// Package parser implements a parser and parse tree dumper for Dockerfiles. package parser import ( "bufio" "bytes" "fmt" "io" "regexp" "strconv" "strings" "unicode" "github.com/docker/docker/builder/dockerfile/command" "github.com/pkg/errors" ) // Node is a structure used to represent a parse tree. // // In the node there are three fields, Value, Next, and Children. Value is the // current token's string value. Next is always the next non-child token, and // children contains all the children. Here's an example: // // (value next (child child-next child-next-next) next-next) // // This data structure is frankly pretty lousy for handling complex languages, // but lucky for us the Dockerfile isn't very complicated. This structure // works a little more effectively than a "proper" parse tree for our needs. // type Node struct { Value string // actual content Next *Node // the next item in the current sexp Children []*Node // the children of this sexp Attributes map[string]bool // special attributes for this node Original string // original line used before parsing Flags []string // only top Node should have this set StartLine int // the line in the original dockerfile where the node begins endLine int // the line in the original dockerfile where the node ends } // Dump dumps the AST defined by `node` as a list of sexps. // Returns a string suitable for printing. func (node *Node) Dump() string { str := "" str += node.Value if len(node.Flags) > 0 { str += fmt.Sprintf(" %q", node.Flags) } for _, n := range node.Children { str += "(" + n.Dump() + ")\n" } for n := node.Next; n != nil; n = n.Next { if len(n.Children) > 0 { str += " " + n.Dump() } else { str += " " + strconv.Quote(n.Value) } } return strings.TrimSpace(str) } func (node *Node) lines(start, end int) { node.StartLine = start node.endLine = end } // AddChild adds a new child node, and updates line information func (node *Node) AddChild(child *Node, startLine, endLine int) { child.lines(startLine, endLine) if node.StartLine < 0 { node.StartLine = startLine } node.endLine = endLine node.Children = append(node.Children, child) } var ( dispatch map[string]func(string, *Directive) (*Node, map[string]bool, error) tokenWhitespace = regexp.MustCompile(`[\t\v\f\r ]+`) tokenEscapeCommand = regexp.MustCompile(`^#[ \t]*escape[ \t]*=[ \t]*(?P.).*$`) tokenComment = regexp.MustCompile(`^#.*$`) ) // DefaultEscapeToken is the default escape token const DefaultEscapeToken = '\\' // Directive is the structure used during a build run to hold the state of // parsing directives. type Directive struct { escapeToken rune // Current escape token lineContinuationRegex *regexp.Regexp // Current line continuation regex processingComplete bool // Whether we are done looking for directives escapeSeen bool // Whether the escape directive has been seen } // setEscapeToken sets the default token for escaping characters in a Dockerfile. func (d *Directive) setEscapeToken(s string) error { if s != "`" && s != "\\" { return fmt.Errorf("invalid ESCAPE '%s'. Must be ` or \\", s) } d.escapeToken = rune(s[0]) d.lineContinuationRegex = regexp.MustCompile(`\` + s + `[ \t]*$`) return nil } // possibleParserDirective looks for one or more parser directives '# escapeToken=' and // '# platform='. Parser directives must precede any builder instruction // or other comments, and cannot be repeated. func (d *Directive) possibleParserDirective(line string) error { if d.processingComplete { return nil } tecMatch := tokenEscapeCommand.FindStringSubmatch(strings.ToLower(line)) if len(tecMatch) != 0 { for i, n := range tokenEscapeCommand.SubexpNames() { if n == "escapechar" { if d.escapeSeen == true { return errors.New("only one escape parser directive can be used") } d.escapeSeen = true return d.setEscapeToken(tecMatch[i]) } } } d.processingComplete = true return nil } // NewDefaultDirective returns a new Directive with the default escapeToken token func NewDefaultDirective() *Directive { directive := Directive{} directive.setEscapeToken(string(DefaultEscapeToken)) return &directive } func init() { // Dispatch Table. see line_parsers.go for the parse functions. // The command is parsed and mapped to the line parser. The line parser // receives the arguments but not the command, and returns an AST after // reformulating the arguments according to the rules in the parser // functions. Errors are propagated up by Parse() and the resulting AST can // be incorporated directly into the existing AST as a next. dispatch = map[string]func(string, *Directive) (*Node, map[string]bool, error){ command.Add: parseMaybeJSONToList, command.Arg: parseNameOrNameVal, command.Cmd: parseMaybeJSON, command.Copy: parseMaybeJSONToList, command.Entrypoint: parseMaybeJSON, command.Env: parseEnv, command.Expose: parseStringsWhitespaceDelimited, command.From: parseStringsWhitespaceDelimited, command.Healthcheck: parseHealthConfig, command.Label: parseLabel, command.Maintainer: parseString, command.Onbuild: parseSubCommand, command.Run: parseMaybeJSON, command.Shell: parseMaybeJSON, command.StopSignal: parseString, command.User: parseString, command.Volume: parseMaybeJSONToList, command.Workdir: parseString, } } // newNodeFromLine splits the line into parts, and dispatches to a function // based on the command and command arguments. A Node is created from the // result of the dispatch. func newNodeFromLine(line string, directive *Directive) (*Node, error) { cmd, flags, args, err := splitCommand(line) if err != nil { return nil, err } fn := dispatch[cmd] // Ignore invalid Dockerfile instructions if fn == nil { fn = parseIgnore } next, attrs, err := fn(args, directive) if err != nil { return nil, err } return &Node{ Value: cmd, Original: line, Flags: flags, Next: next, Attributes: attrs, }, nil } // Result is the result of parsing a Dockerfile type Result struct { AST *Node EscapeToken rune } // Parse reads lines from a Reader, parses the lines into an AST and returns // the AST and escape token func Parse(rwc io.Reader) (*Result, error) { d := NewDefaultDirective() currentLine := 0 root := &Node{StartLine: -1} scanner := bufio.NewScanner(rwc) var err error for scanner.Scan() { bytesRead := scanner.Bytes() if currentLine == 0 { // First line, strip the byte-order-marker if present bytesRead = bytes.TrimPrefix(bytesRead, utf8bom) } bytesRead, err = processLine(d, bytesRead, true) if err != nil { return nil, err } currentLine++ startLine := currentLine line, isEndOfLine := trimContinuationCharacter(string(bytesRead), d) if isEndOfLine && line == "" { continue } for !isEndOfLine && scanner.Scan() { bytesRead, err := processLine(d, scanner.Bytes(), false) if err != nil { return nil, err } currentLine++ // TODO: warn this is being deprecated/removed if isEmptyContinuationLine(bytesRead) { continue } continuationLine := string(bytesRead) continuationLine, isEndOfLine = trimContinuationCharacter(continuationLine, d) line += continuationLine } child, err := newNodeFromLine(line, d) if err != nil { return nil, err } root.AddChild(child, startLine, currentLine) } return &Result{AST: root, EscapeToken: d.escapeToken}, nil } func trimComments(src []byte) []byte { return tokenComment.ReplaceAll(src, []byte{}) } func trimWhitespace(src []byte) []byte { return bytes.TrimLeftFunc(src, unicode.IsSpace) } func isEmptyContinuationLine(line []byte) bool { return len(trimComments(trimWhitespace(line))) == 0 } var utf8bom = []byte{0xEF, 0xBB, 0xBF} func trimContinuationCharacter(line string, d *Directive) (string, bool) { if d.lineContinuationRegex.MatchString(line) { line = d.lineContinuationRegex.ReplaceAllString(line, "") return line, false } return line, true } // TODO: remove stripLeftWhitespace after deprecation period. It seems silly // to preserve whitespace on continuation lines. Why is that done? func processLine(d *Directive, token []byte, stripLeftWhitespace bool) ([]byte, error) { if stripLeftWhitespace { token = trimWhitespace(token) } err := d.possibleParserDirective(string(token)) return trimComments(token), err }