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go/internal/lsp/source/extract.go
Josh Baum 1c1ec420e5 internal/lsp/source: move initial extract function logic to lsp/command
In the previous implementation, the initial verification in lsp/command
for whether extract function was relavant to the given range did not
contain much of the initial logic for extract function. This meant
that "canExtractFunction" produced many false positives (i.e. the
lightbulb would appear when it should not have in VSCode). This CL
moves more of the verification process from "extractFunction"
(lsp/source) to "canExtractFunction" (lsp/command).

Change-Id: If2683dc9ac3f4bfa8c3444418cf88edd8cbe73e6
Reviewed-on: https://go-review.googlesource.com/c/tools/+/245398
Run-TryBot: Josh Baum <joshbaum@google.com>
TryBot-Result: Gobot Gobot <gobot@golang.org>
Reviewed-by: Rebecca Stambler <rstambler@golang.org>
2020-07-29 16:09:07 +00:00

906 lines
30 KiB
Go

// Copyright 2020 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 (
"bytes"
"fmt"
"go/ast"
"go/format"
"go/parser"
"go/token"
"go/types"
"strings"
"unicode"
"golang.org/x/tools/go/analysis"
"golang.org/x/tools/go/ast/astutil"
"golang.org/x/tools/internal/analysisinternal"
"golang.org/x/tools/internal/span"
)
func extractVariable(fset *token.FileSet, rng span.Range, src []byte, file *ast.File, pkg *types.Package, info *types.Info) (*analysis.SuggestedFix, error) {
expr, path, ok, err := canExtractVariable(rng, file)
if !ok {
return nil, fmt.Errorf("extractVariable: cannot extract %s: %v", fset.Position(rng.Start), err)
}
name := generateAvailableIdentifier(expr.Pos(), file, path, info, "x", 0)
// Create new AST node for extracted code.
var assignment string
switch expr.(type) {
case *ast.BasicLit, *ast.CompositeLit, *ast.IndexExpr,
*ast.SliceExpr, *ast.UnaryExpr, *ast.BinaryExpr, *ast.SelectorExpr: // TODO: stricter rules for selectorExpr.
assignStmt := &ast.AssignStmt{
Lhs: []ast.Expr{ast.NewIdent(name)},
Tok: token.DEFINE,
Rhs: []ast.Expr{expr},
}
var buf bytes.Buffer
if err := format.Node(&buf, fset, assignStmt); err != nil {
return nil, err
}
assignment = buf.String()
case *ast.CallExpr: // TODO: find number of return values and do according actions.
return nil, nil
default:
return nil, nil
}
insertBeforeStmt := analysisinternal.StmtToInsertVarBefore(path)
if insertBeforeStmt == nil {
return nil, nil
}
tok := fset.File(expr.Pos())
if tok == nil {
return nil, nil
}
indent := calculateIndentation(src, tok, insertBeforeStmt)
return &analysis.SuggestedFix{
TextEdits: []analysis.TextEdit{
{
Pos: insertBeforeStmt.Pos(),
End: insertBeforeStmt.End(),
NewText: []byte(assignment + "\n" + indent),
},
{
Pos: rng.Start,
End: rng.Start,
NewText: []byte(name),
},
},
}, nil
}
// canExtractVariable reports whether the code in the given range can be
// extracted to a variable.
func canExtractVariable(rng span.Range, file *ast.File) (ast.Expr, []ast.Node, bool, error) {
if rng.Start == rng.End {
return nil, nil, false, fmt.Errorf("start and end are equal")
}
path, _ := astutil.PathEnclosingInterval(file, rng.Start, rng.End)
if len(path) == 0 {
return nil, nil, false, fmt.Errorf("no path enclosing interval")
}
node := path[0]
if rng.Start != node.Pos() || rng.End != node.End() {
return nil, nil, false, fmt.Errorf("range does not map to an AST node")
}
expr, ok := node.(ast.Expr)
if !ok {
return nil, nil, false, fmt.Errorf("node is not an expression")
}
return expr, path, true, nil
}
// Calculate indentation for insertion.
