Documentation ¶
Index ¶
- type CSSRepr
- type EntryPoint
- type ExportData
- type ImportData
- type InputFile
- type InputFileRepr
- type JSRepr
- type JSReprMeta
- type LinkerFile
- type LinkerGraph
- func (g *LinkerGraph) AddPartToFile(sourceIndex uint32, part js_ast.Part) uint32
- func (g *LinkerGraph) EntryPoints() []EntryPoint
- func (g *LinkerGraph) GenerateNewSymbol(sourceIndex uint32, kind js_ast.SymbolKind, originalName string) js_ast.Ref
- func (g *LinkerGraph) GenerateRuntimeSymbolImportAndUse(sourceIndex uint32, partIndex uint32, name string, useCount uint32)
- func (g *LinkerGraph) GenerateSymbolImportAndUse(sourceIndex uint32, partIndex uint32, ref js_ast.Ref, useCount uint32, ...)
- type OutputFile
- type SideEffects
- type SideEffectsKind
- type WrapKind
Constants ¶
This section is empty.
Variables ¶
This section is empty.
Functions ¶
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Types ¶
type CSSRepr ¶
type CSSRepr struct { AST css_ast.AST // If present, this is the JavaScript stub corresponding to this CSS file. // A JavaScript stub is automatically generated for a CSS file when it's // imported from a JavaScript file. JSSourceIndex ast.Index32 }
func (*CSSRepr) ImportRecords ¶
func (repr *CSSRepr) ImportRecords() *[]ast.ImportRecord
type EntryPoint ¶
type EntryPoint struct { // This may be an absolute path or a relative path. If absolute, it will // eventually be turned into a relative path by computing the path relative // to the "outbase" directory. Then this relative path will be joined onto // the "outdir" directory to form the final output path for this entry point. OutputPath string // This is the source index of the entry point. This file must have a valid // entry point kind (i.e. not "none"). SourceIndex uint32 // Manually specified output paths are ignored when computing the default // "outbase" directory, which is computed as the lowest common ancestor of // all automatically generated output paths. OutputPathWasAutoGenerated bool }
type ExportData ¶
type ExportData struct { Ref js_ast.Ref // Export star resolution happens first before import resolution. That means // it cannot yet determine if duplicate names from export star resolution are // ambiguous (point to different symbols) or not (point to the same symbol). // This issue can happen in the following scenario: // // // entry.js // export * from './a' // export * from './b' // // // a.js // export * from './c' // // // b.js // export {x} from './c' // // // c.js // export let x = 1, y = 2 // // In this case "entry.js" should have two exports "x" and "y", neither of // which are ambiguous. To handle this case, ambiguity resolution must be // deferred until import resolution time. That is done using this array. PotentiallyAmbiguousExportStarRefs []ImportData // This is the file that the named export above came from. This will be // different from the file that contains this object if this is a re-export. NameLoc logger.Loc // Optional, goes with sourceIndex, ignore if zero SourceIndex uint32 }
type ImportData ¶
type ImportData struct { // This is an array of intermediate statements that re-exported this symbol // in a chain before getting to the final symbol. This can be done either with // "export * from" or "export {} from". If this is done with "export * from" // then this may not be the result of a single chain but may instead form // a diamond shape if this same symbol was re-exported multiple times from // different files. ReExports []js_ast.Dependency NameLoc logger.Loc // Optional, goes with sourceIndex, ignore if zero Ref js_ast.Ref SourceIndex uint32 }
type InputFile ¶
type InputFile struct { Source logger.Source Repr InputFileRepr InputSourceMap *sourcemap.SourceMap // If this file ends up being used in the bundle, these are additional files // that must be written to the output directory. It's used by the "file" // loader. AdditionalFiles []OutputFile UniqueKeyForFileLoader string SideEffects SideEffects Loader config.Loader }
type InputFileRepr ¶
type InputFileRepr interface {
ImportRecords() *[]ast.ImportRecord
}
type JSRepr ¶
type JSRepr struct { AST js_ast.AST Meta JSReprMeta // If present, this is the CSS file that this JavaScript stub corresponds to. // A JavaScript stub is automatically generated for a CSS file when it's // imported from a JavaScript file. CSSSourceIndex ast.Index32 }
func (*JSRepr) ImportRecords ¶
func (repr *JSRepr) ImportRecords() *[]ast.ImportRecord
type JSReprMeta ¶
