// Copyright 2009 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. // Code to parse a template. package template import ( "fmt" "io" "io/ioutil" "reflect" "strconv" "strings" "unicode" "unicode/utf8" ) // Errors returned during parsing and execution. Users may extract the information and reformat // if they desire. type Error struct { Line int Msg string } func (e *Error) Error() string { return fmt.Sprintf("line %d: %s", e.Line, e.Msg) } // checkError is a deferred function to turn a panic with type *Error into a plain error return. // Other panics are unexpected and so are re-enabled. func checkError(error *error) { if v := recover(); v != nil { if e, ok := v.(*Error); ok { *error = e } else { // runtime errors should crash panic(v) } } } // Most of the literals are aces. var lbrace = []byte{'{'} var rbrace = []byte{'}'} var space = []byte{' '} var tab = []byte{'\t'} // The various types of "tokens", which are plain text or (usually) brace-delimited descriptors const ( tokAlternates = iota tokComment tokEnd tokLiteral tokOr tokRepeated tokSection tokText tokVariable ) // FormatterMap is the type describing the mapping from formatter // names to the functions that implement them. type FormatterMap map[string]func(io.Writer, string, ...interface{}) // Built-in formatters. var builtins = FormatterMap{ "html": HTMLFormatter, "str": StringFormatter, "": StringFormatter, } // The parsed state of a template is a vector of xxxElement structs. // Sections have line numbers so errors can be reported better during execution. // Plain text. type textElement struct { text []byte } // A literal such as .meta-left or .meta-right type literalElement struct { text []byte } // A variable invocation to be evaluated type variableElement struct { linenum int args []interface{} // The fields and literals in the invocation. fmts []string // Names of formatters to apply. len(fmts) > 0 } // A variableElement arg to be evaluated as a field name type fieldName string // A .section block, possibly with a .or type sectionElement struct { linenum int // of .section itself field string // cursor field for this block start int // first element or int // first element of .or block end int // one beyond last element } // A .repeated block, possibly with a .or and a .alternates type repeatedElement struct { sectionElement // It has the same structure... altstart int // ... except for alternates altend int } // Template is the type that represents a template definition. // It is unchanged after parsing. type Template struct { fmap FormatterMap // formatters for variables // Used during parsing: ldelim, rdelim []byte // delimiters; default {} buf []byte // input text to process p int // position in buf linenum int // position in input // Parsed results: elems []interface{} } // New creates a new template with the specified formatter map (which // may be nil) to define auxiliary functions for formatting variables. func New(fmap FormatterMap) *Template { t := new(Template) t.fmap = fmap t.ldelim = lbrace t.rdelim = rbrace t.elems = make([]interface{}, 0, 16) return t } // Report error and stop executing. The line number must be provided explicitly. func (t *Template) execError(st *state, line int, err string, args ...interface{}) { panic(&Error{line, fmt.Sprintf(err, args...)}) } // Report error, panic to terminate parsing. // The line number comes from the template state. func (t *Template) parseError(err string, args ...interface{}) { panic(&Error{t.linenum, fmt.Sprintf(err, args...)}) } // Is this an exported - upper case - name? func isExported(name string) bool { r, _ := utf8.DecodeRuneInString(name) return unicode.IsUpper(r) } // -- Lexical analysis // Is c a space character? func isSpace(c uint8) bool { return c == ' ' || c == '\t' || c == '\r' || c == '\n' } // Safely, does s[n:n+len(t)] == t? func equal(s []byte, n int, t []byte) bool { b := s[n:] if len(t) > len(b) { // not enough space left for a match. return false } for i, c := range t { if c != b[i] { return false } } return true } // isQuote returns true if c is a string- or character-delimiting quote character. func isQuote(c byte) bool { return c == '"' || c == '`' || c == '\'' } // endQuote returns the end quote index for the quoted string that // starts at n, or -1 if no matching end quote is found before the end // of the line. func endQuote(s []byte, n int) int { quote := s[n] for n++; n < len(s); n++ { switch s[n] { case '\\': if quote == '"' || quote == '\'' { n++ } case '\n': return -1 case quote: return n } } return -1 } // nextItem returns the next item from the input buffer. If the returned // item is empty, we are at EOF. The item will be either a // delimited string or a non-empty string between delimited // strings. Tokens stop at (but include, if plain text) a newline. // Action tokens on a line by themselves drop any space on // either side, up to and including the newline. func (t *Template) nextItem() []byte { startOfLine := t.p == 0 || t.buf[t.p-1] == '\n' start := t.p var i int newline := func() { t.linenum++ i++ } // Leading space up to but not including newline for i = start; i < len(t.buf); i++ { if t.buf[i] == '\n' || !isSpace(t.buf[i]) { break } } leadingSpace := i > start // What's left is nothing, newline, delimited string, or plain text switch { case i == len(t.buf): // EOF; nothing to do case t.buf[i] == '\n': newline() case equal(t.buf, i, t.ldelim): left := i // Start of left delimiter. right := -1 // Will be (immediately after) right delimiter. haveText := false // Delimiters contain text. i += len(t.ldelim) // Find the end of the action. for ; i < len(t.buf); i++ { if t.buf[i] == '\n' { break } if isQuote(t.buf[i]) { i = endQuote(t.buf, i) if i == -1 { t.parseError("unmatched quote") return nil } continue } if equal(t.buf, i, t.rdelim) { i += len(t.rdelim) right = i break } haveText = true } if right < 0 { t.parseError("unmatched opening delimiter") return nil } // Is this a special action (starts with '.' or '#') and the only thing on the line? if startOfLine && haveText { firstChar := t.buf[left+len(t.ldelim)] if firstChar == '.' || firstChar == '#' { // It's special and the first thing on the line. Is it the last? for j := right; j < len(t.buf) && isSpace(t.buf[j]); j++ { if t.buf[j] == '\n' { // Yes it is. Drop the surrounding space and return the {.foo} t.linenum++ t.p = j + 1 return t.buf[left:right] } } } } // No it's not. If there's leading space, return that. if leadingSpace { // not trimming space: return leading space if there is some. t.p = left return t.buf[start:left] } // Return the word, leave the trailing space. start = left break default: for ; i < len(t.buf); i++ { if t.buf[i] == '\n' { newline() break } if equal(t.buf, i, t.ldelim) { break } } } item := t.buf[start:i] t.p = i return item } // Turn a byte array into a space-split array of strings, // taking into account quoted strings. func words(buf []byte) []string { s := make([]string, 0, 5) for i := 0; i < len(buf); { // One word per loop for i < len(buf) && isSpace(buf[i]) { i++ } if i == len(buf) { break } // Got a word start := i if isQuote(buf[i]) { i = endQuote(buf, i) if i < 0 { i = len(buf) } else { i++ } } // Even with quotes, break on space only. This handles input // such as {""|} and catches quoting mistakes. for i < len(buf) && !isSpace(buf[i]) { i++ } s = append(s, string(buf[start:i])) } return s } // Analyze an item and return its token type and, if it's an action item, an array of // its constituent words. func (t *Template) analyze(item []byte) (tok int, w []string) { // item is known to be non-empty if !equal(item, 0, t.ldelim) { // doesn't start with left delimiter tok = tokText return } if !equal(item, len(item)-len(t.rdelim), t.rdelim) { // doesn't end with right delimiter t.parseError("internal error: unmatched opening delimiter") // lexing should prevent this return } if len(item) <= len(t.ldelim)+len(t.rdelim) { // no contents t.parseError("empty directive") return } // Comment if item[len(t.ldelim)] == '#' { tok = tokComment return } // Split into words w = words(item[len(t.ldelim) : len(item)-len(t.rdelim)]) // drop final delimiter if len(w) == 0 { t.parseError("empty directive") return } first := w[0] if first[0] != '.' { tok = tokVariable return } if len(first) > 1 && first[1] >= '0' && first[1] <= '9' { // Must be a float. tok = tokVariable return } switch first { case ".meta-left", ".meta-right", ".space", ".tab": tok = tokLiteral return case ".or": tok = tokOr return case ".end": tok = tokEnd return case ".section": if len(w) != 2 { t.parseError("incorrect fields for .section: %s", item) return } tok = tokSection return case ".repeated": if len(w) != 3 || w[1] != "section" { t.parseError("incorrect fields for .repeated: %s", item) return } tok = tokRepeated return case ".alternates": if len(w) != 2 || w[1] != "with" { t.parseError("incorrect fields for .alternates: %s", item) return } tok = tokAlternates return } t.parseError("bad directive: %s", item) return } // formatter returns the Formatter with the given name in the Template, or nil if none exists. func (t *Template) formatter(name string) func(io.Writer, string, ...interface{}) { if t.fmap != nil { if fn := t.fmap[name]; fn != nil { return fn } } return builtins[name] } // -- Parsing // newVariable allocates a new variable-evaluation element. func (t *Template) newVariable(words []string) *variableElement { formatters := extractFormatters(words) args := make([]interface{}, len(words)) // Build argument list, processing any literals for i, word := range words { var lerr error switch word[0] { case '"', '`', '\'': v, err := strconv.Unquote(word) if err == nil && word[0] == '\'' { args[i], _ = utf8.DecodeRuneInString(v) } else { args[i], lerr = v, err } case '.', '+', '-', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9': v, err := strconv.ParseInt(word, 0, 64) if err == nil { args[i] = v } else { v, err := strconv.ParseFloat(word, 64) args[i], lerr = v, err } default: args[i] = fieldName(word) } if lerr != nil { t.parseError("invalid literal: %q: %s", word, lerr) } } // We could remember the function address here and avoid the lookup later, // but it's more dynamic to let the user change the map contents underfoot. // We do require the name to be present, though. // Is it in user-supplied map? for _, f := range formatters { if t.formatter(f) == nil { t.parseError("unknown formatter: %q", f) } } return &variableElement{t.linenum, args, formatters} } // extractFormatters extracts a list of formatters from words. // After the final space-separated argument in a variable, formatters may be // specified separated by pipe symbols. For example: {a b c|d|e} // The words parameter still has the formatters joined by '|' in the last word. // extractFormatters splits formatters, replaces the last word with the content // found before the first '|' within it, and returns the formatters obtained. // If no formatters are found in words, the default formatter is returned. func extractFormatters(words []string) (formatters []string) { // "" is the default formatter. formatters = []string{""} if len(words) == 0 { return } var bar int lastWord := words[len(words)-1] if isQuote(lastWord[0]) { end := endQuote([]byte(lastWord), 0) if end < 0 || end+1 == len(lastWord) || lastWord[end+1] != '|' { return } bar = end + 1 } else { bar = strings.IndexRune(lastWord, '|') if bar < 0 { return } } words[len(words)-1] = lastWord[0:bar] formatters = strings.Split(lastWord[bar+1:], "|") return } // Grab the next item. If it's simple, just append it to the template. // Otherwise return its details. func (t *Template) parseSimple(item []byte) (done bool, tok int, w []string) { tok, w = t.analyze(item) done = true // assume for simplicity switch tok { case tokComment: return case tokText: t.elems = append(t.elems, &textElement{item}) return case tokLiteral: switch w[0] { case ".meta-left": t.elems = append(t.elems, &literalElement{t.ldelim}) case ".meta-right": t.elems = append(t.elems, &literalElement{t.rdelim}) case ".space": t.elems = append(t.elems, &literalElement{space}) case ".tab": t.elems = append(t.elems, &literalElement{tab}) default: t.parseError("internal error: unknown literal: %s", w[0]) } return case tokVariable: t.elems = append(t.elems, t.newVariable(w)) return } return false, tok, w } // parseRepeated and parseSection are mutually recursive func (t *Template) parseRepeated(words []string) *repeatedElement { r := new(repeatedElement) t.elems = append(t.elems, r) r.linenum = t.linenum r.field = words[2] // Scan section, collecting true and false (.or) blocks. r.start = len(t.elems) r.or = -1 r.altstart = -1 r.altend = -1 Loop: for { item := t.nextItem() if len(item) == 0 { t.parseError("missing .end for .repeated section") break } done, tok, w := t.parseSimple(item) if done { continue } switch tok { case tokEnd: break Loop case tokOr: if r.or >= 0 { t.parseError("extra .or in .repeated section") break Loop } r.altend = len(t.elems) r.or = len(t.elems) case tokSection: t.parseSection(w) case tokRepeated: t.parseRepeated(w) case tokAlternates: if r.altstart >= 0 { t.parseError("extra .alternates in .repeated section") break Loop } if r.or >= 0 { t.parseError(".alternates inside .or block in .repeated