// Copyright 2011 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 parse builds parse trees for templates as defined by text/template // and html/template. Clients should use those packages to construct templates // rather than this one, which provides shared internal data structures not // intended for general use. package parse import ( "bytes" "fmt" "runtime" "strconv" "strings" ) // Tree is the representation of a single parsed template. type Tree struct { Name string // name of the template represented by the tree. ParseName string // name of the top-level template during parsing, for error messages. Root *ListNode // top-level root of the tree. text string // text parsed to create the template (or its parent) // Parsing only; cleared after parse. funcs []map[string]interface{} lex *lexer token [3]item // three-token lookahead for parser. peekCount int vars []string // variables defined at the moment. } // Copy returns a copy of the Tree. Any parsing state is discarded. func (t *Tree) Copy() *Tree { if t == nil { return nil } return &Tree{ Name: t.Name, ParseName: t.ParseName, Root: t.Root.CopyList(), text: t.text, } } // Parse returns a map from template name to parse.Tree, created by parsing the // templates described in the argument string. The top-level template will be // given the specified name. If an error is encountered, parsing stops and an // empty map is returned with the error. func Parse(name, text, leftDelim, rightDelim string, funcs ...map[string]interface{}) (treeSet map[string]*Tree, err error) { treeSet = make(map[string]*Tree) t := New(name) t.text = text _, err = t.Parse(text, leftDelim, rightDelim, treeSet, funcs...) return } // next returns the next token. func (t *Tree) next() item { if t.peekCount > 0 { t.peekCount-- } else { t.token[0] = t.lex.nextItem() } return t.token[t.peekCount] } // backup backs the input stream up one token. func (t *Tree) backup() { t.peekCount++ } // backup2 backs the input stream up two tokens. // The zeroth token is already there. func (t *Tree) backup2(t1 item) { t.token[1] = t1 t.peekCount = 2 } // backup3 backs the input stream up three tokens // The zeroth token is already there. func (t *Tree) backup3(t2, t1 item) { // Reverse order: we're pushing back. t.token[1] = t1 t.token[2] = t2 t.peekCount = 3 } // peek returns but does not consume the next token. func (t *Tree) peek() item { if t.peekCount > 0 { return t.token[t.peekCount-1] } t.peekCount = 1 t.token[0] = t.lex.nextItem() return t.token[0] } // nextNonSpace returns the next non-space token. func (t *Tree) nextNonSpace() (token item) { for { token = t.next() if token.typ != itemSpace { break } } return token } // peekNonSpace returns but does not consume the next non-space token. func (t *Tree) peekNonSpace() (token item) { for { token = t.next() if token.typ != itemSpace { break } } t.backup() return token } // Parsing. // New allocates a new parse tree with the given name. func New(name string, funcs ...map[string]interface{}) *Tree { return &Tree{ Name: name, funcs: funcs, } } // ErrorContext returns a textual representation of the location of the node in the input text. // The receiver is only used when the node does not have a pointer to the tree inside, // which can occur in old code. func (t *Tree) ErrorContext(n Node) (location, context string) { pos := int(n.Position()) tree := n.tree() if tree == nil { tree = t } text := tree.text[:pos] byteNum := strings.LastIndex(text, "\n") if byteNum == -1 { byteNum = pos // On first line. } else { byteNum++ // After the newline. byteNum = pos - byteNum } lineNum := 1 + strings.Count(text, "\n") context = n.String() if len(context) > 20 { context = fmt.Sprintf("%.20s...", context) } return fmt.Sprintf("%s:%d:%d", tree.ParseName, lineNum, byteNum), context } // errorf formats the error and terminates processing. func (t *Tree) errorf(format string, args ...interface{}) { t.Root = nil format = fmt.Sprintf("template: %s:%d: %s", t.ParseName, t.lex.lineNumber(), format) panic(fmt.Errorf(format, args...)) } // error terminates processing. func (t *Tree) error(err error) { t.errorf("%s", err) } // expect consumes the next token and guarantees it has the required type. func (t *Tree) expect(expected itemType, context string) item { token := t.nextNonSpace() if token.typ != expected { t.unexpected(token, context) } return token } // expectOneOf consumes the next token and guarantees it has one of the required types. func (t *Tree) expectOneOf(expected1, expected2 itemType, context string) item { token := t.nextNonSpace() if token.typ != expected1 && token.typ != expected2 { t.unexpected(token, context) } return token } // unexpected complains about the token and terminates processing. func (t *Tree) unexpected(token item, context string) { t.errorf("unexpected %s in %s", token, context) } // recover is the handler that turns panics into returns from the top level of Parse. func (t *Tree) recover(errp *error) { e := recover() if e != nil { if _, ok := e.