessEnv; use turbo_tasks_fs::{File, FileSystemPath, to_sys_path}; use turbopack_core::{ asset::{Asset, AssetContent}, changed::content_changed, chunk::{ChunkingContext, ChunkingContextExt, EvaluatableAsset, EvaluatableAssets}, module::Module, module_graph::{ModuleGraph, chunk_group_info::ChunkGroupEntry}, output::{OutputAsset, OutputAssets, OutputAssetsSet}, source_map::GenerateSourceMap, virtual_output::VirtualOutputAsset, }; use self::{pool::NodeJsPool, source_map::StructuredError}; pub mod debug; pub mod embed_js; pub mod evaluate; pub mod execution_context; mod node_entry; mod pool; pub mod render; pub mod route_matcher; pub mod source_map; pub mod transforms; #[turbo_tasks::function] async fn emit( intermediate_asset: Vc>, intermediate_output_path: FileSystemPath, ) -> Result<()> { for asset in internal_assets(intermediate_asset, intermediate_output_path).await? { let _ = asset .content() .write(asset.path().owned().await?) .resolve() .await?; } Ok(()) } /// List of the all assets of the "internal" subgraph and a list of boundary /// assets that are not considered "internal" ("external") #[derive(Debug)] #[turbo_tasks::value] struct SeparatedAssets { internal_assets: ResolvedVc, external_asset_entrypoints: ResolvedVc, } /// Extracts the subgraph of "internal" assets (assets within the passes /// directory). Also lists all boundary assets that are not part of the /// "internal" subgraph. #[turbo_tasks::function] async fn internal_assets( intermediate_asset: ResolvedVc>, intermediate_output_path: FileSystemPath, ) -> Result> { Ok( *separate_assets_operation(intermediate_asset, intermediate_output_path) .read_strongly_consistent() .await? .internal_assets, ) } #[turbo_tasks::value(transparent)] pub struct AssetsForSourceMapping(FxHashMap>>); /// Extracts a map of "internal" assets ([`internal_assets`]) which implement /// the [GenerateSourceMap] trait. #[turbo_tasks::function] async fn internal_assets_for_source_mapping( intermediate_asset: Vc>, intermediate_output_path: FileSystemPath, ) -> Result> { let internal_assets = internal_assets(intermediate_asset, intermediate_output_path.clone()).await?; let intermediate_output_path = intermediate_output_path.clone(); let mut internal_assets_for_source_mapping = FxHashMap::default(); for asset in internal_assets.iter() { if let Some(generate_source_map) = ResolvedVc::try_sidecast::>(*asset) && let Some(path) = intermediate_output_path.get_path_to(&*asset.path().await?) { internal_assets_for_source_mapping.insert(path.to_string(), generate_source_map); } } Ok(Vc::cell(internal_assets_for_source_mapping)) } /// Returns a set of "external" assets on the boundary of the "internal" /// subgraph #[turbo_tasks::function] pub async fn external_asset_entrypoints( module: Vc>, runtime_entries: Vc, chunking_context: Vc>, intermediate_output_path: FileSystemPath, ) -> Result> { Ok(*separate_assets_operation( get_intermediate_asset(chunking_context, module, runtime_entries) .to_resolved() .await?, intermediate_output_path, ) .read_strongly_consistent() .await? .external_asset_entrypoints) } /// Splits the asset graph into "internal" assets and boundaries to "external" /// assets. #[turbo_tasks::function(operation)] async fn separate_assets_operation( intermediate_asset: ResolvedVc>, intermediate_output_path: FileSystemPath, ) -> Result> { let intermediate_output_path = intermediate_output_path.clone(); #[derive(PartialEq, Eq, Hash, Clone, Copy)] enum Type { Internal(ResolvedVc>), External(ResolvedVc>), } let get_asset_children = |asset| { let intermediate_output_path = intermediate_output_path.clone(); async move { let Type::Internal(asset) = asset else { return Ok(Vec::new()); }; asset .references() .await? .iter() .map(|asset| async { // Assets