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mirror of https://github.com/golang/go synced 2024-11-19 05:24:42 -07:00
go/internal/lsp/source/completion.go
Muir Manders 431033348d internal/lsp: fix function value completions
Previously we would always expand *types.Func completion candidates to
function calls, even if the expected type matched the function itself,
not its return value. Now we check the function itself before we check
its return value. This fixes cases like this:

func foo() int { return 0 }
var f func() int
f = <foo> // now completes to "foo" instead of "foo()"

Also, *types.Var function values were never getting expanded to calls.
I fixed the completion formatting to know that both *types.Func
and *types.Var objects might need to be invoked in the completion
item. This fixes cases like this:

foo := func() int { return 0 }
var i int
i = <foo()> // now completes to "foo()" instead of "foo"

Change-Id: I8d0e9e2774f92866a3dd881092c13019fb3f3fd5
GitHub-Last-Rev: 7442bc84b5bbb86296289bbc745ec56a5f89d901
GitHub-Pull-Request: golang/tools#122
Reviewed-on: https://go-review.googlesource.com/c/tools/+/182879
Run-TryBot: Rebecca Stambler <rstambler@golang.org>
TryBot-Result: Gobot Gobot <gobot@golang.org>
Reviewed-by: Rebecca Stambler <rstambler@golang.org>
2019-06-20 15:43:39 +00:00

978 lines
27 KiB
Go

// 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 source
import (
"context"
"fmt"
"go/ast"
"go/token"
"go/types"
"golang.org/x/tools/go/ast/astutil"
"golang.org/x/tools/internal/lsp/snippet"
"golang.org/x/tools/internal/span"
)
type CompletionItem struct {
// Label is the primary text the user sees for this completion item.
Label string
// Detail is supplemental information to present to the user.
// This often contains the type or return type of the completion item.
Detail string
// InsertText is the text to insert if this item is selected.
// Any of the prefix that has already been typed is not trimmed.
// The insert text does not contain snippets.
InsertText string
Kind CompletionItemKind
// Score is the internal relevance score.
// A higher score indicates that this completion item is more relevant.
Score float64
// Snippet is the LSP snippet for the completion item, without placeholders.
// The LSP specification contains details about LSP snippets.
// For example, a snippet for a function with the following signature:
//
// func foo(a, b, c int)
//
// would be:
//
// foo(${1:})
//
plainSnippet *snippet.Builder
// PlaceholderSnippet is the LSP snippet for the completion ite, containing
// placeholders. The LSP specification contains details about LSP snippets.
// For example, a placeholder snippet for a function with the following signature:
//
// func foo(a, b, c int)
//
// would be:
//
// foo(${1:a int}, ${2: b int}, ${3: c int})
//
placeholderSnippet *snippet.Builder
}
// Snippet is a convenience function that determines the snippet that should be
// used for an item, depending on if the callee wants placeholders or not.
func (i *CompletionItem) Snippet(usePlaceholders bool) string {
if usePlaceholders {
if i.placeholderSnippet != nil {
return i.placeholderSnippet.String()
}
}
if i.plainSnippet != nil {
return i.plainSnippet.String()
}
return i.InsertText
}
type CompletionItemKind int
const (
Unknown CompletionItemKind = iota
InterfaceCompletionItem
StructCompletionItem
TypeCompletionItem
ConstantCompletionItem
FieldCompletionItem
ParameterCompletionItem
VariableCompletionItem
FunctionCompletionItem
MethodCompletionItem
PackageCompletionItem
)
// Scoring constants are used for weighting the relevance of different candidates.
const (
// stdScore is the base score for all completion items.
stdScore float64 = 1.0
// highScore indicates a very relevant completion item.
highScore float64 = 10.0
// lowScore indicates an irrelevant or not useful completion item.
lowScore float64 = 0.01
)
// completer contains the necessary information for a single completion request.
type completer struct {
// Package-specific fields.
types *types.Package
info *types.Info
qf types.Qualifier
// view is the View associated with this completion request.
view View
// ctx is the context associated with this completion request.
ctx context.Context
// pos is the position at which the request was triggered.
