internal/facts/imports.go - tools - Git at Google

 // Copyright 2018 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package facts

 import (
 	"go/types"

 	"golang.org/x/tools/internal/typeparams"
 )

 // importMap computes the import map for a package by traversing the
 // entire exported API each of its imports.
 //
 // This is a workaround for the fact that we cannot access the map used
 // internally by the types.Importer returned by go/importer. The entries
 // in this map are the packages and objects that may be relevant to the
 // current analysis unit.
 //
 // Packages in the map that are only indirectly imported may be
 // incomplete (!pkg.Complete()).
 //
 // This function scales very poorly with packages' transitive object
 // references, which can be more than a million for each package near
 // the top of a large project. (This was a significant contributor to
 // #60621.)
 // TODO(adonovan): opt: compute this information more efficiently
 // by obtaining it from the internals of the gcexportdata decoder.
 func importMap(imports []*types.Package) map[string]*types.Package {
 	objects := make(map[types.Object]bool)
 	typs := make(map[types.Type]bool) // Named and TypeParam
 	packages := make(map[string]*types.Package)

 	var addObj func(obj types.Object)
 	var addType func(T types.Type)

 	addObj = func(obj types.Object) {
 		if !objects[obj] {
 			objects[obj] = true
 			addType(obj.Type())
 			if pkg := obj.Pkg(); pkg != nil {
 				packages[pkg.Path()] = pkg
 			}
 		}
 	}

 	addType = func(T types.Type) {
 		switch T := T.(type) {
 		case *types.Basic:
 			// nop
 		case *types.Named:
 			// Remove infinite expansions of *types.Named by always looking at the origin.
 			// Some named types with type parameters [that will not type check] have
 			// infinite expansions:
 			//     type N[T any] struct { F *N[N[T]] }
 			// importMap() is called on such types when Analyzer.RunDespiteErrors is true.
 			T = typeparams.NamedTypeOrigin(T).(*types.Named)
 			if !typs[T] {
 				typs[T] = true
 				addObj(T.Obj())
 				addType(T.Underlying())
 				for i := 0; i < T.NumMethods(); i++ {
 					addObj(T.Method(i))
 				}
 				if tparams := typeparams.ForNamed(T); tparams != nil {
 					for i := 0; i < tparams.Len(); i++ {
 						addType(tparams.At(i))
 					}
 				}
 				if targs := typeparams.NamedTypeArgs(T); targs != nil {
 					for i := 0; i < targs.Len(); i++ {
 						addType(targs.At(i))
 					}
 				}
 			}
 		case *types.Pointer:
 			addType(T.Elem())
 		case *types.Slice:
 			addType(T.Elem())
 		case *types.Array:
 			addType(T.Elem())
 		case *types.Chan:
 			addType(T.Elem())
 		case *types.Map:
 			addType(T.Key())
 			addType(T.Elem())
 		case *types.Signature:
 			addType(T.Params())
 			addType(T.Results())
 			if tparams := typeparams.ForSignature(T); tparams != nil {
 				for i := 0; i < tparams.Len(); i++ {
 					addType(tparams.At(i))
 				}
 			}
 		case *types.Struct:
 			for i := 0; i < T.NumFields(); i++ {
 				addObj(T.Field(i))
 			}
 		case *types.Tuple:
 			for i := 0; i < T.Len(); i++ {
 				addObj(T.At(i))
 			}
 		case *types.Interface:
 			for i := 0; i < T.NumMethods(); i++ {
 				addObj(T.Method(i))
 			}
 			for i := 0; i < T.NumEmbeddeds(); i++ {
 				addType(T.EmbeddedType(i)) // walk Embedded for implicits
 			}
 		case *typeparams.Union:
 			for i := 0; i < T.Len(); i++ {
 				addType(T.Term(i).Type())
 			}
 		case *typeparams.TypeParam:
 			if !typs[T] {
 				typs[T] = true
 				addObj(T.Obj())
 				addType(T.Constraint())
 			}
 		}
 	}

 	for _, imp := range imports {
 		packages[imp.Path()] = imp

 		scope := imp.Scope()
 		for _, name := range scope.Names() {
 			addObj(scope.Lookup(name))
 		}
 	}

 	return packages
 }
	// Copyright 2018 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package facts

	import (
	"go/types"