// When inserting lines of code, we must ensure that the lines have consistent
// formatting (i.e. the proper indentation). To do so, we observe the indentation on the
// line of code on which the insertion occurs.
func calculateIndentation(content []byte, tok *token.File, insertBeforeStmt ast.Node) string {
line := tok.Line(insertBeforeStmt.Pos())
lineOffset := tok.Offset(tok.LineStart(line))
stmtOffset := tok.Offset(insertBeforeStmt.Pos())
return string(content[lineOffset:stmtOffset])
}
// generateAvailableIdentifier adjusts the new function name until there are no collisons in scope.
// Possible collisions include other function and variable names.
func generateAvailableIdentifier(pos token.Pos, file *ast.File, path []ast.Node, info *types.Info, prefix string, idx int) string {
scopes := collectScopes(info, path, pos)
name := prefix + fmt.Sprintf("%d", idx)
for file.Scope.Lookup(name) != nil || !isValidName(name, scopes) {
idx++
name = fmt.Sprintf("%v%d", prefix, idx)
}
return name
}
// isValidName checks for variable collision in scope.
func isValidName(name string, scopes []*types.Scope) bool {
for _, scope := range scopes {
if scope == nil {
continue
}
if scope.Lookup(name) != nil {
return false
}
}
return true
}
// returnVariable keeps track of the information we need to properly introduce a new variable
// that we will return in the extracted function.
type returnVariable struct {
// name is the identifier that is used on the left-hand side of the call to
// the extracted function.
name ast.Expr
// decl is the declaration of the variable. It is used in the type signature of the
// extracted function and for variable declarations.
decl *ast.Field
// zeroVal is the "zero value" of the type of the variable. It is used in a return
// statement in the extracted function.
zeroVal ast.Expr
}
// extractFunction refactors the selected block of code into a new function.
// It also replaces the selected block of code with a call to the extracted
// function. First, we manually adjust the selection range. We remove trailing
// and leading whitespace characters to ensure the range is precisely bounded
// by AST nodes. Next, we determine the variables that will be the paramters
// and return values of the extracted function. Lastly, we construct the call
// of the function and insert this call as well as the extracted function into
// their proper locations.
func extractFunction(fset *token.FileSet, rng span.Range, src []byte, file *ast.File, pkg *types.Package, info *types.Info) (*analysis.SuggestedFix, error) {
tok, path, outer, start, ok, err := canExtractFunction(fset, rng, src, file, info)
if !ok {
return nil, fmt.Errorf("extractFunction: cannot extract %s: %v",
fset.Position(rng.Start), err)
}
fileScope := info.Scopes[file]
if fileScope == nil {
return nil, fmt.Errorf("extractFunction: file scope is empty")
}
pkgScope := fileScope.Parent()
if pkgScope == nil {
return nil, fmt.Errorf("extractFunction: package scope is empty")
}
// TODO: Support non-nested return statements.
// A return statement is non-nested if its parent node is equal to the parent node
// of the first node in the selection. These cases must be handled seperately because
// non-nested return statements are guaranteed to execute. Our control flow does not
// properly consider these situations yet.
var retStmts []*ast.ReturnStmt
var hasNonNestedReturn bool
startParent := findParent(outer, start)
ast.Inspect(outer, func(n ast.Node) bool {
if n == nil {
return true
}
if n.Pos() < rng.Start || n.End() > rng.End {
return n.Pos() <= rng.End
}
ret, ok := n.(*ast.ReturnStmt)
if !ok {
return true
}
if findParent(outer, n) == startParent {
hasNonNestedReturn = true
return false
}
retStmts = append(retStmts, ret)
return true
})
if hasNonNestedReturn {
return nil, fmt.Errorf("extractFunction: selected block contains non-nested return")
}
containsReturnStatement := len(retStmts) > 0
// Now that we have determined the correct range for the selection block,
// we must determine the signature of the extracted function. We will then replace
// the block with an assignment statement that calls the extracted function with
// the appropriate parameters and return values.
