ref: b5483eed6e8c07809fc818192e0ce00d9496565c
dir: /tpl/internal/go_templates/htmltemplate/escape.go/
// 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 template import ( "bytes" "fmt" "html" "io" template "github.com/gohugoio/hugo/tpl/internal/go_templates/texttemplate" "github.com/gohugoio/hugo/tpl/internal/go_templates/texttemplate/parse" ) // escapeTemplate rewrites the named template, which must be // associated with t, to guarantee that the output of any of the named // templates is properly escaped. If no error is returned, then the named templates have // been modified. Otherwise the named templates have been rendered // unusable. func escapeTemplate(tmpl *Template, node parse.Node, name string) error { c, _ := tmpl.esc.escapeTree(context{}, node, name, 0) var err error if c.err != nil { err, c.err.Name = c.err, name } else if c.state != stateText { err = &Error{ErrEndContext, nil, name, 0, fmt.Sprintf("ends in a non-text context: %v", c)} } if err != nil { // Prevent execution of unsafe templates. if t := tmpl.set[name]; t != nil { t.escapeErr = err t.text.Tree = nil t.Tree = nil } return err } tmpl.esc.commit() if t := tmpl.set[name]; t != nil { t.escapeErr = escapeOK t.Tree = t.text.Tree } return nil } // evalArgs formats the list of arguments into a string. It is equivalent to // fmt.Sprint(args...), except that it deferences all pointers. func evalArgs(args ...interface{}) string { // Optimization for simple common case of a single string argument. if len(args) == 1 { if s, ok := args[0].(string); ok { return s } } for i, arg := range args { args[i] = indirectToStringerOrError(arg) } return fmt.Sprint(args...) } // funcMap maps command names to functions that render their inputs safe. var funcMap = template.FuncMap{ "_html_template_attrescaper": attrEscaper, "_html_template_commentescaper": commentEscaper, "_html_template_cssescaper": cssEscaper, "_html_template_cssvaluefilter": cssValueFilter, "_html_template_htmlnamefilter": htmlNameFilter, "_html_template_htmlescaper": htmlEscaper, "_html_template_jsregexpescaper": jsRegexpEscaper, "_html_template_jsstrescaper": jsStrEscaper, "_html_template_jsvalescaper": jsValEscaper, "_html_template_nospaceescaper": htmlNospaceEscaper, "_html_template_rcdataescaper": rcdataEscaper, "_html_template_srcsetescaper": srcsetFilterAndEscaper, "_html_template_urlescaper": urlEscaper, "_html_template_urlfilter": urlFilter, "_html_template_urlnormalizer": urlNormalizer, "_eval_args_": evalArgs, } // escaper collects type inferences about templates and changes needed to make // templates injection safe. type escaper struct { // ns is the nameSpace that this escaper is associated with. ns *nameSpace // output[templateName] is the output context for a templateName that // has been mangled to include its input context. output map[string]context // derived[c.mangle(name)] maps to a template derived from the template // named name templateName for the start context c. derived map[string]*template.Template // called[templateName] is a set of called mangled template names. called map[string]bool // xxxNodeEdits are the accumulated edits to apply during commit. // Such edits are not applied immediately in case a template set // executes a given template in different escaping contexts. actionNodeEdits map[*parse.ActionNode][]string templateNodeEdits map[*parse.TemplateNode]string textNodeEdits map[*parse.TextNode][]byte } // makeEscaper creates a blank escaper for the given set. func makeEscaper(n *nameSpace) escaper { return escaper{ n, map[string]context{}, map[string]*template.Template{}, map[string]bool{}, map[*parse.ActionNode][]string{}, map[*parse.TemplateNode]string{}, map[*parse.TextNode][]byte{}, } } // filterFailsafe is an innocuous word that is emitted in place of unsafe values // by sanitizer functions. It is not a keyword in any programming language, // contains no special characters, is not empty, and when it appears in output // it is distinct enough that a developer can find the source of the problem // via a search engine. const filterFailsafe = "ZgotmplZ" // escape escapes a template node. func (e *escaper) escape(c context, n parse.Node) context { switch n := n.(type) { case *parse.ActionNode: return e.escapeAction(c, n) case *parse.IfNode: return e.escapeBranch(c, &n.BranchNode, "if") case *parse.ListNode: return e.escapeList(c, n) case *parse.RangeNode: return e.escapeBranch(c, &n.BranchNode, "range") case *parse.TemplateNode: return e.escapeTemplate(c, n) case *parse.TextNode: return e.escapeText(c, n) case *parse.WithNode: return e.escapeBranch(c, &n.BranchNode, "with") } panic("escaping " + n.String() + " is unimplemented") } // escapeAction escapes an action template node. func (e *escaper) escapeAction(c context, n *parse.ActionNode) context { if len(n.Pipe.Decl) != 0 { // A local variable assignment, not an interpolation. return c } c = nudge(c) // Check for disallowed use of predefined escapers in the pipeline. for pos, idNode := range n.Pipe.Cmds { node, ok := idNode.Args[0].