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denoland-deno/cli/emit.rs
2022-05-30 09:39:14 -04:00

722 lines
22 KiB
Rust

// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license.
//! The collection of APIs to be able to take `deno_graph` module graphs and
//! populate a cache, emit files, and transform a graph into the structures for
//! loading into an isolate.
use crate::cache::CacheType;
use crate::cache::Cacher;
use crate::colors;
use crate::config_file;
use crate::config_file::ConfigFile;
use crate::config_file::IgnoredCompilerOptions;
use crate::config_file::TsConfig;
use crate::diagnostics::Diagnostics;
use crate::flags;
use crate::graph_util::GraphData;
use crate::graph_util::ModuleEntry;
use crate::tsc;
use crate::version;
use deno_ast::swc::bundler::Hook;
use deno_ast::swc::bundler::ModuleRecord;
use deno_ast::swc::common::Span;
use deno_core::error::AnyError;
use deno_core::parking_lot::RwLock;
use deno_core::serde::Deserialize;
use deno_core::serde::Deserializer;
use deno_core::serde::Serialize;
use deno_core::serde::Serializer;
use deno_core::serde_json;
use deno_core::serde_json::json;
use deno_core::serde_json::Value;
use deno_core::ModuleSpecifier;
use deno_graph::MediaType;
use deno_graph::ModuleGraph;
use deno_graph::ModuleGraphError;
use deno_graph::ModuleKind;
use deno_graph::ResolutionError;
use std::collections::HashMap;
use std::collections::HashSet;
use std::fmt;
use std::result;
use std::sync::Arc;
use std::time::Instant;
/// Represents the "default" type library that should be used when type
/// checking the code in the module graph. Note that a user provided config
/// of `"lib"` would override this value.
#[derive(Debug, Clone, Eq, Hash, PartialEq)]
pub enum TypeLib {
DenoWindow,
DenoWorker,
UnstableDenoWindow,
UnstableDenoWorker,
}
impl Default for TypeLib {
fn default() -> Self {
Self::DenoWindow
}
}
impl Serialize for TypeLib {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: Serializer,
{
let value = match self {
Self::DenoWindow => vec!["deno.window".to_string()],
Self::DenoWorker => vec!["deno.worker".to_string()],
Self::UnstableDenoWindow => {
vec!["deno.window".to_string(), "deno.unstable".to_string()]
}
Self::UnstableDenoWorker => {
vec!["deno.worker".to_string(), "deno.unstable".to_string()]
}
};
Serialize::serialize(&value, serializer)
}
}
/// A structure representing stats from an emit operation for a graph.
#[derive(Clone, Debug, Default, Eq, PartialEq)]
pub struct Stats(pub Vec<(String, u32)>);
impl<'de> Deserialize<'de> for Stats {
fn deserialize<D>(deserializer: D) -> result::Result<Self, D::Error>
where
D: Deserializer<'de>,
{
let items: Vec<(String, u32)> = Deserialize::deserialize(deserializer)?;
Ok(Stats(items))
}
}
impl Serialize for Stats {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: Serializer,
{
Serialize::serialize(&self.0, serializer)
}
}
impl fmt::Display for Stats {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
writeln!(f, "Compilation statistics:")?;
for (key, value) in self.0.clone() {
writeln!(f, " {}: {}", key, value)?;
}
Ok(())
}
}
/// An enum that represents the base tsc configuration to return.
pub enum ConfigType {
/// Return a configuration for bundling, using swc to emit the bundle. This is
/// independent of type checking.
Bundle,
/// Return a configuration to use tsc to type check and optionally emit. This
/// is independent of either bundling or just emitting via swc
Check { lib: TypeLib, tsc_emit: bool },
/// Return a configuration to use swc to emit single module files.
Emit,
}
/// For a given configuration type and optionally a configuration file, return a
/// tuple of the resulting `TsConfig` struct and optionally any user
/// configuration options that were ignored.