free, vars, assigned := collectFreeVars(info, file, fileScope, pkgScope, rng, path[0])
var (
params, returns []ast.Expr // used when calling the extracted function
paramTypes, returnTypes []*ast.Field // used in the signature of the extracted function
uninitialized []types.Object // vars we will need to initialize before the call
)
// Avoid duplicates while traversing vars and uninitialzed.
seenVars := make(map[types.Object]ast.Expr)
seenUninitialized := make(map[types.Object]struct{})
// Each identifier in the selected block must become (1) a parameter to the
// extracted function, (2) a return value of the extracted function, or (3) a local
// variable in the extracted function. Determine the outcome(s) for each variable
// based on whether it is free, altered within the selected block, and used outside
// of the selected block.
for _, obj := range vars {
if _, ok := seenVars[obj]; ok {
continue
}
typ := analysisinternal.TypeExpr(fset, file, pkg, obj.Type())
if typ == nil {
return nil, fmt.Errorf("nil AST expression for type: %v", obj.Name())
}
seenVars[obj] = typ
identifier := ast.NewIdent(obj.Name())
// An identifier must meet two conditions to become a return value of the
// extracted function. (1) it must be used at least once after the
// selection (isUsed), and (2) its value must be initialized or reassigned
// within the selection (isAssigned).
isUsed := objUsed(obj, info, rng.End, obj.Parent().End())
_, isAssigned := assigned[obj]
_, isFree := free[obj]
if isUsed && isAssigned {
returnTypes = append(returnTypes, &ast.Field{Type: typ})
returns = append(returns, identifier)
if !isFree {
uninitialized = append(uninitialized, obj)
}
}
// All free variables are parameters of and passed as arguments to the
// extracted function.
if isFree {
params = append(params, identifier)
paramTypes = append(paramTypes, &ast.Field{
Names: []*ast.Ident{identifier},
Type: typ,
})
}
}
// Find the function literal that encloses the selection. The enclosing function literal
// may not be the enclosing function declaration (i.e. 'outer'). For example, in the
// following block:
//
// func main() {
// ast.Inspect(node, func(n ast.Node) bool {
// v := 1 // this line extracted
// return true
// })
// }
//
// 'outer' is main(). However, the extracted selection most directly belongs to
// the anonymous function literal, the second argument of ast.Inspect(). We use the
// enclosing function literal to determine the proper return types for return statements
// within the selection. We still need the enclosing function declaration because this is
// the top-level declaration. We inspect the top-level declaration to look for variables
// as well as for code replacement.
enclosing := outer.Type
for _, p := range path {
if p == enclosing {
break
}
if fl, ok := p.(*ast.FuncLit); ok {
enclosing = fl.Type
break
}
}
// We put the selection in a constructed file. We can then traverse and edit
// the extracted selection without modifying the original AST.
startOffset := tok.Offset(rng.Start)
endOffset := tok.Offset(rng.End)
selection := src[startOffset:endOffset]
extractedBlock, err := parseBlockStmt(fset, selection)
if err != nil {
return nil, err
}
// We need to account for return statements in the selected block, as they will complicate
// the logical flow of the extracted function. See the following example, where ** denotes
// the range to be extracted.
//
// Before:
//
// func _() int {
// a := 1
// b := 2
// **if a == b {
// return a
// }**
// ...
// }
//
// After:
//
// func _() int {
// a := 1
// b := 2
// cond0, ret0 := x0(a, b)
// if cond0 {
// return ret0
// }
// ...
