| // 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, _ *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) |
| } |
| |
| // Create new AST node for extracted code. |
| var lhsNames []string |
| switch expr := expr.(type) { |
| // TODO: stricter rules for selectorExpr. |
| case *ast.BasicLit, *ast.CompositeLit, *ast.IndexExpr, *ast.SliceExpr, |
| *ast.UnaryExpr, *ast.BinaryExpr, *ast.SelectorExpr: |
| lhsNames = append(lhsNames, generateAvailableIdentifier(expr.Pos(), file, path, info, "x", 0)) |
| case *ast.CallExpr: |
| tup, ok := info.TypeOf(expr).(*types.Tuple) |
| if !ok { |
| // If the call expression only has one return value, we can treat it the |
| // same as our standard extract variable case. |
| lhsNames = append(lhsNames, |
| generateAvailableIdentifier(expr.Pos(), file, path, info, "x", 0)) |
| break |
| } |
| for i := 0; i < tup.Len(); i++ { |
| // Generate a unique variable for each return value. |
| lhsNames = append(lhsNames, |
| generateAvailableIdentifier(expr.Pos(), file, path, info, "x", i)) |
| } |
| default: |
| return nil, fmt.Errorf("cannot extract %T", expr) |
| } |
| |
| insertBeforeStmt := analysisinternal.StmtToInsertVarBefore(path) |
| if insertBeforeStmt == nil { |
| return nil, fmt.Errorf("cannot find location to insert extraction") |
| } |
| tok := fset.File(expr.Pos()) |
| if tok == nil { |
| return nil, fmt.Errorf("no file for pos %v", fset.Position(file.Pos())) |
| } |
| newLineIndent := "\n" + calculateIndentation(src, tok, insertBeforeStmt) |
| |
| lhs := strings.Join(lhsNames, ", ") |
| assignStmt := &ast.AssignStmt{ |
| Lhs: []ast.Expr{ast.NewIdent(lhs)}, |
| Tok: token.DEFINE, |
| Rhs: []ast.Expr{expr}, |
| } |
| var buf bytes.Buffer |
| if err := format.Node(&buf, fset, assignStmt); err != nil { |
| return nil, err |
| } |
| assignment := strings.ReplaceAll(buf.String(), "\n", newLineIndent) + newLineIndent |
| |
| return &analysis.SuggestedFix{ |
| TextEdits: []analysis.TextEdit{ |
| { |
| Pos: rng.Start, |
| End: rng.End, |
| NewText: []byte(lhs), |
| }, |
| { |
| Pos: insertBeforeStmt.Pos(), |
| End: insertBeforeStmt.Pos(), |
| NewText: []byte(assignment), |
| }, |
| }, |
| }, 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") |
| } |
| for _, n := range path { |
| if _, ok := n.(*ast.ImportSpec); ok { |
| return nil, nil, false, fmt.Errorf("cannot extract variable in an import block") |
| } |
| } |
| 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") |
| } |
| switch expr.(type) { |
| case *ast.BasicLit, *ast.CompositeLit, *ast.IndexExpr, *ast.CallExpr, |
| *ast.SliceExpr, *ast.UnaryExpr, *ast.BinaryExpr, *ast.SelectorExpr: |
| return expr, path, true, nil |
| } |
| return nil, nil, false, fmt.Errorf("cannot extract an %T to a variable", expr) |
| } |
| |
| // 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 parameters |
| // 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) { |
| p, ok, err := canExtractFunction(fset, rng, src, file, info) |
| if !ok { |
| return nil, fmt.Errorf("extractFunction: cannot extract %s: %v", |
| fset.Position(rng.Start), err) |
| } |
| tok, path, rng, outer, start := p.tok, p.path, p.rng, p.outer, p.start |
| 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 separately 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 false |
| } |
| 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 false |
| }) |
| 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. |
| variables, err := collectFreeVars(info, file, fileScope, pkgScope, rng, path[0]) |
| if err != nil { |
| return nil, err |
| } |
| |
| 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{}) |
| |
| // Some variables on the left-hand side of our assignment statement may be free. If our |
| // selection begins in the same scope in which the free variable is defined, we can |