pos token.Pos
// path is the path of AST nodes enclosing the position.
path []ast.Node
// seen is the map that ensures we do not return duplicate results.
seen map[types.Object]bool
// items is the list of completion items returned.
items []CompletionItem
// surrounding describes the identifier surrounding the position.
surrounding *Selection
// expectedType conains information about the type we expect the completion
// candidate to be. It will be the zero value if no information is available.
expectedType typeInference
// enclosingFunction is the function declaration enclosing the position.
enclosingFunction *types.Signature
// enclosingCompositeLiteral contains information about the composite literal
// enclosing the position.
enclosingCompositeLiteral *compLitInfo
}
type compLitInfo struct {
// cl is the *ast.CompositeLit enclosing the position.
cl *ast.CompositeLit
// clType is the type of cl.
clType types.Type
// kv is the *ast.KeyValueExpr enclosing the position, if any.
kv *ast.KeyValueExpr
// inKey is true if we are certain the position is in the key side
// of a key-value pair.
inKey bool
// maybeInFieldName is true if inKey is false and it is possible
// we are completing a struct field name. For example,
// "SomeStruct{<>}" will be inKey=false, but maybeInFieldName=true
// because we _could_ be completing a field name.
maybeInFieldName bool
}
// A Selection represents the cursor position and surrounding identifier.
type Selection struct {
Content string
Range span.Range
Cursor token.Pos
}
func (p Selection) Prefix() string {
return p.Content[:p.Cursor-p.Range.Start]
}
func (c *completer) setSurrounding(ident *ast.Ident) {
if c.surrounding != nil {
return
}
if !(ident.Pos() <= c.pos && c.pos <= ident.End()) {
return
}
c.surrounding = &Selection{
Content: ident.Name,
Range: span.NewRange(c.view.Session().Cache().FileSet(), ident.Pos(), ident.End()),
Cursor: c.pos,
}
}
// found adds a candidate completion.
//
// Only the first candidate of a given name is considered.
func (c *completer) found(obj types.Object, score float64) {
if obj.Pkg() != nil && obj.Pkg() != c.types && !obj.Exported() {
return // inaccessible
}
if c.seen[obj] {
return
}
c.seen[obj] = true
cand := candidate{
obj: obj,
score: score,
}
if c.matchingType(&cand) {
cand.score *= highScore
}
if c.wantTypeName() && !isTypeName(obj) {
cand.score *= lowScore
}
c.items = append(c.items, c.item(cand))
}
// candidate represents a completion candidate.
type candidate struct {
// obj is the types.Object to complete to.
obj types.Object
// score is used to rank candidates.
score float64
// expandFuncCall is true if obj should be invoked in the completion.
// For example, expandFuncCall=true yields "foo()", expandFuncCall=false yields "foo".
expandFuncCall bool
}
// Completion returns a list of possible candidates for completion, given a
// a file and a position.
//
// The selection is computed based on the preceding identifier and can be used by
// the client to score the quality of the completion. For instance, some clients
// may tolerate imperfect matches as valid completion results, since users may make typos.
func Completion(ctx context.Context, f GoFile, pos token.Pos) ([]CompletionItem, *Selection, error) {
file := f.GetAST(ctx)
if file == nil {
return nil, nil, fmt.Errorf("no AST for %s", f.URI())
}
pkg := f.GetPackage(ctx)
if pkg == nil || pkg.IsIllTyped() {
return nil, nil, fmt.Errorf("package for %s is ill typed", f.URI())
}
// Completion is based on what precedes the cursor.