// }
//
// func x0(a int, b int) (bool, int) {
// if a == b {
// return true, a
// }
// return false, 0
// }
//
// We handle returns by adding an additional boolean return value to the extracted function.
// This bool reports whether the original function would have returned. Because the
// extracted selection contains a return statement, we must also add the types in the
// return signature of the enclosing function to the return signature of the
// extracted function. We then add an extra if statement checking this boolean value
// in the original function. If the condition is met, the original function should
// return a value, mimicking the functionality of the original return statement(s)
// in the selection.
var retVars []*returnVariable
var ifReturn *ast.IfStmt
if containsReturnStatement {
// The selected block contained return statements, so we have to modify the
// signature of the extracted function as described above. Adjust all of
// the return statements in the extracted function to reflect this change in
// signature.
if err := adjustReturnStatements(returnTypes, seenVars, fset, file,
pkg, extractedBlock); err != nil {
return nil, err
}
// Collect the additional return values and types needed to accomodate return
// statements in the selection. Update the type signature of the extracted
// function and construct the if statement that will be inserted in the enclosing
// function.
retVars, ifReturn, err = generateReturnInfo(
enclosing, pkg, path, file, info, fset, rng.Start)
if err != nil {
return nil, err
}
}
// Add a return statement to the end of the new function. This return statement must include
// the values for the types of the original extracted function signature and (if a return
// statement is present in the selection) enclosing function signature.
hasReturnValues := len(returns)+len(retVars) > 0
if hasReturnValues {
extractedBlock.List = append(extractedBlock.List, &ast.ReturnStmt{
Results: append(returns, getZeroVals(retVars)...),
})
}
// Construct the appropriate call to the extracted function.
funName := generateAvailableIdentifier(rng.Start, file, path, info, "fn", 0)
// If none of the variables on the left-hand side of the function call have
// been initialized before the selection, we can use ':=' instead of '='.
sym := token.ASSIGN
if len(uninitialized) == len(returns) {
sym = token.DEFINE
}
extractedFunCall := generateFuncCall(hasReturnValues, params,
append(returns, getNames(retVars)...), funName, sym)
// Build the extracted function.
newFunc := &ast.FuncDecl{
Name: ast.NewIdent(funName),
Type: &ast.FuncType{
Params: &ast.FieldList{List: paramTypes},
Results: &ast.FieldList{List: append(returnTypes, getDecls(retVars)...)},
},
Body: extractedBlock,
}
// Create variable declarations for any identifiers that need to be initialized prior to
// calling the extracted function.
declarations, err := initializeVars(
uninitialized, returns, retVars, seenUninitialized, seenVars)
if err != nil {
return nil, err
}
var declBuf, replaceBuf, newFuncBuf, ifBuf bytes.Buffer
if err := format.Node(&declBuf, fset, declarations); err != nil {
return nil, err
}
if err := format.Node(&replaceBuf, fset, extractedFunCall); err != nil {
return nil, err
}
if ifReturn != nil {
if err := format.Node(&ifBuf, fset, ifReturn); err != nil {
return nil, err
}
}
if err := format.Node(&newFuncBuf, fset, newFunc); err != nil {
return nil, err
}
// We're going to replace the whole enclosing function,
// so preserve the text before and after the selected block.