| // redefine it in our assignment statement. See the following example, where 'b' and |
| // 'err' (both free variables) can be redefined in the second funcCall() while maintaining |
| // correctness. |
| // |
| // |
| // Not Redefined: |
| // |
| // a, err := funcCall() |
| // var b int |
| // b, err = funcCall() |
| // |
| // Redefined: |
| // |
| // a, err := funcCall() |
| // b, err := funcCall() |
| // |
| // We track the number of free variables that can be redefined to maintain our preference |
| // of using "x, y, z := fn()" style assignment statements. |
| var canRedefineCount int |
| |
| // 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 _, v := range variables { |
| if _, ok := seenVars[v.obj]; ok { |
| continue |
| } |
| typ := analysisinternal.TypeExpr(fset, file, pkg, v.obj.Type()) |
| if typ == nil { |
| return nil, fmt.Errorf("nil AST expression for type: %v", v.obj.Name()) |
| } |
| seenVars[v.obj] = typ |
| identifier := ast.NewIdent(v.obj.Name()) |
| // An identifier must meet three conditions to become a return value of the |
| // extracted function. (1) its value must be defined or reassigned within |
| // the selection (isAssigned), (2) it must be used at least once after the |
| // selection (isUsed), and (3) its first use after the selection |
| // cannot be its own reassignment or redefinition (objOverriden). |
| if v.obj.Parent() == nil { |
| return nil, fmt.Errorf("parent nil") |
| } |
| isUsed, firstUseAfter := objUsed(info, span.NewRange(fset, rng.End, v.obj.Parent().End()), v.obj) |
| if v.assigned && isUsed && !varOverridden(info, firstUseAfter, v.obj, v.free, outer) { |
| returnTypes = append(returnTypes, &ast.Field{Type: typ}) |
| returns = append(returns, identifier) |
| if !v.free { |
| uninitialized = append(uninitialized, v.obj) |
| } else if v.obj.Parent().Pos() == startParent.Pos() { |
| canRedefineCount++ |
| } |
| } |
| // An identifier must meet two conditions to become a parameter of the |
| // extracted function. (1) it must be free (isFree), and (2) its first |
| // use within the selection cannot be its own definition (isDefined). |
| if v.free && !v.defined { |
| 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 accommodate 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. |
| // We must meet two conditions to use ":=" instead of '='. (1) there must be at least |
| // one variable on the lhs that is uninitailized (non-free) prior to the assignment. |
| // (2) all of the initialized (free) variables on the lhs must be able to be redefined. |
| sym := token.ASSIGN |
| canDefineCount := len(uninitialized) + canRedefineCount |
| canDefine := len(uninitialized)+len(retVars) > 0 && canDefineCount == len(returns) |
| if canDefine { |
| sym = token.DEFINE |
| } |
| funName := generateAvailableIdentifier(rng.Start, file, path, info, "fn", 0) |
| 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. We do not manually initialize variables if every return |
| // value is unitialized. We can use := to initialize the variables in this situation. |
| var declarations []ast.Stmt |
| if canDefineCount != len(returns) { |
| declarations = initializeVars(uninitialized, retVars, seenUninitialized, seenVars) |
| } |
| |
| 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) |
| |
| // Move backwards to find a non-whitespace character. |
| offset = tok.Offset(rng.End) |
| for o := offset - 1; 0 <= o && o < len(content); o-- { |
| if !unicode.IsSpace(rune(content[o])) { |
| break |
| } |
| offset = o |
| } |
| 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 |
| } |
| |
| // variable describes the status of a variable within a selection. |
| type variable struct { |
| obj types.Object |
| |
| // free reports whether the variable is a free variable, meaning it should |
| // be a parameter to the extracted function. |
| free bool |
| |