// Find the path to the position before pos.
path, _ := astutil.PathEnclosingInterval(file, pos-1, pos-1)
if path == nil {
return nil, nil, fmt.Errorf("cannot find node enclosing position")
}
// Skip completion inside comments.
for _, g := range file.Comments {
if g.Pos() <= pos && pos <= g.End() {
return nil, nil, nil
}
}
// Skip completion inside any kind of literal.
if _, ok := path[0].(*ast.BasicLit); ok {
return nil, nil, nil
}
clInfo := enclosingCompositeLiteral(path, pos, pkg.GetTypesInfo())
c := &completer{
types: pkg.GetTypes(),
info: pkg.GetTypesInfo(),
qf: qualifier(file, pkg.GetTypes(), pkg.GetTypesInfo()),
view: f.View(),
ctx: ctx,
path: path,
pos: pos,
seen: make(map[types.Object]bool),
enclosingFunction: enclosingFunction(path, pos, pkg.GetTypesInfo()),
enclosingCompositeLiteral: clInfo,
}
// Set the filter surrounding.
if ident, ok := path[0].(*ast.Ident); ok {
c.setSurrounding(ident)
}
c.expectedType = expectedType(c)
// Struct literals are handled entirely separately.
if c.wantStructFieldCompletions() {
if err := c.structLiteralFieldName(); err != nil {
return nil, nil, err
}
return c.items, c.surrounding, nil
}
switch n := path[0].(type) {
case *ast.Ident:
// Is this the Sel part of a selector?
if sel, ok := path[1].(*ast.SelectorExpr); ok && sel.Sel == n {
if err := c.selector(sel); err != nil {
return nil, nil, err
}
return c.items, c.surrounding, nil
}
// reject defining identifiers
if obj, ok := pkg.GetTypesInfo().Defs[n]; ok {
if v, ok := obj.(*types.Var); ok && v.IsField() {
// An anonymous field is also a reference to a type.
} else {
of := ""
if obj != nil {
qual := types.RelativeTo(pkg.GetTypes())
of += ", of " + types.ObjectString(obj, qual)
}
return nil, nil, fmt.Errorf("this is a definition%s", of)
}
}
if err := c.lexical(); err != nil {
return nil, nil, err
}
// The function name hasn't been typed yet, but the parens are there:
// recv.‸(arg)
case *ast.TypeAssertExpr:
// Create a fake selector expression.
if err := c.selector(&ast.SelectorExpr{X: n.X}); err != nil {
return nil, nil, err
}
case *ast.SelectorExpr:
// The go parser inserts a phantom "_" Sel node when the selector is
// not followed by an identifier or a "(". The "_" isn't actually in
// the text, so don't think it is our surrounding.
// TODO: Find a way to differentiate between phantom "_" and real "_",
// perhaps by checking if "_" is present in file contents.
if n.Sel.Name != "_" || c.pos != n.Sel.Pos() {
c.setSurrounding(n.Sel)
}
if err := c.selector(n); err != nil {
return nil, nil, err
}
default:
// fallback to lexical completions
if err := c.lexical(); err != nil {
return nil, nil, err
}
}
return c.items, c.surrounding, nil
}
func (c *completer) wantStructFieldCompletions() bool {
clInfo := c.enclosingCompositeLiteral
if clInfo == nil {
return false
}
return clInfo.isStruct() && (clInfo.inKey || clInfo.maybeInFieldName)
}
func (c *completer) wantTypeName() bool {
return c.expectedType.wantTypeName
}
// selector finds completions for the specified selector expression.
func (c *completer) selector(sel *ast.SelectorExpr) error {
// Is sel a qualified identifier?
if id, ok := sel.X.(*ast.Ident); ok {
if pkgname, ok := c.info.Uses[id].(*types.PkgName); ok {
// Enumerate package members.
scope := pkgname.Imported().Scope()
for _, name := range scope.Names() {
c.found(scope.Lookup(name), stdScore)
}
return nil
}
}
// Invariant: sel is a true selector.
tv, ok := c.info.Types[sel.X]
if !ok {
return fmt.Errorf("cannot resolve %s", sel.X)
}
// Add methods of T.
mset := types.NewMethodSet(tv.Type)
for i := 0; i < mset.Len(); i++ {
c.found(mset.At(i).Obj(), stdScore)
}
// Add methods of *T.
if tv.Addressable() && !types.IsInterface(tv.Type) && !isPointer(tv.Type) {
mset := types.NewMethodSet(types.NewPointer(tv.Type))
for i := 0; i < mset.Len(); i++ {
c.found(mset.At(i).Obj(), stdScore)
}
}
// Add fields of T.
for _, f := range fieldSelections(tv.Type) {
c.found(f, stdScore)
}
return nil
}
// lexical finds completions in the lexical environment.
func (c *completer) lexical() error {
var scopes []*types.Scope // scopes[i], where i<len(path), is the possibly nil Scope of path[i].
for _, n := range c.path {
switch node := n.(type) {
case *ast.FuncDecl:
n = node.Type
case *ast.FuncLit:
n = node.Type
}
scopes = append(scopes, c.info.Scopes[n])
}
scopes = append(scopes, c.types.Scope(), types.Universe)
// Track seen variables to avoid showing completions for shadowed variables.