outerStart := tok.Offset(outer.Pos())
outerEnd := tok.Offset(outer.End())
before := src[outerStart:startOffset]
after := src[endOffset:outerEnd]
newLineIndent := "\n" + calculateIndentation(src, tok, start)
var fullReplacement strings.Builder
fullReplacement.Write(before)
if declBuf.Len() > 0 { // add any initializations, if needed
initializations := strings.ReplaceAll(declBuf.String(), "\n", newLineIndent) +
newLineIndent
fullReplacement.WriteString(initializations)
}
fullReplacement.Write(replaceBuf.Bytes()) // call the extracted function
if ifBuf.Len() > 0 { // add the if statement below the function call, if needed
ifstatement := newLineIndent +
strings.ReplaceAll(ifBuf.String(), "\n", newLineIndent)
fullReplacement.WriteString(ifstatement)
}
fullReplacement.Write(after)
fullReplacement.WriteString("\n\n") // add newlines after the enclosing function
fullReplacement.Write(newFuncBuf.Bytes()) // insert the extracted function
return &analysis.SuggestedFix{
TextEdits: []analysis.TextEdit{
{
Pos: outer.Pos(),
End: outer.End(),
NewText: []byte(fullReplacement.String()),
},
},
}, nil
}
// adjustRangeForWhitespace adjusts the given range to exclude unnecessary leading or
// trailing whitespace characters from selection. In the following example, each line
// of the if statement is indented once. There are also two extra spaces after the
// closing bracket before the line break.
//
// \tif (true) {
// \t _ = 1
// \t} \n
//
// By default, a valid range begins at 'if' and ends at the first whitespace character
// after the '}'. But, users are likely to highlight full lines rather than adjusting
// their cursors for whitespace. To support this use case, we must manually adjust the
// ranges to match the correct AST node. In this particular example, we would adjust
// rng.Start forward by one byte, and rng.End backwards by two bytes.
func adjustRangeForWhitespace(rng span.Range, tok *token.File, content []byte) span.Range {
offset := tok.Offset(rng.Start)
for offset < len(content) {
if !unicode.IsSpace(rune(content[offset])) {
break
}
// Move forwards one byte to find a non-whitespace character.
offset += 1
}
rng.Start = tok.Pos(offset)
offset = tok.Offset(rng.End)
for offset-1 >= 0 {
if !unicode.IsSpace(rune(content[offset-1])) {
break
}
// Move backwards one byte to find a non-whitespace character.
offset -= 1
}
rng.End = tok.Pos(offset)
return rng
}
// findParent finds the parent AST node of the given target node, if the target is a
// descendant of the starting node.
func findParent(start ast.Node, target ast.Node) ast.Node {
var parent ast.Node
analysisinternal.WalkASTWithParent(start, func(n, p ast.Node) bool {
if n == target {
parent = p
return false
}
return true
})
return parent
}
// collectFreeVars maps each identifier in the given range to whether it is "free."
// Given a range, a variable in that range is defined as "free" if it is declared
// outside of the range and neither at the file scope nor package scope. These free
// variables will be used as arguments in the extracted function. It also returns a
// list of identifiers that may need to be returned by the extracted function.
// Some of the code in this function has been adapted from tools/cmd/guru/freevars.go.
func collectFreeVars(info *types.Info, file *ast.File, fileScope *types.Scope,
pkgScope *types.Scope, rng span.Range, node ast.Node) (map[types.Object]struct{}, []types.Object, map[types.Object]struct{}) {
// id returns non-nil if n denotes an object that is referenced by the span
// and defined either within the span or in the lexical environment. The bool
// return value acts as an indicator for where it was defined.
id := func(n *ast.Ident) (types.Object, bool) {
obj := info.Uses[n]
if obj == nil {
return info.Defs[n], false
}
if _, ok := obj.(*types.PkgName); ok {
return nil, false // imported package
}
if !(file.Pos() <= obj.Pos() && obj.Pos() <= file.End()) {
return nil, false // not defined in this file
}
scope := obj.Parent()
if scope == nil {
return nil, false // e.g. interface method, struct field
}
if scope == fileScope || scope == pkgScope {
return nil, false // defined at file or package scope
}
if rng.Start <= obj.Pos() && obj.Pos() <= rng.End {
return obj, false // defined within selection => not free
}
return obj, true
}
// sel returns non-nil if n denotes a selection o.x.y that is referenced by the
// span and defined either within the span or in the lexical environment. The bool
// return value acts as an indicator for where it was defined.