section") break Loop } r.altstart = len(t.elems) default: t.parseError("internal error: unknown repeated section item: %s", item) break Loop } } if r.altend < 0 { r.altend = len(t.elems) } r.end = len(t.elems) return r } func (t *Template) parseSection(words []string) *sectionElement { s := new(sectionElement) t.elems = append(t.elems, s) s.linenum = t.linenum s.field = words[1] // Scan section, collecting true and false (.or) blocks. s.start = len(t.elems) s.or = -1 Loop: for { item := t.nextItem() if len(item) == 0 { t.parseError("missing .end for .section") break } done, tok, w := t.parseSimple(item) if done { continue } switch tok { case tokEnd: break Loop case tokOr: if s.or >= 0 { t.parseError("extra .or in .section") break Loop } s.or = len(t.elems) case tokSection: t.parseSection(w) case tokRepeated: t.parseRepeated(w) case tokAlternates: t.parseError(".alternates not in .repeated") default: t.parseError("internal error: unknown section item: %s", item) } } s.end = len(t.elems) return s } func (t *Template) parse() { for { item := t.nextItem() if len(item) == 0 { break } done, tok, w := t.parseSimple(item) if done { continue } switch tok { case tokOr, tokEnd, tokAlternates: t.parseError("unexpected %s", w[0]) case tokSection: t.parseSection(w) case tokRepeated: t.parseRepeated(w) default: t.parseError("internal error: bad directive in parse: %s", item) } } } // -- Execution // -- Public interface // Parse initializes a Template by parsing its definition. The string // s contains the template text. If any errors occur, Parse returns // the error. func (t *Template) Parse(s string) (err error) { if t.elems == nil { return &Error{1, "template not allocated with New"} } if !validDelim(t.ldelim) || !validDelim(t.rdelim) { return &Error{1, fmt.Sprintf("bad delimiter strings %q %q", t.ldelim, t.rdelim)} } defer checkError(&err) t.buf = []byte(s) t.p = 0 t.linenum = 1 t.parse() return nil } // ParseFile is like Parse but reads the template definition from the // named file. func (t *Template) ParseFile(filename string) (err error) { b, err := ioutil.ReadFile(filename) if err != nil { return err } return t.Parse(string(b)) } // Execute applies a parsed template to the specified data object, // generating output to wr. func (t *Template) Execute(wr io.Writer, data interface{}) (err error) { // Extract the driver data. val := reflect.ValueOf(data) defer checkError(&err) t.p = 0 t.execute(0, len(t.elems), &state{parent: nil, data: val, wr: wr}) return nil } // SetDelims sets the left and right delimiters for operations in the // template. They are validated during parsing. They could be // validated here but it's better to keep the routine simple. The // delimiters are very rarely invalid and Parse has the necessary // error-handling interface already. func (t *Template) SetDelims(left, right string) { t.ldelim = []byte(left) t.rdelim = []byte(right) } // Parse creates a Template with default parameters (such as {} for // metacharacters). The string s contains the template text while // the formatter map fmap, which may be nil, defines auxiliary functions // for formatting variables. The template is returned. If any errors // occur, err will be non-nil. func Parse(s string, fmap FormatterMap) (t *Template, err error) { t = New(fmap) err = t.Parse(s) if err != nil { t = nil } return } // ParseFile is a wrapper function that creates a Template with default // parameters (such as {} for metacharacters). The filename identifies // a file containing the template text, while the formatter map fmap, which // may be nil, defines auxiliary functions for formatting variables. // The template is returned. If any errors occur, err will be non-nil. func ParseFile(filename string, fmap FormatterMap) (t *Template, err error) { b, err := ioutil.ReadFile(filename) if err != nil { return nil, err } return Parse(string(b), fmap) } // MustParse is like Parse but panics if the template cannot be parsed. func MustParse(s string, fmap FormatterMap) *Template { t, err := Parse(s, fmap) if err != nil { panic("template.MustParse error: " + err.Error()) } return t } // MustParseFile is like ParseFile but panics if the file cannot be read // or the template cannot be parsed. func MustParseFile(filename string, fmap FormatterMap) *Template { b, err := ioutil.ReadFile(filename) if err != nil { panic("template.MustParseFile error: " + err.Error()) } return MustParse(string(b), fmap) }