type JSReprMeta struct { // This is only for TypeScript files. If an import symbol is in this map, it // means the import couldn't be found and doesn't actually exist. This is not // an error in TypeScript because the import is probably just a type. // // Normally we remove all unused imports for TypeScript files during parsing, // which automatically removes type-only imports. But there are certain re- // export situations where it's impossible to tell if an import is a type or // not: // // import {typeOrNotTypeWhoKnows} from 'path'; // export {typeOrNotTypeWhoKnows}; // // Really people should be using the TypeScript "isolatedModules" flag with // bundlers like this one that compile TypeScript files independently without // type checking. That causes the TypeScript type checker to emit the error // "Re-exporting a type when the '--isolatedModules' flag is provided requires // using 'export type'." But we try to be robust to such code anyway. IsProbablyTypeScriptType map[js_ast.Ref]bool // Imports are matched with exports in a separate pass from when the matched // exports are actually bound to the imports. Here "binding" means adding non- // local dependencies on the parts in the exporting file that declare the // exported symbol to all parts in the importing file that use the imported // symbol. // // This must be a separate pass because of the "probably TypeScript type" // check above. We can't generate the part for the export namespace until // we've matched imports with exports because the generated code must omit // type-only imports in the export namespace code. And we can't bind exports // to imports until the part for the export namespace is generated since that // part needs to participate in the binding. // // This array holds the deferred imports to bind so the pass can be split // into two separate passes. ImportsToBind map[js_ast.Ref]ImportData // This includes both named exports and re-exports. // // Named exports come from explicit export statements in the original file, // and are copied from the "NamedExports" field in the AST. // // Re-exports come from other files and are the result of resolving export // star statements (i.e. "export * from 'foo'"). ResolvedExports map[string]ExportData ResolvedExportStar *ExportData // Never iterate over "resolvedExports" directly. Instead, iterate over this // array. Some exports in that map aren't meant to end up in generated code. // This array excludes these exports and is also sorted, which avoids non- // determinism due to random map iteration order. SortedAndFilteredExportAliases []string // If this is an entry point, this array holds a reference to one free // temporary symbol for each entry in "sortedAndFilteredExportAliases". // These may be needed to store copies of CommonJS re-exports in ESM. CJSExportCopies []js_ast.Ref // This is merged on top of the corresponding map from the parser in the AST. // You should call "TopLevelSymbolToParts" to access this instead of accessing // it directly. TopLevelSymbolToPartsOverlay map[js_ast.Ref][]uint32 // The index of the automatically-generated part used to represent the // CommonJS or ESM wrapper. This part is empty and is only useful for tree // shaking and code splitting. The wrapper can't be inserted into the part // because the wrapper contains other parts, which can't be represented by // the current part system. Only wrapped files have one of these. WrapperPartIndex ast.Index32 // The index of the automatically-generated part used to handle entry point // specific stuff. If a certain part is needed by the entry point, it's added // as a dependency of this part. This is important for parts that are marked // as removable when unused and that are not used by anything else. Only // entry point files have one of these. EntryPointPartIndex ast.Index32 // This is true if this file is affected by top-level await, either by having // a top-level await inside this file or by having an import/export statement // that transitively imports such a file. It is forbidden to call "require()" // on these files since they are evaluated asynchronously. IsAsyncOrHasAsyncDependency bool Wrap WrapKind // If true, the "__export(exports, { ... })" call will be force-included even // if there are no parts that reference "exports". Otherwise this call will // be removed due to the tree shaking pass. This is used when for entry point // files when code related to the current output format needs to reference // the "exports" variable. ForceIncludeExportsForEntryPoint bool // This is set when we need to pull in the "__export" symbol in to the part // at "nsExportPartIndex". This can't be done in "createExportsForFile" // because of concurrent map hazards. Instead, it must be done later. NeedsExportSymbolFromRuntime bool NeedsMarkAsModuleSymbolFromRuntime bool // Wrapped files must also ensure that their dependencies are wrapped. This // flag is used during the traversal that enforces this invariant, and is used // to detect when the fixed point has been reached. DidWrapDependencies bool }
This contains linker-specific metadata corresponding to a "file" struct from the initial scan phase of the bundler. It's separated out because it's conceptually only used for a single linking operation and because multiple linking operations may be happening in parallel with different metadata for the same file.