| // assigned reports whether the variable is assigned to in the selection. |
| assigned bool |
| |
| // defined reports whether the variable is defined in the selection. |
| defined bool |
| } |
| |
| // 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, pkgScope *types.Scope, rng span.Range, node ast.Node) ([]*variable, error) { |
| // 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 obj.Name() == "_" { |
| return nil, false // exclude objects denoting '_' |
| } |
| 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 |
| } |
| seen := make(map[types.Object]*variable) |
| firstUseIn := make(map[types.Object]token.Pos) |
| var vars []types.Object |
| ast.Inspect(node, func(n ast.Node) bool { |
| if n == nil { |
| return false |
| } |
| 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 { |
| seen[obj] = &variable{ |
| obj: obj, |
| free: isFree, |
| } |
| vars = append(vars, obj) |
| // Find the first time that the object is used in the selection. |
| first, ok := firstUseIn[obj] |
| if !ok || n.Pos() < first { |
| firstUseIn[obj] = n.Pos() |
| } |
| 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 |
| // |
| ast.Inspect(node, func(n ast.Node) bool { |
| if n == nil { |
| return false |
| } |
| 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 { |
| lhs, ok := assignment.(*ast.Ident) |
| if !ok { |
| continue |
| } |
| obj, _ := id(lhs) |
| if obj == nil { |
| continue |
| } |
| if _, ok := seen[obj]; !ok { |
| continue |
| } |
| seen[obj].assigned = true |
| if n.Tok != token.DEFINE { |
| continue |
| } |
| // Find identifiers that are defined prior to being used |
| // elsewhere in the selection. |
| // TODO: Include identifiers that are assigned prior to being |
| // used elsewhere in the selection. Then, change the assignment |
| // to a definition in the extracted function. |
| if firstUseIn[obj] != lhs.Pos() { |
| continue |
| } |
| // Ensure that the object is not used in its own re-definition. |
| // For example: |
| // var f float64 |
| // f, e := math.Frexp(f) |
| for _, expr := range n.Rhs { |
| if referencesObj(info, expr, obj) { |
| continue |
| } |
| if _, ok := seen[obj]; !ok { |
| continue |
| } |
| seen[obj].defined = true |
| break |
| } |
| } |
| return false |
| case *ast.DeclStmt: |
| gen, ok := n.Decl.(*ast.GenDecl) |
| if !ok { |
| return false |
| } |
| 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 |
| } |
| if _, ok := seen[obj]; !ok { |
| continue |
| } |
| seen[obj].assigned = true |
| } |
| } |
| return false |
| case *ast.IncDecStmt: |
| if ident, ok := n.X.(*ast.Ident); !ok { |
| return false |
| } else if obj, _ := id(ident); obj == nil { |
| return false |
| } else { |
| if _, ok := seen[obj]; !ok { |
| return false |
| } |
| seen[obj].assigned = true |
| } |
| } |
| return true |
| }) |
| var variables []*variable |
| for _, obj := range vars { |
| v, ok := seen[obj] |
| if !ok { |
| return nil, fmt.Errorf("no seen types.Object for %v", obj) |
| } |
| variables = append(variables, v) |
| } |
| return variables, nil |
| } |
| |
| // referencesObj checks whether the given object appears in the given expression. |
| func referencesObj(info *types.Info, expr ast.Expr, obj types.Object) bool { |
| var hasObj bool |
| ast.Inspect(expr, func(n ast.Node) bool { |
| if n == nil { |
| return false |
| } |
| ident, ok := n.(*ast.Ident) |
| if !ok { |
| return true |
| } |
| objUse := info.Uses[ident] |
| if obj == objUse { |
| hasObj = true |
| return false |
| } |
| return false |
| }) |
| return hasObj |
| } |
| |
| type fnExtractParams struct { |
| tok *token.File |
| path []ast.Node |
| rng span.Range |
| outer *ast.FuncDecl |
| start ast.Node |
| } |
| |
| // 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, _ *types.Info) (*fnExtractParams, bool, error) { |
| if rng.Start == rng.End { |
| return nil, false, fmt.Errorf("start and end are equal") |
| } |