within the output directory are considered as "internal" and all // others as "external". We follow references on "internal" assets, but do not // look into references of "external" assets, since there are no "internal" // assets behind "externals" if asset.path().await?.is_inside_ref(&intermediate_output_path) { Ok(Type::Internal(*asset)) } else { Ok(Type::External(*asset)) } }) .try_join() .await } }; let graph = AdjacencyMap::new() .skip_duplicates() .visit(once(Type::Internal(intermediate_asset)), get_asset_children) .await .completed()? .into_inner(); let mut internal_assets = FxIndexSet::default(); let mut external_asset_entrypoints = FxIndexSet::default(); for item in graph.into_postorder_topological() { match item { Type::Internal(asset) => { internal_assets.insert(asset); } Type::External(asset) => { external_asset_entrypoints.insert(asset); } } } Ok(SeparatedAssets { internal_assets: ResolvedVc::cell(internal_assets), external_asset_entrypoints: ResolvedVc::cell(external_asset_entrypoints), } .cell()) } /// Emit a basic package.json that sets the type of the package to commonjs. /// Currently code generated for Node is CommonJS, while authored code may be /// ESM, for example. fn emit_package_json(dir: FileSystemPath) -> Result> { Ok(emit( Vc::upcast(VirtualOutputAsset::new( dir.join("package.json")?, AssetContent::file(File::from("{\"type\": \"commonjs\"}").into()), )), dir, )) } /// Creates a node.js renderer pool for an entrypoint. #[turbo_tasks::function(operation)] pub async fn get_renderer_pool_operation( cwd: FileSystemPath, env: ResolvedVc>, intermediate_asset: ResolvedVc>, intermediate_output_path: FileSystemPath, output_root: FileSystemPath, project_dir: FileSystemPath, debug: bool, ) -> Result> { emit_package_json(intermediate_output_path.clone())?.await?; emit(*intermediate_asset, output_root.clone()) .as_side_effect() .await?; let assets_for_source_mapping = internal_assets_for_source_mapping(*intermediate_asset, output_root.clone()); let entrypoint = intermediate_asset.path().owned().await?; let Some(cwd) = to_sys_path(cwd.clone()).await? else { bail!( "can only render from a disk filesystem, but `cwd = {}`", cwd.value_to_string().await? ); }; let Some(entrypoint) = to_sys_path(entrypoint.clone()).await? else { bail!( "can only render from a disk filesystem, but `entrypoint = {}`", entrypoint.value_to_string().await? ); }; // Invalidate pool when code content changes content_changed(*ResolvedVc::upcast(intermediate_asset)).await?; Ok(NodeJsPool::new( cwd, entrypoint, env.read_all() .await? .iter() .map(|(k, v)| (k.clone(), v.clone())) .collect(), assets_for_source_mapping.to_resolved().await?, output_root, project_dir, available_parallelism().map_or(1, |v| v.get()), debug, ) .cell()) } /// Converts a module graph into node.js executable assets #[turbo_tasks::function] pub async fn get_intermediate_asset( chunking_context: Vc>, main_entry: ResolvedVc>, other_entries: Vc, ) -> Result>> { Ok(Vc::upcast( chunking_context.root_entry_chunk_group_asset( chunking_context .chunk_path(None, main_entry.ident(), None, rcstr!(".js")) .owned() .await?, other_entries.with_entry(*main_entry), ModuleGraph::from_modules( Vc::cell(vec![ChunkGroupEntry::Entry( other_entries .await? .into_iter() .copied() .chain(std::iter::once(main_entry)) .map(ResolvedVc::upcast) .collect(), )]), false, ), OutputAssets::empty(), ), )) } #[derive(Clone, Debug)] #[turbo_tasks::value(shared)] pub struct ResponseHeaders { pub status: u16, pub headers: Vec<(RcStr, RcStr)>, } pub fn register() { turbo_tasks::register(); turbo_tasks_bytes::register(); turbo_tasks_fs::register(); turbopack_dev_server::register(); turbopack_ecmascript::register(); include!(concat!(env!("OUT_DIR"), "/register.rs")); }