type LinkerFile ¶
type LinkerFile struct { InputFile InputFile // This holds all entry points that can reach this file. It will be used to // assign the parts in this file to a chunk. EntryBits helpers.BitSet // The minimum number of links in the module graph to get from an entry point // to this file DistanceFromEntryPoint uint32 // If "entryPointKind" is not "entryPointNone", this is the index of the // corresponding entry point chunk. EntryPointChunkIndex uint32 // This is true if this file has been marked as live by the tree shaking // algorithm. IsLive bool // contains filtered or unexported fields }
func (*LinkerFile) IsEntryPoint ¶
func (f *LinkerFile) IsEntryPoint() bool
func (*LinkerFile) IsUserSpecifiedEntryPoint ¶
func (f *LinkerFile) IsUserSpecifiedEntryPoint() bool
func (*LinkerFile) LineColumnTracker ¶ added in v0.11.23
func (f *LinkerFile) LineColumnTracker() *logger.LineColumnTracker
Note: This is not guarded by a mutex. Make sure this isn't called from a parallel part of the code.
type LinkerGraph ¶
type LinkerGraph struct { Files []LinkerFile Symbols js_ast.SymbolMap // We should avoid traversing all files in the bundle, because the linker // should be able to run a linking operation on a large bundle where only // a few files are needed (e.g. an incremental compilation scenario). This // holds all files that could possibly be reached through the entry points. // If you need to iterate over all files in the linking operation, iterate // over this array. This array is also sorted in a deterministic ordering // to help ensure deterministic builds (source indices are random). ReachableFiles []uint32 // This maps from unstable source index to stable reachable file index. This // is useful as a deterministic key for sorting if you need to sort something // containing a source index (such as "js_ast.Ref" symbol references). StableSourceIndices []uint32 // contains filtered or unexported fields }
func CloneLinkerGraph ¶ added in v0.11.13
func CloneLinkerGraph( inputFiles []InputFile, reachableFiles []uint32, originalEntryPoints []EntryPoint, codeSplitting bool, ) LinkerGraph
func (*LinkerGraph) AddPartToFile ¶
func (g *LinkerGraph) AddPartToFile(sourceIndex uint32, part js_ast.Part) uint32
func (*LinkerGraph) EntryPoints ¶
func (g *LinkerGraph) EntryPoints() []EntryPoint
Prevent packages that depend on us from adding or removing entry points
func (*LinkerGraph) GenerateNewSymbol ¶
func (g *LinkerGraph) GenerateNewSymbol(sourceIndex uint32, kind js_ast.SymbolKind, originalName string) js_ast.Ref
func (*LinkerGraph) GenerateRuntimeSymbolImportAndUse ¶
func (g *LinkerGraph) GenerateRuntimeSymbolImportAndUse( sourceIndex uint32, partIndex uint32, name string, useCount uint32, )
func (*LinkerGraph) GenerateSymbolImportAndUse ¶
type OutputFile ¶
type SideEffects ¶
type SideEffects struct { // This is optional additional information for use in error messages Data *resolver.SideEffectsData Kind SideEffectsKind }
type SideEffectsKind ¶
type SideEffectsKind uint8
const ( // The default value conservatively considers all files to have side effects. HasSideEffects SideEffectsKind = iota // This file was listed as not having side effects by a "package.json" // file in one of our containing directories with a "sideEffects" field. NoSideEffects_PackageJSON // This file was loaded using a data-oriented loader (e.g. "text") that is // known to not have side effects. NoSideEffects_PureData // Same as above but it came from a plugin. We don't want to warn about // unused imports to these files since running the plugin is a side effect. // Removing the import would not call the plugin which is observable. NoSideEffects_PureData_FromPlugin )
type WrapKind ¶
type WrapKind uint8
const ( WrapNone WrapKind = iota // The module will be bundled CommonJS-style like this: // // // foo.ts // let require_foo = __commonJS((exports, module) => { // exports.foo = 123; // }); // // // bar.ts // let foo = flag ? require_foo() : null; // WrapCJS // The module will be bundled ESM-style like this: // // // foo.ts // var foo, foo_exports = {}; // __exports(foo_exports, { // foo: () => foo // }); // let init_foo = __esm(() => { // foo = 123; // }); // // // bar.ts // let foo = flag ? (init_foo(), foo_exports) : null; // WrapESM )
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