| tok := fset.File(file.Pos()) |
| if tok == nil { |
| return 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, 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, 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, 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 false |
| } |
| // 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, false, fmt.Errorf("range does not map to AST nodes") |
| } |
| return &fnExtractParams{ |
| tok: tok, |
| path: path, |
| rng: rng, |
| outer: outer, |
| start: start, |
| }, true, nil |
| } |
| |
| // objUsed checks if the object is used within the range. It returns the first |
| // occurrence of the object in the range, if it exists. |
| func objUsed(info *types.Info, rng span.Range, obj types.Object) (bool, *ast.Ident) { |
| var firstUse *ast.Ident |
| for id, objUse := range info.Uses { |
| if obj != objUse { |
| continue |
| } |
| if id.Pos() < rng.Start || id.End() > rng.End { |
| continue |
| } |
| if firstUse == nil || id.Pos() < firstUse.Pos() { |
| firstUse = id |
| } |
| } |
| return firstUse != nil, firstUse |
| } |
| |
| // varOverridden traverses the given AST node until we find the given identifier. Then, we |
| // examine the occurrence of the given identifier and check for (1) whether the identifier |
| // is being redefined. If the identifier is free, we also check for (2) whether the identifier |
| // is being reassigned. We will not include an identifier in the return statement of the |
| // extracted function if it meets one of the above conditions. |
| func varOverridden(info *types.Info, firstUse *ast.Ident, obj types.Object, isFree bool, node ast.Node) bool { |
| var isOverriden bool |
| ast.Inspect(node, func(n ast.Node) bool { |
| if n == nil { |
| return false |
| } |
| assignment, ok := n.(*ast.AssignStmt) |
| if !ok { |
| return true |
| } |
| // A free variable is initialized prior to the selection. We can always reassign |
| // this variable after the selection because it has already been defined. |
| // Conversely, a non-free variable is initialized within the selection. Thus, we |
| // cannot reassign this variable after the selection unless it is initialized and |
| // returned by the extracted function. |
| if !isFree && assignment.Tok == token.ASSIGN { |
| return false |
| } |
| for _, assigned := range assignment.Lhs { |
| ident, ok := assigned.(*ast.Ident) |
| // Check if we found the first use of the identifier. |
| if !ok || ident != firstUse { |
| continue |
| } |
| objUse := info.Uses[ident] |
| if objUse == nil || objUse != obj { |
| continue |
| } |
| // Ensure that the object is not used in its own definition. |
| // For example: |
| // var f float64 |
| // f, e := math.Frexp(f) |
| for _, expr := range assignment.Rhs { |
| if referencesObj(info, expr, obj) { |
| return false |
| } |
| } |
| isOverriden = true |
| return false |
| } |
| return false |
| }) |
| return isOverriden |
| } |
| |
| // 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 false |
| } |
| if n, ok := n.(*ast.ReturnStmt); ok { |
| n.Results = append(zeroVals, n.Results...) |
| return false |
| } |
| 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 all of the variables in the |
| // extracted function's return statement are either not defined prior to the extracted block |
| // or can be safely redefined. However, for example, if z is already defined |
| // in a different scope, we replace the selected block with: |
| // |
| // var x int |
| // var y string |
| // x, y, z = fn() |
| func initializeVars(uninitialized []types.Object, retVars []*returnVariable, seenUninitialized map[types.Object]struct{}, seenVars map[types.Object]ast.Expr) []ast.Stmt { |
| var declarations []ast.Stmt |
| 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 |
| } |
| |
| // 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 |
| } |