pub fn get_ts_config(
config_type: ConfigType,
maybe_config_file: Option<&ConfigFile>,
maybe_user_config: Option<&HashMap<String, Value>>,
) -> Result<(TsConfig, Option<IgnoredCompilerOptions>), AnyError> {
let mut ts_config = match config_type {
ConfigType::Bundle => TsConfig::new(json!({
"checkJs": false,
"emitDecoratorMetadata": false,
"importsNotUsedAsValues": "remove",
"inlineSourceMap": false,
"inlineSources": false,
"sourceMap": false,
"jsx": "react",
"jsxFactory": "React.createElement",
"jsxFragmentFactory": "React.Fragment",
})),
ConfigType::Check { tsc_emit, lib } => {
let mut ts_config = TsConfig::new(json!({
"allowJs": true,
"allowSyntheticDefaultImports": true,
"experimentalDecorators": true,
"incremental": true,
"jsx": "react",
"isolatedModules": true,
"lib": lib,
"module": "esnext",
"resolveJsonModule": true,
"strict": true,
"target": "esnext",
"tsBuildInfoFile": "deno:///.tsbuildinfo",
"useDefineForClassFields": true,
// TODO(@kitsonk) remove for Deno 2.0
"useUnknownInCatchVariables": false,
}));
if tsc_emit {
ts_config.merge(&json!({
"emitDecoratorMetadata": false,
"importsNotUsedAsValues": "remove",
"inlineSourceMap": true,
"inlineSources": true,
"outDir": "deno://",
"removeComments": true,
}));
} else {
ts_config.merge(&json!({
"noEmit": true,
}));
}
ts_config
}
ConfigType::Emit => TsConfig::new(json!({
"checkJs": false,
"emitDecoratorMetadata": false,
"importsNotUsedAsValues": "remove",
"inlineSourceMap": true,
"inlineSources": true,
"sourceMap": false,
"jsx": "react",
"jsxFactory": "React.createElement",
"jsxFragmentFactory": "React.Fragment",
"resolveJsonModule": true,
})),
};
let maybe_ignored_options = if let Some(user_options) = maybe_user_config {
ts_config.merge_user_config(user_options)?
} else {
ts_config.merge_tsconfig_from_config_file(maybe_config_file)?
};
Ok((ts_config, maybe_ignored_options))
}
/// Transform the graph into root specifiers that we can feed `tsc`. We have to
/// provide the media type for root modules because `tsc` does not "resolve" the
/// media type like other modules, as well as a root specifier needs any
/// redirects resolved. If we aren't checking JavaScript, we need to include all
/// the emittable files in the roots, so they get type checked and optionally
/// emitted, otherwise they would be ignored if only imported into JavaScript.
fn get_tsc_roots(
roots: &[(ModuleSpecifier, ModuleKind)],
graph_data: &GraphData,
check_js: bool,
) -> Vec<(ModuleSpecifier, MediaType)> {
if !check_js {
graph_data
.entries()
.into_iter()
.filter_map(|(specifier, module_entry)| match module_entry {
ModuleEntry::Module {
media_type,
ts_check,
..
} => match &media_type {
MediaType::TypeScript
| MediaType::Tsx
| MediaType::Mts
| MediaType::Cts
| MediaType::Jsx => Some((specifier.clone(), *media_type)),
MediaType::JavaScript | MediaType::Mjs | MediaType::Cjs
if check_js || *ts_check =>
{
Some((specifier.clone(), *media_type))
}
_ => None,
},
_ => None,
})
.collect()
} else {
roots
.iter()
.filter_map(|(specifier, _)| match graph_data.get(specifier) {
Some(ModuleEntry::Module { media_type, .. }) => {
Some((specifier.clone(), *media_type))
}
_ => None,
})
.collect()
}
}
/// A hashing function that takes the source code, version and optionally a
/// user provided config and generates a string hash which can be stored to
/// determine if the cached emit is valid or not.
fn get_version(source_bytes: &[u8], config_bytes: &[u8]) -> String {
crate::checksum::gen(&[
source_bytes,
version::deno().as_bytes(),
config_bytes,
])
}
/// Determine if a given module kind and media type is emittable or not.
pub fn is_emittable(
kind: &ModuleKind,
media_type: &MediaType,
include_js: bool,
) -> bool {
if matches!(kind, ModuleKind::Synthetic) {
return false;
}
match &media_type {
MediaType::TypeScript
| MediaType::Mts
| MediaType::Cts
| MediaType::Tsx
| MediaType::Jsx => true,
MediaType::JavaScript | MediaType::Mjs | MediaType::Cjs => include_js,
_ => false,
}
}
/// Options for performing a check of a module graph. Note that the decision to
/// emit or not is determined by the `ts_config` settings.
pub struct CheckOptions {
/// The check flag from the option which can effect the filtering of
/// diagnostics in the emit result.
pub type_check_mode: flags::TypeCheckMode,
/// Set the debug flag on the TypeScript type checker.
pub debug: bool,
/// If true, any files emitted will be cached, even if there are diagnostics
/// produced. If false, if there are diagnostics, caching emitted files will
/// be skipped.