var sel func(n *ast.SelectorExpr) (types.Object, bool)
sel = func(n *ast.SelectorExpr) (types.Object, bool) {
switch x := astutil.Unparen(n.X).(type) {
case *ast.SelectorExpr:
return sel(x)
case *ast.Ident:
return id(x)
}
return nil, false
}
free := make(map[types.Object]struct{})
var vars []types.Object
ast.Inspect(node, func(n ast.Node) bool {
if n == nil {
return true
}
if rng.Start <= n.Pos() && n.End() <= rng.End {
var obj types.Object
var isFree, prune bool
switch n := n.(type) {
case *ast.Ident:
obj, isFree = id(n)
case *ast.SelectorExpr:
obj, isFree = sel(n)
prune = true
}
if obj != nil && obj.Name() != "_" {
if isFree {
free[obj] = struct{}{}
}
vars = append(vars, obj)
if prune {
return false
}
}
}
return n.Pos() <= rng.End
})
// Find identifiers that are initialized or whose values are altered at some
// point in the selected block. For example, in a selected block from lines 2-4,
// variables x, y, and z are included in assigned. However, in a selected block
// from lines 3-4, only variables y and z are included in assigned.
//
// 1: var a int
// 2: var x int
// 3: y := 3
// 4: z := x + a
//
assigned := make(map[types.Object]struct{})
ast.Inspect(node, func(n ast.Node) bool {
if n == nil {
return true
}
if n.Pos() < rng.Start || n.End() > rng.End {
return n.Pos() <= rng.End
}
switch n := n.(type) {
case *ast.AssignStmt:
for _, assignment := range n.Lhs {
if assignment, ok := assignment.(*ast.Ident); ok {
obj, _ := id(assignment)
if obj == nil {
continue
}
assigned[obj] = struct{}{}
}
}
return false
case *ast.DeclStmt:
gen, ok := n.Decl.(*ast.GenDecl)
if !ok {
return true
}
for _, spec := range gen.Specs {
vSpecs, ok := spec.(*ast.ValueSpec)
if !ok {
continue
}
for _, vSpec := range vSpecs.Names {
obj, _ := id(vSpec)
if obj == nil {
continue
}
assigned[obj] = struct{}{}
}
}
return false
}
return true
})
return free, vars, assigned
}
// canExtractFunction reports whether the code in the given range can be extracted to a function.
func canExtractFunction(fset *token.FileSet, rng span.Range, src []byte, file *ast.File, info *types.Info) (*token.File, []ast.Node, *ast.FuncDecl, ast.Node, bool, error) {
if rng.Start == rng.End {
return nil, nil, nil, nil, false, fmt.Errorf("start and end are equal")
}
tok := fset.File(file.Pos())
if tok == nil {
return nil, nil, nil, nil, false,
fmt.Errorf("no file for pos %v", fset.Position(file.Pos()))
}
rng = adjustRangeForWhitespace(rng, tok, src)
path, _ := astutil.PathEnclosingInterval(file, rng.Start, rng.End)
if len(path) == 0 {
return nil, nil, nil, nil, false, fmt.Errorf("no path enclosing interval")
}
// Node that encloses the selection must be a statement.
// TODO: Support function extraction for an expression.
_, ok := path[0].(ast.Stmt)
if !ok {
return nil, nil, nil, nil, false, fmt.Errorf("node is not a statement")
}
// Find the function declaration that encloses the selection.
var outer *ast.FuncDecl
for _, p := range path {
if p, ok := p.(*ast.FuncDecl); ok {
outer = p
break
}
}
if outer == nil {
return nil, nil, nil, nil, false, fmt.Errorf("no enclosing function")
}
// Find the nodes at the start and end of the selection.
var start, end ast.Node
ast.Inspect(outer, func(n ast.Node) bool {
if n == nil {
return true
}
// Do not override 'start' with a node that begins at the same location but is
// nested further from 'outer'.
