// (c) Copyright 2016 Hewlett Packard Enterprise Development LP // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package gas import ( "fmt" "go/ast" "go/token" "go/types" "reflect" "regexp" "strconv" "strings" ) // helpfull "canned" matching routines ---------------------------------------- func selectName(n ast.Node, s reflect.Type) (string, bool) { t := reflect.TypeOf(&ast.SelectorExpr{}) if node, ok := SimpleSelect(n, s, t).(*ast.SelectorExpr); ok { t = reflect.TypeOf(&ast.Ident{}) if ident, ok := SimpleSelect(node.X, t).(*ast.Ident); ok { return strings.Join([]string{ident.Name, node.Sel.Name}, "."), ok } } return "", false } // MatchCall will match an ast.CallNode if its method name obays the given regex. func MatchCall(n ast.Node, r *regexp.Regexp) *ast.CallExpr { t := reflect.TypeOf(&ast.CallExpr{}) if name, ok := selectName(n, t); ok && r.MatchString(name) { return n.(*ast.CallExpr) } return nil } // MatchCallByPackage ensures that the specified package is imported, // adjusts the name for any aliases and ignores cases that are // initialization only imports. // // Usage: // node, matched := MatchCallByPackage(n, ctx, "math/rand", "Read") // func MatchCallByPackage(n ast.Node, c *Context, pkg string, names ...string) (*ast.CallExpr, bool) { importedName, found := GetImportedName(pkg, c) if !found { return nil, false } if callExpr, ok := n.(*ast.CallExpr); ok { packageName, callName, err := GetCallInfo(callExpr, c) if err != nil { return nil, false } if packageName == importedName { for _, name := range names { if callName == name { return callExpr, true } } } } return nil, false } // MatchCallByType ensures that the node is a call expression to a // specific object type. // // Usage: // node, matched := MatchCallByType(n, ctx, "bytes.Buffer", "WriteTo", "Write") // func MatchCallByType(n ast.Node, ctx *Context, requiredType string, calls ...string) (*ast.CallExpr, bool) { if callExpr, ok := n.(*ast.CallExpr); ok { typeName, callName, err := GetCallInfo(callExpr, ctx) if err != nil { return nil, false } if typeName == requiredType { for _, call := range calls { if call == callName { return callExpr, true } } } } return nil, false } // MatchCompLit will match an ast.CompositeLit if its string value obays the given regex. func MatchCompLit(n ast.Node, r *regexp.Regexp) *ast.CompositeLit { t := reflect.TypeOf(&ast.CompositeLit{}) if name, ok := selectName(n, t); ok && r.MatchString(name) { return n.(*ast.CompositeLit) } return nil } // GetInt will read and return an integer value from an ast.BasicLit func GetInt(n ast.Node) (int64, error) { if node, ok := n.(*ast.BasicLit); ok && node.Kind == token.INT { return strconv.ParseInt(node.Value, 0, 64) } return 0, fmt.Errorf("Unexpected AST node type: %T", n) } // GetInt will read and return a float value from an ast.BasicLit func GetFloat(n ast.Node) (float64, error) { if node, ok := n.(*ast.BasicLit); ok && node.Kind == token.FLOAT { return strconv.ParseFloat(node.Value, 64) } return 0.0, fmt.Errorf("Unexpected AST node type: %T", n) } // GetInt will read and return a char value from an ast.BasicLit func GetChar(n ast.Node) (byte, error) { if node, ok := n.(*ast.BasicLit); ok && node.Kind == token.CHAR { return node.Value[0], nil } return 0, fmt.Errorf("Unexpected AST node type: %T", n) } // GetInt will read and return a string value from an ast.BasicLit func GetString(n ast.Node) (string, error) { if node, ok := n.(*ast.BasicLit); ok && node.Kind == token.STRING { return strconv.Unquote(node.Value) } return "", fmt.Errorf("Unexpected AST node type: %T", n) } // GetCallObject returns the object and call expression and associated // object for a given AST node. nil, nil will be returned if the // object cannot be resolved. func GetCallObject(n ast.Node, ctx *Context) (*ast.CallExpr, types.Object) { switch node := n.(type) { case *ast.CallExpr: switch fn := node.Fun.(type) { case *ast.Ident: return node, ctx.Info.Uses[fn] case *ast.SelectorExpr: return node, ctx.Info.Uses[fn.Sel] } } return nil, nil } // GetCallInfo returns the package or type and name associated with a // call expression. func GetCallInfo(n ast.Node, ctx *Context) (string, string, error) { switch node := n.(type) { case *ast.CallExpr: switch fn := node.Fun.(type) { case *ast.SelectorExpr: switch expr := fn.X.(type) { case *ast.Ident: if expr.Obj != nil && expr.Obj.Kind == ast.Var { t := ctx.Info.TypeOf(expr) if t != nil { return t.String(), fn.Sel.Name, nil } else { return "undefined", fn.Sel.Name, fmt.Errorf("missing type info") } } else { return expr.Name, fn.Sel.Name, nil } } case *ast.Ident: return ctx.Pkg.Name(), fn.Name, nil } } return "", "", fmt.Errorf("unable to determine call info") } // GetImportedName returns the name used for the package within the // code. It will resolve aliases and ignores initalization only imports. func GetImportedName(path string, ctx *Context) (string, bool) { importName, imported := ctx.Imports.Imported[path] if !imported { return "", false } if _, initonly := ctx.Imports.InitOnly[path]; initonly { return "", false } if alias, ok := ctx.Imports.Aliased[path]; ok { importName = alias } return importName, true } // GetImportPath resolves the full import path of an identifer based on // the imports in the current context. func GetImportPath(name string, ctx *Context) (string, bool) { for path, _ := range ctx.Imports.Imported { if imported, ok := GetImportedName(path, ctx); ok && imported == name { return path, true } } return "", false } // GetLocation returns the filename and line number of an ast.Node func GetLocation(n ast.Node, ctx *Context) (string, int) { fobj := ctx.FileSet.File(n.Pos()) return fobj.Name(), fobj.Line(n.Pos()) }