pub emit_with_diagnostics: bool,
/// The module specifier to the configuration file, passed to tsc so that
/// configuration related diagnostics are properly formed.
pub maybe_config_specifier: Option<ModuleSpecifier>,
/// The derived tsconfig that should be used when checking.
pub ts_config: TsConfig,
/// If true, `Check <specifier>` will be written to stdout for each root.
pub log_checks: bool,
/// If true, valid existing emits and `.tsbuildinfo` files will be ignored.
pub reload: bool,
pub reload_exclusions: HashSet<ModuleSpecifier>,
}
/// The result of a check or emit of a module graph. Note that the actual
/// emitted sources are stored in the cache and are not returned in the result.
#[derive(Debug, Default)]
pub struct CheckEmitResult {
pub diagnostics: Diagnostics,
pub stats: Stats,
}
/// Given a set of roots and graph data, type check the module graph and
/// optionally emit modules, updating the cache as appropriate. Emitting is
/// determined by the `ts_config` supplied in the options, and if emitting, the
/// files are stored in the cache.
///
/// It is expected that it is determined if a check and/or emit is validated
/// before the function is called.
pub fn check_and_maybe_emit(
roots: &[(ModuleSpecifier, ModuleKind)],
graph_data: Arc<RwLock<GraphData>>,
cache: &mut dyn Cacher,
options: CheckOptions,
) -> Result<CheckEmitResult, AnyError> {
let check_js = options.ts_config.get_check_js();
let segment_graph_data = {
let graph_data = graph_data.read();
graph_data.graph_segment(roots).unwrap()
};
if valid_emit(
&segment_graph_data,
cache,
&options.ts_config,
options.reload,
&options.reload_exclusions,
) {
return Ok(Default::default());
}
let root_names = get_tsc_roots(roots, &segment_graph_data, check_js);
if options.log_checks {
for (root, _) in roots {
let root_str = root.to_string();
// `$deno` specifiers are internal, don't print them.
if !root_str.contains("$deno") {
log::info!("{} {}", colors::green("Check"), root);
}
}
}
// while there might be multiple roots, we can't "merge" the build info, so we
// try to retrieve the build info for first root, which is the most common use
// case.
let maybe_tsbuildinfo = if options.reload {
None
} else {
cache.get(CacheType::TypeScriptBuildInfo, &roots[0].0)
};
// to make tsc build info work, we need to consistently hash modules, so that
// tsc can better determine if an emit is still valid or not, so we provide
// that data here.
let hash_data = vec![
options.ts_config.as_bytes(),
version::deno().as_bytes().to_owned(),
];
let config_bytes = options.ts_config.as_bytes();
let response = tsc::exec(tsc::Request {
config: options.ts_config,
debug: options.debug,
graph_data: graph_data.clone(),
hash_data,
maybe_config_specifier: options.maybe_config_specifier,
maybe_tsbuildinfo,
root_names,
})?;
let diagnostics = if options.type_check_mode == flags::TypeCheckMode::Local {
response.diagnostics.filter(|d| {
if let Some(file_name) = &d.file_name {
!file_name.starts_with("http")
} else {
true
}
})
} else {
response.diagnostics
};
// sometimes we want to emit when there are diagnostics, and sometimes we
// don't. tsc will always return an emit if there are diagnostics
if (diagnostics.is_empty() || options.emit_with_diagnostics)
&& !response.emitted_files.is_empty()
{
if let Some(info) = &response.maybe_tsbuildinfo {
// while we retrieve the build info for just the first module, it can be
// used for all the roots in the graph, so we will cache it for all roots
for (root, _) in roots {
cache.set(CacheType::TypeScriptBuildInfo, root, info.clone())?;
}
}
for emit in response.emitted_files.into_iter() {
if let Some(specifiers) = emit.maybe_specifiers {
assert!(specifiers.len() == 1);
// The emitted specifier might not be the file specifier we want, so we
// resolve it via the graph.
let graph_data = graph_data.read();
let specifier = graph_data.follow_redirect(&specifiers[0]);
let (source_bytes, media_type, ts_check) =
match graph_data.get(&specifier) {
Some(ModuleEntry::Module {
code,
media_type,
ts_check,
..