if start == nil && n.Pos() == rng.Start && n.End() <= rng.End {
start = n
}
if end == nil && n.End() == rng.End && n.Pos() >= rng.Start {
end = n
}
return n.Pos() <= rng.End
})
if start == nil || end == nil {
return nil, nil, nil, nil, false, fmt.Errorf("range does not map to AST nodes")
}
return tok, path, outer, start, true, nil
}
// objUsed checks if the object is used between the given positions.
func objUsed(obj types.Object, info *types.Info, endSel token.Pos, endScope token.Pos) bool {
for id, ob := range info.Uses {
if obj == ob && endSel < id.Pos() && id.End() <= endScope {
return true
}
}
return false
}
// parseExtraction generates an AST file from the given text. We then return the portion of the
// file that represents the text.
func parseBlockStmt(fset *token.FileSet, src []byte) (*ast.BlockStmt, error) {
text := "package main\nfunc _() { " + string(src) + " }"
extract, err := parser.ParseFile(fset, "", text, 0)
if err != nil {
return nil, err
}
if len(extract.Decls) == 0 {
return nil, fmt.Errorf("parsed file does not contain any declarations")
}
decl, ok := extract.Decls[0].(*ast.FuncDecl)
if !ok {
return nil, fmt.Errorf("parsed file does not contain expected function declaration")
}
if decl.Body == nil {
return nil, fmt.Errorf("extracted function has no body")
}
return decl.Body, nil
}
// generateReturnInfo generates the information we need to adjust the return statements and
// signature of the extracted function. We prepare names, signatures, and "zero values" that
// represent the new variables. We also use this information to construct the if statement that
// is inserted below the call to the extracted function.
func generateReturnInfo(enclosing *ast.FuncType, pkg *types.Package, path []ast.Node, file *ast.File, info *types.Info, fset *token.FileSet, pos token.Pos) ([]*returnVariable, *ast.IfStmt, error) {
// Generate information for the added bool value.
cond := &ast.Ident{Name: generateAvailableIdentifier(pos, file, path, info, "cond", 0)}
retVars := []*returnVariable{
{
name: cond,
decl: &ast.Field{Type: ast.NewIdent("bool")},
zeroVal: ast.NewIdent("false"),
},
}
// Generate information for the values in the return signature of the enclosing function.
if enclosing.Results != nil {
for i, field := range enclosing.Results.List {
typ := info.TypeOf(field.Type)
if typ == nil {
return nil, nil, fmt.Errorf(
"failed type conversion, AST expression: %T", field.Type)
}
expr := analysisinternal.TypeExpr(fset, file, pkg, typ)
if expr == nil {
return nil, nil, fmt.Errorf("nil AST expression")
}
retVars = append(retVars, &returnVariable{
name: ast.NewIdent(generateAvailableIdentifier(pos, file,
path, info, "ret", i)),
decl: &ast.Field{Type: expr},
zeroVal: analysisinternal.ZeroValue(
fset, file, pkg, typ),
})
}
}
// Create the return statement for the enclosing function. We must exclude the variable
// for the condition of the if statement (cond) from the return statement.
ifReturn := &ast.IfStmt{
Cond: cond,
Body: &ast.BlockStmt{
List: []ast.Stmt{&ast.ReturnStmt{Results: getNames(retVars)[1:]}},
},
}
return retVars, ifReturn, nil
}
// adjustReturnStatements adds "zero values" of the given types to each return statement
// in the given AST node.
func adjustReturnStatements(returnTypes []*ast.Field, seenVars map[types.Object]ast.Expr, fset *token.FileSet, file *ast.File, pkg *types.Package, extractedBlock *ast.BlockStmt) error {
var zeroVals []ast.Expr
// Create "zero values" for each type.
for _, returnType := range returnTypes {
var val ast.Expr
for obj, typ := range seenVars {
if typ != returnType.Type {
continue
}
val = analysisinternal.ZeroValue(fset, file, pkg, obj.Type())
break
}
if val == nil {
return fmt.Errorf(
"could not find matching AST expression for %T", returnType.Type)
}
zeroVals = append(zeroVals, val)
}
// Add "zero values" to each return statement.