// This works since we look at scopes from innermost to outermost.
seen := make(map[string]struct{})
// Process scopes innermost first.
for i, scope := range scopes {
if scope == nil {
continue
}
for _, name := range scope.Names() {
declScope, obj := scope.LookupParent(name, c.pos)
if declScope != scope {
continue // Name was declared in some enclosing scope, or not at all.
}
// If obj's type is invalid, find the AST node that defines the lexical block
// containing the declaration of obj. Don't resolve types for packages.
if _, ok := obj.(*types.PkgName); !ok && obj.Type() == types.Typ[types.Invalid] {
// Match the scope to its ast.Node. If the scope is the package scope,
// use the *ast.File as the starting node.
var node ast.Node
if i < len(c.path) {
node = c.path[i]
} else if i == len(c.path) { // use the *ast.File for package scope
node = c.path[i-1]
}
if node != nil {
if resolved := resolveInvalid(obj, node, c.info); resolved != nil {
obj = resolved
}
}
}
score := stdScore
// Rank builtins significantly lower than other results.
if scope == types.Universe {
score *= 0.1
}
// If we haven't already added a candidate for an object with this name.
if _, ok := seen[obj.Name()]; !ok {
seen[obj.Name()] = struct{}{}
c.found(obj, score)
}
}
}
return nil
}
// structLiteralFieldName finds completions for struct field names inside a struct literal.
func (c *completer) structLiteralFieldName() error {
clInfo := c.enclosingCompositeLiteral
// Mark fields of the composite literal that have already been set,
// except for the current field.
addedFields := make(map[*types.Var]bool)
for _, el := range clInfo.cl.Elts {
if kvExpr, ok := el.(*ast.KeyValueExpr); ok {
if clInfo.kv == kvExpr {
continue
}
if key, ok := kvExpr.Key.(*ast.Ident); ok {
if used, ok := c.info.Uses[key]; ok {
if usedVar, ok := used.(*types.Var); ok {
addedFields[usedVar] = true
}
}
}
}
}
switch t := clInfo.clType.(type) {
case *types.Struct:
for i := 0; i < t.NumFields(); i++ {
field := t.Field(i)
if !addedFields[field] {
c.found(field, highScore)
}
}
// Add lexical completions if we aren't certain we are in the key part of a
// key-value pair.
if clInfo.maybeInFieldName {
return c.lexical()
}
default:
return c.lexical()
}
return nil
}
func (cl *compLitInfo) isStruct() bool {
_, ok := cl.clType.(*types.Struct)
return ok
}
// enclosingCompositeLiteral returns information about the composite literal enclosing the
// position.
func enclosingCompositeLiteral(path []ast.Node, pos token.Pos, info *types.Info) *compLitInfo {
for _, n := range path {
switch n := n.(type) {
case *ast.CompositeLit:
// The enclosing node will be a composite literal if the user has just
// opened the curly brace (e.g. &x{<>) or the completion request is triggered
// from an already completed composite literal expression (e.g. &x{foo: 1, <>})
//
// The position is not part of the composite literal unless it falls within the
// curly braces (e.g. "foo.Foo<>Struct{}").
if !(n.Lbrace <= pos && pos <= n.Rbrace) {
return nil
}
tv, ok := info.Types[n]
if !ok {
return nil
}
clInfo := compLitInfo{
cl: n,
clType: tv.Type.Underlying(),
}
var (
expr ast.Expr
hasKeys bool
)
for _, el := range n.Elts {
// Remember the expression that the position falls in, if any.
if el.Pos() <= pos && pos <= el.End() {
expr = el
}
if kv, ok := el.(*ast.KeyValueExpr); ok {
hasKeys = true
// If expr == el then we know the position falls in this expression,
// so also record kv as the enclosing *ast.KeyValueExpr.
if expr == el {
clInfo.kv = kv
break
}
}
}
if clInfo.kv != nil {
// If in a *ast.KeyValueExpr, we know we are in the key if the position
// is to the left of the colon (e.g. "Foo{F<>: V}".
clInfo.inKey = pos <= clInfo.kv.Colon
} else if hasKeys {
// If we aren't in a *ast.KeyValueExpr but the composite literal has
// other *ast.KeyValueExprs, we must be on the key side of a new
// *ast.KeyValueExpr (e.g. "Foo{F: V, <>}").
clInfo.inKey = true
} else {
switch clInfo.clType.(type) {
case *types.Struct:
if len(n.Elts) == 0 {
// If the struct literal is empty, next could be a struct field
// name or an expression (e.g. "Foo{<>}" could become "Foo{F:}"
// or "Foo{someVar}").
clInfo.maybeInFieldName = true
} else if len(n.Elts) == 1 {
// If there is one expression and the position is in that expression
// and the expression is an identifier, we may be writing a field
// name or an expression (e.g. "Foo{F<>}").
_, clInfo.maybeInFieldName = expr.(*ast.Ident)
}
case *types.Map:
// If we aren't in a *ast.KeyValueExpr we must be adding a new key
// to the map.
clInfo.inKey = true
}
}
return &clInfo
default:
if breaksExpectedTypeInference(n) {
return nil
}
}
}
return nil
}
// enclosingFunction returns the signature of the function enclosing the given position.
func enclosingFunction(path []ast.Node, pos token.Pos, info *types.Info) *types.Signature {
for _, node := range path {
switch t := node.(type) {
case *ast.FuncDecl:
if obj, ok := info.Defs[t.Name]; ok {
return obj.Type().(*types.Signature)
}
case *ast.FuncLit:
if typ, ok := info.Types[t]; ok {
return typ.Type.(*types.Signature)
}
}
}
return nil
}
func (c *completer) expectedCompositeLiteralType() types.Type {
clInfo := c.enclosingCompositeLiteral
switch t := clInfo.clType.(type) {
case *types.Slice:
if clInfo.inKey {
return types.Typ[types.Int]
}
return t.Elem()
case *types.Array:
if clInfo.inKey {
return types.Typ[types.Int]
}
return t.Elem()
case *types.Map:
if clInfo.inKey {
return t.Key()
}
return t.Elem()
case *types.Struct:
// If we are completing a key (i.e. field name), there is no expected type.
if clInfo.inKey {
return nil
}
// If we are in a key-value pair, but not in the key, then we must be on the
// value side. The expected type of the value will be determined from the key.
if clInfo.kv != nil {
if key, ok := clInfo.kv.Key.(*ast.Ident); ok {
for i := 0; i < t.NumFields(); i++ {
if field := t.Field(i); field.Name() == key.Name {
return field.Type()
}
}
}
} else {
// If we aren't in a key-value pair and aren't in the key, we must be using
// implicit field names.
// The order of the literal fields must match the order in the struct definition.
// Find the element that the position belongs to and suggest that field's type.
if i := indexExprAtPos(c.pos, clInfo.cl.Elts); i < t.NumFields() {
return t.Field(i).Type()
}
}
}
return nil
}
// typeModifier represents an operator that changes the expected type.
type typeModifier int
const (
dereference typeModifier = iota // dereference ("*") operator
reference // reference ("&") operator
chanRead // channel read ("<-") operator
)
// typeInference holds information we have inferred about a type that can be
// used at the current position.
type typeInference struct {
// objType is the desired type of an object used at the query position.
objType types.Type
// wantTypeName is true if we expect the name of a type.
wantTypeName bool
// modifiers are prefixes such as "*", "&" or "<-" that influence how
// a candidate type relates to the expected type.
modifiers []typeModifier
}
// expectedType returns information about the expected type for an expression at
// the query position.