}) => (code.as_bytes(), *media_type, *ts_check),
_ => {
log::debug!("skipping emit for {}", specifier);
continue;
}
};
// Sometimes if `tsc` sees a CommonJS file or a JSON module, it will
// _helpfully_ output it, which we don't really want to do unless
// someone has enabled check_js.
if matches!(media_type, MediaType::Json)
|| (!check_js
&& !ts_check
&& matches!(
media_type,
MediaType::JavaScript | MediaType::Cjs | MediaType::Mjs
))
{
log::debug!("skipping emit for {}", specifier);
continue;
}
match emit.media_type {
MediaType::JavaScript | MediaType::Mjs | MediaType::Cjs => {
let version = get_version(source_bytes, &config_bytes);
cache.set(CacheType::Version, &specifier, version)?;
cache.set(CacheType::Emit, &specifier, emit.data)?;
}
MediaType::SourceMap => {
cache.set(CacheType::SourceMap, &specifier, emit.data)?;
}
// this only occurs with the runtime emit, but we are using the same
// code paths, so we handle it here.
MediaType::Dts | MediaType::Dcts | MediaType::Dmts => {
cache.set(CacheType::Declaration, &specifier, emit.data)?;
}
_ => unreachable!(
"unexpected media_type {} {}",
emit.media_type, specifier
),
}
}
}
}
Ok(CheckEmitResult {
diagnostics,
stats: response.stats,
})
}
pub struct EmitOptions {
pub ts_config: TsConfig,
pub reload: bool,
pub reload_exclusions: HashSet<ModuleSpecifier>,
}
/// Given a module graph, emit any appropriate modules and cache them.
// TODO(nayeemrmn): This would ideally take `GraphData` like
// `check_and_maybe_emit()`, but the AST isn't stored in that. Cleanup.
pub fn emit(
graph: &ModuleGraph,
cache: &mut dyn Cacher,
options: EmitOptions,
) -> Result<CheckEmitResult, AnyError> {
let start = Instant::now();
let config_bytes = options.ts_config.as_bytes();
let include_js = options.ts_config.get_check_js();
let emit_options = options.ts_config.into();
let mut emit_count = 0_u32;
let mut file_count = 0_u32;
for module in graph.modules() {
file_count += 1;
if !is_emittable(&module.kind, &module.media_type, include_js) {
continue;
}
let needs_reload =
options.reload && !options.reload_exclusions.contains(&module.specifier);
let version = get_version(
module.maybe_source.as_ref().map(|s| s.as_bytes()).unwrap(),
&config_bytes,
);
let is_valid =
cache
.get(CacheType::Version, &module.specifier)
.map_or(false, |v| {
v == get_version(
module.maybe_source.as_ref().map(|s| s.as_bytes()).unwrap(),
&config_bytes,
)
});
if is_valid && !needs_reload {
continue;
}
let transpiled_source = module
.maybe_parsed_source
.as_ref()
.map(|ps| ps.transpile(&emit_options))
.unwrap()?;
emit_count += 1;
cache.set(CacheType::Emit, &module.specifier, transpiled_source.text)?;
if let Some(map) = transpiled_source.source_map {
cache.set(CacheType::SourceMap, &module.specifier, map)?;
}
if !is_valid {
cache.set(CacheType::Version, &module.specifier, version)?;
}
}
let stats = Stats(vec![
("Files".to_string(), file_count),
("Emitted".to_string(), emit_count),
("Total time".to_string(), start.elapsed().as_millis() as u32),
]);
Ok(CheckEmitResult {
diagnostics: Diagnostics::default(),
stats,
})
}
/// Check a module graph to determine if the graph contains anything that
/// is required to be emitted to be valid. It determines what modules in the
/// graph are emittable and for those that are emittable, if there is currently
/// a valid emit in the cache.
fn valid_emit(
graph_data: &GraphData,
cache: &dyn Cacher,
ts_config: &TsConfig,
reload: bool,
reload_exclusions: &HashSet<ModuleSpecifier>,
) -> bool {
let config_bytes = ts_config.as_bytes();
let check_js = ts_config.get_check_js();
for (specifier, module_entry) in graph_data.entries() {
if let ModuleEntry::Module {
code,
media_type,
ts_check,
..
} = module_entry
{
match media_type {
MediaType::TypeScript
| MediaType::Mts
| MediaType::Cts
| MediaType::Tsx
| MediaType::Jsx => {}
MediaType::JavaScript | MediaType::Mjs | MediaType::Cjs => {
if !check_js && !ts_check {
continue;
}
}
_ => continue,
}
if reload && !reload_exclusions.contains(specifier) {
return false;
}
if let Some(version) = cache.get(CacheType::Version, specifier) {
if version != get_version(code.as_bytes(), &config_bytes) {
return false;
}
} else {
return false;
}
}
}
true
}
/// An adapter struct to make a deno_graph::ModuleGraphError display as expected
/// in the Deno CLI.