// The bool reports whether the enclosing function should return after calling the
// extracted function. We set the bool to 'true' because, if these return statements
// execute, the extracted function terminates early, and the enclosing function must
// return as well.
zeroVals = append(zeroVals, ast.NewIdent("true"))
ast.Inspect(extractedBlock, func(n ast.Node) bool {
if n == nil {
return true
}
if n, ok := n.(*ast.ReturnStmt); ok {
n.Results = append(zeroVals, n.Results...)
return true
}
return true
})
return nil
}
// generateFuncCall constructs a call expression for the extracted function, described by the
// given parameters and return variables.
func generateFuncCall(hasReturnVals bool, params, returns []ast.Expr, name string, token token.Token) ast.Node {
var replace ast.Node
if hasReturnVals {
callExpr := &ast.CallExpr{
Fun: ast.NewIdent(name),
Args: params,
}
replace = &ast.AssignStmt{
Lhs: returns,
Tok: token,
Rhs: []ast.Expr{callExpr},
}
} else {
replace = &ast.CallExpr{
Fun: ast.NewIdent(name),
Args: params,
}
}
return replace
}
// initializeVars creates variable declarations, if needed.
// Our preference is to replace the selected block with an "x, y, z := fn()" style
// assignment statement. We can use this style when none of the variables in the
// extracted function's return statement have already be initialized outside of the
// selected block. However, for example, if z is already defined elsewhere, we
// replace the selected block with:
//
// var x int
// var y string
// x, y, z = fn()
func initializeVars(uninitialized []types.Object, returns []ast.Expr, retVars []*returnVariable, seenUninitialized map[types.Object]struct{}, seenVars map[types.Object]ast.Expr) ([]ast.Stmt, error) {
var declarations []ast.Stmt
// We do not manually initialize variables if every return value is unitialized.
// We can use := to initialize the variables in this situation.
if len(uninitialized) == len(returns) {
return declarations, nil
}
for _, obj := range uninitialized {
if _, ok := seenUninitialized[obj]; ok {
continue
}
seenUninitialized[obj] = struct{}{}
valSpec := &ast.ValueSpec{
Names: []*ast.Ident{ast.NewIdent(obj.Name())},
Type: seenVars[obj],
}
genDecl := &ast.GenDecl{
Tok: token.VAR,
Specs: []ast.Spec{valSpec},
}
declarations = append(declarations, &ast.DeclStmt{Decl: genDecl})
}
// Each variable added from a return statement in the selection
// must be initialized.
for i, retVar := range retVars {
n := retVar.name.(*ast.Ident)
valSpec := &ast.ValueSpec{
Names: []*ast.Ident{n},
Type: retVars[i].decl.Type,
}
genDecl := &ast.GenDecl{
Tok: token.VAR,
Specs: []ast.Spec{valSpec},
}
declarations = append(declarations, &ast.DeclStmt{Decl: genDecl})
}
return declarations, nil
}
// getNames returns the names from the given list of returnVariable.
func getNames(retVars []*returnVariable) []ast.Expr {
var names []ast.Expr
for _, retVar := range retVars {
names = append(names, retVar.name)
}
return names
}
// getZeroVals returns the "zero values" from the given list of returnVariable.
func getZeroVals(retVars []*returnVariable) []ast.Expr {
var zvs []ast.Expr
for _, retVar := range retVars {
zvs = append(zvs, retVar.zeroVal)
}
return zvs
}
// getDecls returns the declarations from the given list of returnVariable.
func getDecls(retVars []*returnVariable) []*ast.Field {
var decls []*ast.Field
for _, retVar := range retVars {
decls = append(decls, retVar.decl)
}
return decls
}