(*parse.IdentifierNode) if !ok { // A predefined escaper "esc" will never be found as an identifier in a // Chain or Field node, since: // - "esc.x ..." is invalid, since predefined escapers return strings, and // strings do not have methods, keys or fields. // - "... .esc" is invalid, since predefined escapers are global functions, // not methods or fields of any types. // Therefore, it is safe to ignore these two node types. continue } ident := node.Ident if _, ok := predefinedEscapers[ident]; ok { if pos < len(n.Pipe.Cmds)-1 || c.state == stateAttr && c.delim == delimSpaceOrTagEnd && ident == "html" { return context{ state: stateError, err: errorf(ErrPredefinedEscaper, n, n.Line, "predefined escaper %q disallowed in template", ident), } } } } s := make([]string, 0, 3) switch c.state { case stateError: return c case stateURL, stateCSSDqStr, stateCSSSqStr, stateCSSDqURL, stateCSSSqURL, stateCSSURL: switch c.urlPart { case urlPartNone: s = append(s, "_html_template_urlfilter") fallthrough case urlPartPreQuery: switch c.state { case stateCSSDqStr, stateCSSSqStr: s = append(s, "_html_template_cssescaper") default: s = append(s, "_html_template_urlnormalizer") } case urlPartQueryOrFrag: s = append(s, "_html_template_urlescaper") case urlPartUnknown: return context{ state: stateError, err: errorf(ErrAmbigContext, n, n.Line, "%s appears in an ambiguous context within a URL", n), } default: panic(c.urlPart.String()) } case stateJS: s = append(s, "_html_template_jsvalescaper") // A slash after a value starts a div operator. c.jsCtx = jsCtxDivOp case stateJSDqStr, stateJSSqStr: s = append(s, "_html_template_jsstrescaper") case stateJSRegexp: s = append(s, "_html_template_jsregexpescaper") case stateCSS: s = append(s, "_html_template_cssvaluefilter") case stateText: s = append(s, "_html_template_htmlescaper") case stateRCDATA: s = append(s, "_html_template_rcdataescaper") case stateAttr: // Handled below in delim check. case stateAttrName, stateTag: c.state = stateAttrName s = append(s, "_html_template_htmlnamefilter") case stateSrcset: s = append(s, "_html_template_srcsetescaper") default: if isComment(c.state) { s = append(s, "_html_template_commentescaper") } else { panic("unexpected state " + c.state.String()) } } switch c.delim { case delimNone: // No extra-escaping needed for raw text content. case delimSpaceOrTagEnd: s = append(s, "_html_template_nospaceescaper") default: s = append(s, "_html_template_attrescaper") } e.editActionNode(n, s) return c } // ensurePipelineContains ensures that the pipeline ends with the commands with // the identifiers in s in order. If the pipeline ends with a predefined escaper // (i.e. "html" or "urlquery"), merge it with the identifiers in s. func ensurePipelineContains(p *parse.PipeNode, s []string) { if len(s) == 0 { // Do not rewrite pipeline if we have no escapers to insert. return } // Precondition: p.Cmds contains at most one predefined escaper and the // escaper will be present at p.Cmds[len(p.Cmds)-1]. This precondition is // always true because of the checks in escapeAction. pipelineLen := len(p.Cmds) if pipelineLen > 0 { lastCmd := p.Cmds[pipelineLen-1] if idNode, ok := lastCmd.Args[0].(*parse.IdentifierNode); ok { if esc := idNode.Ident; predefinedEscapers[esc] { // Pipeline ends with a predefined escaper. if len(p.Cmds) == 1 && len(lastCmd.Args) > 1 { // Special case: pipeline is of the form {{ esc arg1 arg2 ... argN }}, // where esc is the predefined escaper, and arg1...argN are its arguments. // Convert this into the equivalent form // {{ _eval_args_ arg1 arg2 ... argN | esc }}, so that esc can be easily // merged with the escapers in s. lastCmd.Args[0] = parse.NewIdentifier("_eval_args_").SetTree(nil).SetPos(lastCmd.Args[0].Position()) p.Cmds = appendCmd(p.Cmds, newIdentCmd(esc, p.Position())) pipelineLen++ } // If any of the commands in s that we are about to insert is equivalent // to the predefined escaper, use the predefined escaper instead. dup := false for i, escaper := range s { if escFnsEq(esc, escaper) { s[i] = idNode.Ident dup = true } } if dup { // The predefined escaper will already be inserted along with the // escapers in s, so do not copy it to the rewritten pipeline. pipelineLen-- } } } } // Rewrite the pipeline, creating the escapers in s at the end of the pipeline. newCmds := make([]*parse.CommandNode, pipelineLen, pipelineLen+len(s)) insertedIdents := make(map[string]bool) for i := 0; i < pipelineLen; i++ { cmd := p.Cmds[i] newCmds[i] = cmd if idNode, ok := cmd.Args[0].