	"golang.org/x/tools/internal/typeparams"
	)

	// importMap computes the import map for a package by traversing the
	// entire exported API each of its imports.
	//
	// This is a workaround for the fact that we cannot access the map used
	// internally by the types.Importer returned by go/importer. The entries
	// in this map are the packages and objects that may be relevant to the
	// current analysis unit.
	//
	// Packages in the map that are only indirectly imported may be
	// incomplete (!pkg.Complete()).
	//
	// This function scales very poorly with packages' transitive object
	// references, which can be more than a million for each package near
	// the top of a large project. (This was a significant contributor to
	// #60621.)
	// TODO(adonovan): opt: compute this information more efficiently
	// by obtaining it from the internals of the gcexportdata decoder.
	func importMap(imports []types.Package) map[string]types.Package {
	objects := make(map[types.Object]bool)
	typs := make(map[types.Type]bool) // Named and TypeParam
	packages := make(map[string]*types.Package)

	var addObj func(obj types.Object)
	var addType func(T types.Type)

	addObj = func(obj types.Object) {
	if !objects[obj] {
	objects[obj] = true
	addType(obj.Type())
	if pkg := obj.Pkg(); pkg != nil {
	packages[pkg.Path()] = pkg
	}
	}
	}

	addType = func(T types.Type) {
	switch T := T.(type) {
	case *types.Basic:
	// nop
	case *types.Named:
	// Remove infinite expansions of *types.Named by always looking at the origin.
	// Some named types with type parameters [that will not type check] have
	// infinite expansions:
	// type N[T any] struct { F *N[N[T]] }
	// importMap() is called on such types when Analyzer.RunDespiteErrors is true.
	T = typeparams.NamedTypeOrigin(T).(*types.Named)
	if !typs[T] {
	typs[T] = true
	addObj(T.Obj())
	addType(T.Underlying())
	for i := 0; i < T.NumMethods(); i++ {
	addObj(T.Method(i))
	}
	if tparams := typeparams.ForNamed(T); tparams != nil {
	for i := 0; i < tparams.Len(); i++ {
	addType(tparams.At(i))
	}
	}
	if targs := typeparams.NamedTypeArgs(T); targs != nil {
	for i := 0; i < targs.Len(); i++ {
	addType(targs.At(i))
	}
	}
	}
	case *types.Pointer:
	addType(T.Elem())
	case *types.Slice:
	addType(T.Elem())
	case *types.Array:
	addType(T.Elem())
	case *types.Chan:
	addType(T.Elem())
	case *types.Map:
	addType(T.Key())
	addType(T.Elem())
	case *types.Signature:
	addType(T.Params())
	addType(T.Results())
	if tparams := typeparams.ForSignature(T); tparams != nil {
	for i := 0; i < tparams.Len(); i++ {
	addType(tparams.At(i))
	}
	}
	case *types.Struct:
	for i := 0; i < T.NumFields(); i++ {
	addObj(T.Field(i))
	}
	case *types.Tuple:
	for i := 0; i < T.Len(); i++ {
	addObj(T.At(i))
	}
	case *types.Interface:
	for i := 0; i < T.NumMethods(); i++ {
	addObj(T.Method(i))
	}
	for i := 0; i < T.NumEmbeddeds(); i++ {
	addType(T.EmbeddedType(i)) // walk Embedded for implicits
	}
	case *typeparams.Union:
	for i := 0; i < T.Len(); i++ {
	addType(T.Term(i).Type())
	}
	case *typeparams.TypeParam:
	if !typs[T] {
	typs[T] = true
	addObj(T.Obj())
	addType(T.Constraint())
	}
	}
	}

	for _, imp := range imports {
	packages[imp.Path()] = imp

	scope := imp.Scope()
	for _, name := range scope.Names() {
	addObj(scope.Lookup(name))
	}
	}

	return packages
	}