(runtime.Error); ok { panic(e) } if t != nil { t.stopParse() } *errp = e.(error) } return } // startParse initializes the parser, using the lexer. func (t *Tree) startParse(funcs []map[string]interface{}, lex *lexer) { t.Root = nil t.lex = lex t.vars = []string{"$"} t.funcs = funcs } // stopParse terminates parsing. func (t *Tree) stopParse() { t.lex = nil t.vars = nil t.funcs = nil } // Parse parses the template definition string to construct a representation of // the template for execution. If either action delimiter string is empty, the // default ("{{" or "}}") is used. Embedded template definitions are added to // the treeSet map. func (t *Tree) Parse(text, leftDelim, rightDelim string, treeSet map[string]*Tree, funcs ...map[string]interface{}) (tree *Tree, err error) { defer t.recover(&err) t.ParseName = t.Name t.startParse(funcs, lex(t.Name, text, leftDelim, rightDelim)) t.text = text t.parse(treeSet) t.add(treeSet) t.stopParse() return t, nil } // add adds tree to the treeSet. func (t *Tree) add(treeSet map[string]*Tree) { tree := treeSet[t.Name] if tree == nil || IsEmptyTree(tree.Root) { treeSet[t.Name] = t return } if !IsEmptyTree(t.Root) { t.errorf("template: multiple definition of template %q", t.Name) } } // IsEmptyTree reports whether this tree (node) is empty of everything but space. func IsEmptyTree(n Node) bool { switch n := n.(type) { case nil: return true case *ActionNode: case *IfNode: case *ListNode: for _, node := range n.Nodes { if !IsEmptyTree(node) { return false } } return true case *RangeNode: case *TemplateNode: case *TextNode: return len(bytes.TrimSpace(n.Text)) == 0 case *WithNode: default: panic("unknown node: " + n.String()) } return false } // parse is the top-level parser for a template, essentially the same // as itemList except it also parses {{define}} actions. // It runs to EOF. func (t *Tree) parse(treeSet map[string]*Tree) (next Node) { t.Root = t.newList(t.peek().pos) for t.peek().typ != itemEOF { if t.peek().typ == itemLeftDelim { delim := t.next() if t.nextNonSpace().typ == itemDefine { newT := New("definition") // name will be updated once we know it. newT.text = t.text newT.ParseName = t.ParseName newT.startParse(t.funcs, t.lex) newT.parseDefinition(treeSet) continue } t.backup2(delim) } n := t.textOrAction() if n.Type() == nodeEnd { t.errorf("unexpected %s", n) } t.Root.append(n) } return nil } // parseDefinition parses a {{define}} ... {{end}} template definition and // installs the definition in the treeSet map. The "define" keyword has already // been scanned. func (t *Tree) parseDefinition(treeSet map[string]*Tree) { const context = "define clause" name := t.expectOneOf(itemString, itemRawString, context) var err error t.Name, err = strconv.Unquote(name.val) if err != nil { t.error(err) } t.expect(itemRightDelim, context) var end Node t.Root, end = t.itemList() if end.Type() != nodeEnd { t.errorf("unexpected %s in %s", end, context) } t.add(treeSet) t.stopParse() } // itemList: // textOrAction* // Terminates at {{end}} or {{else}}, returned separately. func (t *Tree) itemList() (list *ListNode, next Node) { list = t.newList(t.peekNonSpace().pos) for t.peekNonSpace().typ != itemEOF { n := t.textOrAction() switch n.Type() { case nodeEnd, nodeElse: return list, n } list.append(n) } t.errorf("unexpected EOF") return } // textOrAction: // text | action func (t *Tree) textOrAction() Node { switch token := t.nextNonSpace(); token.typ { case itemElideNewline: return t.elideNewline() case itemText: return t.newText(token.pos, token.val) case itemLeftDelim: return t.action() default: t.unexpected(token, "input") } return nil } // elideNewline: // Remove newlines trailing rightDelim if \\ is present. func (t *Tree) elideNewline() Node { token := t.peek() if token.typ != itemText { t.unexpected(token, "input") return nil } t.next() stripped := strings.TrimLeft(token.val, "\n\r") diff := len(token.val) - len(stripped) if diff > 0 { // This is a bit nasty. We mutate the token in-place to remove // preceding newlines. token.pos += Pos(diff) token.val = stripped } return t.newText(token.pos, token.val) } // Action: // control // command ("|" command)* // Left delim is past. Now get actions. // First word could be a keyword such as range. func (t *Tree) action() (n Node) { switch token := t.nextNonSpace(); token.typ { case itemElse: return t.elseControl() case itemEnd: return t.endControl() case itemIf: return t.ifControl() case itemRange: return t.rangeControl() case itemTemplate: return t.templateControl() case itemWith: return t.withControl() } t.backup() // Do not pop variables; they persist until "end". return t.newAction(t.peek().pos, t.lex.lineNumber(), t.pipeline("command")) } // Pipeline: // declarations? command ('|' command)* func (t *Tree) pipeline(context string) (pipe *PipeNode) { var decl []*VariableNode pos := t.peekNonSpace().pos // Are there declarations? for { if v := t.peekNonSpace(); v.typ == itemVariable { t.next() // Since space is a token, we need 3-token look-ahead here in the worst case: // in "$x foo" we need to read "foo" (as opposed to ":=") to know that $x is an // argument variable rather than a declaration. So remember the token // adjacent to the variable so we can push it back if necessary. tokenAfterVariable := t.peek() if next := t.peekNonSpace(); next.typ == itemColonEquals || (next.typ == itemChar && next.val == ",") { t.nextNonSpace() variable := t.newVariable(v.pos, v.val) decl = append(decl, variable) t.vars = append(t.vars, v.val) if next.typ == itemChar && next.val == "," { if context == "range" && len(decl) < 2 { continue } t.errorf("too many declarations in %s", context) } } else if tokenAfterVariable.typ == itemSpace { t.backup3(v, tokenAfterVariable) } else { t.backup2(v) } } break } pipe = t.newPipeline(pos, t.lex.lineNumber(), decl) for { switch token := t.nextNonSpace(); token.typ { case itemRightDelim, itemRightParen: if len(pipe.Cmds) == 0 { t.errorf("missing value for %s", context) } if token.typ == itemRightParen { t.backup() } return case itemBool, itemCharConstant, itemComplex, itemDot, itemField, itemIdentifier, itemNumber, itemNil, itemRawString, itemString, itemVariable, itemLeftParen: t.backup() pipe.append(t.command()) default: t.unexpected(token, context) } } } func (t *Tree) parseControl(allowElseIf bool, context string) (pos Pos, line int, pipe *PipeNode, list, elseList *ListNode) { defer t.popVars(len(t.vars)) line = t.lex.lineNumber() pipe = t.pipeline(context) var next Node list, next = t.itemList() switch next.Type() { case nodeEnd: //done case nodeElse: if allowElseIf { // Special case for "else if". If the "else" is followed immediately by an "if", // the elseControl will have left the "if" token pending. Treat // {{if a}}_{{else if b}}_{{end}} // as // {{if a}}_{{else}}{{if b}}_{{end}}{{end}}. // To do this, parse the if as usual and stop at it {{end}}; the subsequent{{end}} // is assumed. This technique works even for long if-else-if chains. // TODO: Should we allow else-if in with and range? if t.peek().typ == itemIf { t.next() // Consume the "if" token. elseList = t.newList(next.Position()) elseList.append(t.ifControl()) // Do not consume the next item - only one {{end}} required. break } } elseList, next = t.itemList() if next.Type() != nodeEnd { t.errorf("expected end; found %s", next) } } return pipe.Position(), line, pipe, list, elseList } // If: // {{if pipeline}} itemList {{end}} // {{if pipeline}} itemList {{else}} itemList {{end}} // If keyword is past. func (t *Tree) ifControl() Node { return t.newIf(t.parseControl(true, "if")) } // Range: // {{range pipeline}} itemList {{end}} // {{range pipeline}} itemList {{else}} itemList {{end}} // Range keyword is past. func (t *Tree) rangeControl() Node { return t.newRange(t.parseControl(false, "range")) } // With: // {{with pipeline}} itemList {{end}} // {{with pipeline}} itemList {{else}} itemList {{end}} // If keyword is past. func (t *Tree) withControl() Node { return t.newWith(t.parseControl(false, "with")) } // End: // {{end}} // End keyword is past. func (t *Tree) endControl() Node { return t.newEnd(t.expect(itemRightDelim, "end").pos) } // Else: // {{else}} // Else keyword is past. func (t *Tree) elseControl() Node { // Special case for "else if". peek := t.peekNonSpace() if peek.typ == itemIf { // We see "{{else if ... " but in effect rewrite it to {{else}}{{if ... ". return t.newElse(peek.pos, t.lex.lineNumber()) } return t.newElse(t.expect(itemRightDelim, "else").pos, t.lex.lineNumber()) } // Template: // {{template stringValue pipeline}} // Template keyword is past. The name must be something that can evaluate // to a string. func (t *Tree) templateControl() Node { var name string token := t.nextNonSpace() switch token.typ { case itemString, itemRawString: s, err := strconv.Unquote(token.val) if err != nil { t.error(err) } name = s default: t.unexpected(token, "template invocation") } var pipe *PipeNode if t.nextNonSpace().typ != itemRightDelim { t.backup() // Do not pop variables; they persist until "end". pipe = t.pipeline("template") } return t.newTemplate(token.pos, t.lex.lineNumber(), name, pipe) } // command: // operand (space operand)* // space-separated arguments up to a pipeline character or right delimiter. // we consume the pipe character but leave the right delim to terminate the action. func (t *Tree) command() *CommandNode { cmd := t.newCommand(t.peekNonSpace().pos) for { t.peekNonSpace() // skip leading spaces. operand := t.operand() if operand != nil { cmd.append(operand) } switch token := t.next(); token.typ { case itemSpace: continue case itemError: t.errorf("%s", token.val) case itemRightDelim, itemRightParen: t.backup() case itemPipe: default: t.errorf("unexpected %s in operand; missing space?", token) } break } if len(cmd.Args) == 0 { t.errorf("empty command") } return cmd } // operand: // term .Field* // An operand is a space-separated component of a command, // a term possibly followed by field accesses. // A nil return means the next item is not an operand. func (t *Tree) operand() Node { node := t.term() if node == nil { return nil } if t.peek().typ == itemField { chain := t.newChain(t.peek().pos, node) for t.peek().typ == itemField { chain.Add(t.next().val) } // Compatibility with original API: If the term is of type NodeField // or NodeVariable, just put more fields on the original. // Otherwise, keep the Chain node. // TODO: Switch to Chains always when we can. switch node.Type() { case NodeField: node = t.newField(chain.Position(), chain.String()) case NodeVariable: node = t.newVariable(chain.Position(), chain.String()) default: node = chain } } return node } // term: // literal (number, string, nil, boolean) // function (identifier) // . // .Field // $ // '(' pipeline ')' // A term is a simple "expression". // A nil return means the next item is not a term. func (t *Tree) term() Node { switch token := t.nextNonSpace(); token.typ { case itemError: t.errorf("%s", token.val) case itemIdentifier: if !t.hasFunction(token.val) { t.errorf("function %q not defined", token.val) } return NewIdentifier(token.val).SetTree(t).SetPos(token.pos) case itemDot: return t.newDot(token.pos) case itemNil: return t.newNil(token.pos) case itemVariable: return t.useVar(token.pos, token.val) case itemField: return t.newField(token.pos, token.val) case itemBool: return t.newBool(token.pos, token.val == "true") case itemCharConstant, itemComplex, itemNumber: number, err := t.newNumber(token.pos, token.val, token.typ) if err != nil { t.error(err) } return number case itemLeftParen: pipe := t.pipeline("parenthesized pipeline") if token := t.next(); token.typ != itemRightParen { t.errorf("unclosed right paren: unexpected %s", token) } return pipe case itemString, itemRawString: s, err := strconv.Unquote(token.val) if err != nil { t.error(err) } return t.newString(token.pos, token.val, s) } t.backup() return nil } // hasFunction reports if a function name exists in the Tree's maps. func (t *Tree) hasFunction(name string) bool { for _, funcMap := range t.funcs { if funcMap == nil { continue } if funcMap[name] != nil { return true } } return false } // popVars trims the variable list to the specified length func (t *Tree) popVars(n int) { t.vars = t.vars[:n] } // useVar returns a node for a variable reference. It errors if the // variable is not defined. func (t *Tree) useVar(pos Pos, name string) Node { v := t.newVariable(pos, name) for _, varName := range t.vars { if varName == v.Ident[0] { return v } } t.errorf("undefined variable %q", v.Ident[0]) return nil }