func expectedType(c *completer) typeInference {
if ti := expectTypeName(c); ti.wantTypeName {
return ti
}
if c.enclosingCompositeLiteral != nil {
return typeInference{objType: c.expectedCompositeLiteralType()}
}
var (
modifiers []typeModifier
typ types.Type
)
Nodes:
for i, node := range c.path {
switch node := node.(type) {
case *ast.BinaryExpr:
// Determine if query position comes from left or right of op.
e := node.X
if c.pos < node.OpPos {
e = node.Y
}
if tv, ok := c.info.Types[e]; ok {
typ = tv.Type
break Nodes
}
case *ast.AssignStmt:
// Only rank completions if you are on the right side of the token.
if c.pos > node.TokPos {
i := indexExprAtPos(c.pos, node.Rhs)
if i >= len(node.Lhs) {
i = len(node.Lhs) - 1
}
if tv, ok := c.info.Types[node.Lhs[i]]; ok {
typ = tv.Type
break Nodes
}
}
return typeInference{}
case *ast.CallExpr:
// Only consider CallExpr args if position falls between parens.
if node.Lparen <= c.pos && c.pos <= node.Rparen {
if tv, ok := c.info.Types[node.Fun]; ok {
if sig, ok := tv.Type.(*types.Signature); ok {
if sig.Params().Len() == 0 {
return typeInference{}
}
i := indexExprAtPos(c.pos, node.Args)
// Make sure not to run past the end of expected parameters.
if i >= sig.Params().Len() {
i = sig.Params().Len() - 1
}
typ = sig.Params().At(i).Type()
break Nodes
}
}
}
return typeInference{}
case *ast.ReturnStmt:
if sig := c.enclosingFunction; sig != nil {
// Find signature result that corresponds to our return statement.
if resultIdx := indexExprAtPos(c.pos, node.Results); resultIdx < len(node.Results) {
if resultIdx < sig.Results().Len() {
typ = sig.Results().At(resultIdx).Type()
break Nodes
}
}
}
return typeInference{}
case *ast.CaseClause:
if swtch, ok := findSwitchStmt(c.path[i+1:], c.pos, node).(*ast.SwitchStmt); ok {
if tv, ok := c.info.Types[swtch.Tag]; ok {
typ = tv.Type
break Nodes
}
}
return typeInference{}
case *ast.SliceExpr:
// Make sure position falls within the brackets (e.g. "foo[a:<>]").
if node.Lbrack < c.pos && c.pos <= node.Rbrack {
typ = types.Typ[types.Int]
break Nodes
}
return typeInference{}
case *ast.IndexExpr:
// Make sure position falls within the brackets (e.g. "foo[<>]").
if node.Lbrack < c.pos && c.pos <= node.Rbrack {
if tv, ok := c.info.Types[node.X]; ok {
switch t := tv.Type.Underlying().(type) {
case *types.Map:
typ = t.Key()
case *types.Slice, *types.Array:
typ = types.Typ[types.Int]
default:
return typeInference{}
}
break Nodes
}
}
return typeInference{}
case *ast.SendStmt:
// Make sure we are on right side of arrow (e.g. "foo <- <>").
if c.pos > node.Arrow+1 {
if tv, ok := c.info.Types[node.Chan]; ok {
if ch, ok := tv.Type.Underlying().(*types.Chan); ok {
typ = ch.Elem()
break Nodes
}
}
}
return typeInference{}
case *ast.StarExpr:
modifiers = append(modifiers, dereference)
case *ast.UnaryExpr:
switch node.Op {
case token.AND:
modifiers = append(modifiers, reference)
case token.ARROW:
modifiers = append(modifiers, chanRead)
}
default:
if breaksExpectedTypeInference(node) {
return typeInference{}
}
}
}
return typeInference{
objType: typ,
modifiers: modifiers,
}
}
// applyTypeModifiers applies the list of type modifiers to a type.
func (ti typeInference) applyTypeModifiers(typ types.Type) types.Type {
for _, mod := range ti.modifiers {
switch mod {
case dereference:
// For every "*" deref operator, remove a pointer layer from candidate type.
typ = deref(typ)
case reference:
// For every "&" ref operator, add another pointer layer to candidate type.