#[derive(Debug)]
pub struct GraphError(pub ModuleGraphError);
impl std::error::Error for GraphError {}
impl From<ModuleGraphError> for GraphError {
fn from(err: ModuleGraphError) -> Self {
Self(err)
}
}
impl fmt::Display for GraphError {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match &self.0 {
ModuleGraphError::ResolutionError(err) => {
if matches!(
err,
ResolutionError::InvalidDowngrade { .. }
| ResolutionError::InvalidLocalImport { .. }
) {
write!(f, "{}", err.to_string_with_range())
} else {
self.0.fmt(f)
}
}
_ => self.0.fmt(f),
}
}
}
/// This contains the logic for Deno to rewrite the `import.meta` when bundling.
pub struct BundleHook;
impl Hook for BundleHook {
fn get_import_meta_props(
&self,
span: Span,
module_record: &ModuleRecord,
) -> Result<Vec<deno_ast::swc::ast::KeyValueProp>, AnyError> {
use deno_ast::swc::ast;
Ok(vec![
ast::KeyValueProp {
key: ast::PropName::Ident(ast::Ident::new("url".into(), span)),
value: Box::new(ast::Expr::Lit(ast::Lit::Str(ast::Str {
span,
value: module_record.file_name.to_string().into(),
raw: None,
}))),
},
ast::KeyValueProp {
key: ast::PropName::Ident(ast::Ident::new("main".into(), span)),
value: Box::new(if module_record.is_entry {
ast::Expr::Member(ast::MemberExpr {
span,
obj: Box::new(ast::Expr::MetaProp(ast::MetaPropExpr {
span,
kind: ast::MetaPropKind::ImportMeta,
})),
prop: ast::MemberProp::Ident(ast::Ident::new("main".into(), span)),
})
} else {
ast::Expr::Lit(ast::Lit::Bool(ast::Bool { span, value: false }))
}),
},
])
}
}
impl From<config_file::TsConfig> for deno_ast::EmitOptions {
fn from(config: config_file::TsConfig) -> Self {
let options: config_file::EmitConfigOptions =
serde_json::from_value(config.0).unwrap();
let imports_not_used_as_values =
match options.imports_not_used_as_values.as_str() {
"preserve" => deno_ast::ImportsNotUsedAsValues::Preserve,
"error" => deno_ast::ImportsNotUsedAsValues::Error,
_ => deno_ast::ImportsNotUsedAsValues::Remove,
};
let (transform_jsx, jsx_automatic, jsx_development) =
match options.jsx.as_str() {
"react" => (true, false, false),
"react-jsx" => (true, true, false),
"react-jsxdev" => (true, true, true),
_ => (false, false, false),
};
deno_ast::EmitOptions {
emit_metadata: options.emit_decorator_metadata,
imports_not_used_as_values,
inline_source_map: options.inline_source_map,
inline_sources: options.inline_sources,
source_map: options.source_map,
jsx_automatic,
jsx_development,
jsx_factory: options.jsx_factory,
jsx_fragment_factory: options.jsx_fragment_factory,
jsx_import_source: options.jsx_import_source,
transform_jsx,
var_decl_imports: false,
}
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_is_emittable() {
assert!(is_emittable(
&ModuleKind::Esm,
&MediaType::TypeScript,
false
));
assert!(!is_emittable(
&ModuleKind::Synthetic,
&MediaType::TypeScript,
false
));
assert!(!is_emittable(&ModuleKind::Esm, &MediaType::Dts, false));
assert!(!is_emittable(&ModuleKind::Esm, &MediaType::Dcts, false));
assert!(!is_emittable(&ModuleKind::Esm, &MediaType::Dmts, false));
assert!(is_emittable(&ModuleKind::Esm, &MediaType::Tsx, false));
assert!(!is_emittable(
&ModuleKind::Esm,
&MediaType::JavaScript,
false
));
assert!(!is_emittable(&ModuleKind::Esm, &MediaType::Cjs, false));
assert!(!is_emittable(&ModuleKind::Esm, &MediaType::Mjs, false));
assert!(is_emittable(&ModuleKind::Esm, &MediaType::JavaScript, true));
assert!(is_emittable(&ModuleKind::Esm, &MediaType::Jsx, false));
assert!(!is_emittable(&ModuleKind::Esm, &MediaType::Json, false));
}
}