typ = types.NewPointer(typ)
case chanRead:
// For every "<-" operator, remove a layer of channelness.
if ch, ok := typ.(*types.Chan); ok {
typ = ch.Elem()
}
}
}
return typ
}
// findSwitchStmt returns an *ast.CaseClause's corresponding *ast.SwitchStmt or
// *ast.TypeSwitchStmt. path should start from the case clause's first ancestor.
func findSwitchStmt(path []ast.Node, pos token.Pos, c *ast.CaseClause) ast.Stmt {
// Make sure position falls within a "case <>:" clause.
if exprAtPos(pos, c.List) == nil {
return nil
}
// A case clause is always nested within a block statement in a switch statement.
if len(path) < 2 {
return nil
}
if _, ok := path[0].(*ast.BlockStmt); !ok {
return nil
}
switch s := path[1].(type) {
case *ast.SwitchStmt:
return s
case *ast.TypeSwitchStmt:
return s
default:
return nil
}
}
// breaksExpectedTypeInference reports if an expression node's type is unrelated
// to its child expression node types. For example, "Foo{Bar: x.Baz(<>)}" should
// expect a function argument, not a composite literal value.
func breaksExpectedTypeInference(n ast.Node) bool {
switch n.(type) {
case *ast.FuncLit, *ast.CallExpr, *ast.TypeAssertExpr, *ast.IndexExpr, *ast.SliceExpr, *ast.CompositeLit:
return true
default:
return false
}
}
// expectTypeName returns information about the expected type name at position.
func expectTypeName(c *completer) typeInference {
var wantTypeName bool
Nodes:
for i, p := range c.path {
switch n := p.(type) {
case *ast.FuncDecl:
// Expect type names in a function declaration receiver, params and results.
if r := n.Recv; r != nil && r.Pos() <= c.pos && c.pos <= r.End() {
wantTypeName = true
break Nodes
}
if t := n.Type; t != nil {
if p := t.Params; p != nil && p.Pos() <= c.pos && c.pos <= p.End() {
wantTypeName = true
break Nodes
}
if r := t.Results; r != nil && r.Pos() <= c.pos && c.pos <= r.End() {
wantTypeName = true
break Nodes
}
}
return typeInference{}
case *ast.CaseClause:
// Expect type names in type switch case clauses.
if _, ok := findSwitchStmt(c.path[i+1:], c.pos, n).(*ast.TypeSwitchStmt); ok {
wantTypeName = true
break Nodes
}
return typeInference{}
case *ast.TypeAssertExpr:
// Expect type names in type assert expressions.
if n.Lparen < c.pos && c.pos <= n.Rparen {
wantTypeName = true
break Nodes
}
return typeInference{}
default:
if breaksExpectedTypeInference(p) {
return typeInference{}
}
}
}
return typeInference{
wantTypeName: wantTypeName,
}
}
// matchingType reports whether an object is a good completion candidate
// in the context of the expected type.
func (c *completer) matchingType(cand *candidate) bool {
objType := cand.obj.Type()
// Default to invoking *types.Func candidates. This is so function
// completions in an empty statement (or other cases with no expected type)
// are invoked by default.
cand.expandFuncCall = isFunc(cand.obj)
typeMatches := func(actual types.Type) bool {
// Take into account any type modifiers on the expected type.
actual = c.expectedType.applyTypeModifiers(actual)
if c.expectedType.objType != nil {
// AssignableTo covers the case where the types are equal, but also handles
// cases like assigning a concrete type to an interface type.
return types.AssignableTo(types.Default(actual), types.Default(c.expectedType.objType))
}
return false
}
if typeMatches(objType) {
// If obj's type matches, we don't want to expand to an invocation of obj.
cand.expandFuncCall = false
return true
}
// Try using a function's return type as its type.
if sig, ok := objType.Underlying().(*types.Signature); ok && sig.Results().Len() == 1 {
if typeMatches(sig.Results().At(0).Type()) {
// If obj's return value matches the expected type, we need to invoke obj
// in the completion.
cand.expandFuncCall = true
return true
}
}
return false
}