(*parse.IdentifierNode); ok { insertedIdents[normalizeEscFn(idNode.Ident)] = true } } for _, name := range s { if !insertedIdents[normalizeEscFn(name)] { // When two templates share an underlying parse tree via the use of // AddParseTree and one template is executed after the other, this check // ensures that escapers that were already inserted into the pipeline on // the first escaping pass do not get inserted again. newCmds = appendCmd(newCmds, newIdentCmd(name, p.Position())) } } p.Cmds = newCmds } // predefinedEscapers contains template predefined escapers that are equivalent // to some contextual escapers. Keep in sync with equivEscapers. var predefinedEscapers = map[string]bool{ "html": true, "urlquery": true, } // equivEscapers matches contextual escapers to equivalent predefined // template escapers. var equivEscapers = map[string]string{ // The following pairs of HTML escapers provide equivalent security // guarantees, since they all escape '\000', '\'', '"', '&', '<', and '>'. "_html_template_attrescaper": "html", "_html_template_htmlescaper": "html", "_html_template_rcdataescaper": "html", // These two URL escapers produce URLs safe for embedding in a URL query by // percent-encoding all the reserved characters specified in RFC 3986 Section // 2.2 "_html_template_urlescaper": "urlquery", // These two functions are not actually equivalent; urlquery is stricter as it // escapes reserved characters (e.g. '#'), while _html_template_urlnormalizer // does not. It is therefore only safe to replace _html_template_urlnormalizer // with urlquery (this happens in ensurePipelineContains), but not the otherI've // way around. We keep this entry around to preserve the behavior of templates // written before Go 1.9, which might depend on this substitution taking place. "_html_template_urlnormalizer": "urlquery", } // escFnsEq reports whether the two escaping functions are equivalent. func escFnsEq(a, b string) bool { return normalizeEscFn(a) == normalizeEscFn(b) } // normalizeEscFn(a) is equal to normalizeEscFn(b) for any pair of names of // escaper functions a and b that are equivalent. func normalizeEscFn(e string) string { if norm := equivEscapers[e]; norm != "" { return norm } return e } // redundantFuncs[a][b] implies that funcMap[b](funcMap[a](x)) == funcMap[a](x) // for all x. var redundantFuncs = map[string]map[string]bool{ "_html_template_commentescaper": { "_html_template_attrescaper": true, "_html_template_nospaceescaper": true, "_html_template_htmlescaper": true, }, "_html_template_cssescaper": { "_html_template_attrescaper": true, }, "_html_template_jsregexpescaper": { "_html_template_attrescaper": true, }, "_html_template_jsstrescaper": { "_html_template_attrescaper": true, }, "_html_template_urlescaper": { "_html_template_urlnormalizer": true, }, } // appendCmd appends the given command to the end of the command pipeline // unless it is redundant with the last command. func appendCmd(cmds []*parse.CommandNode, cmd *parse.CommandNode) []*parse.CommandNode { if n := len(cmds); n != 0 { last, okLast := cmds[n-1].Args[0].(*parse.IdentifierNode) next, okNext := cmd.Args[0].(*parse.IdentifierNode) if okLast && okNext && redundantFuncs[last.Ident][next.Ident] { return cmds } } return append(cmds, cmd) } // newIdentCmd produces a command containing a single identifier node. func newIdentCmd(identifier string, pos parse.Pos) *parse.CommandNode { return &parse.CommandNode{ NodeType: parse.NodeCommand, Args: []parse.Node{parse.NewIdentifier(identifier).SetTree(nil).SetPos(pos)}, // TODO: SetTree. } } // nudge returns the context that would result from following empty string // transitions from the input context. // For example, parsing: // `<a href=` // will end in context{stateBeforeValue, attrURL}, but parsing one extra rune: // `<a href=x` // will end in context{stateURL, delimSpaceOrTagEnd, ...}. // There are two transitions that happen when the 'x' is seen: // (1) Transition from a before-value state to a start-of-value state without // consuming any character. // (2) Consume 'x' and transition past the first value character. // In this case, nudging produces the context after (1) happens. func nudge(c context) context { switch c.state { case stateTag: // In `<foo {{.}}`, the action should emit an attribute. c.state = stateAttrName case stateBeforeValue: // In `<foo bar={{.}}`, the action is an undelimited value. c.state, c.delim, c.attr = attrStartStates[c.attr], delimSpaceOrTagEnd, attrNone case stateAfterName: // In `<foo bar {{.}}`, the action is an attribute name. c.state, c.attr = stateAttrName, attrNone } return c } // join joins the two contexts of a branch template node. The result is an // error context if either of the input contexts are error contexts, or if the // input contexts differ. func join(a, b context, node parse.Node, nodeName string) context { if a.state == stateError { return a } if b.state == stateError { return b } if a.eq(b) { return a } c := a c.urlPart = b.urlPart if c.eq(b) { // The contexts differ only by urlPart. c.urlPart = urlPartUnknown return c } c = a c.jsCtx = b.jsCtx if c.eq(b) { // The contexts differ only by jsCtx. c.jsCtx = jsCtxUnknown return c } // Allow a nudged context to join with an unnudged one. // This means that // <p title={{if .C}}{{.}}{{end}} // ends in an unquoted value state even though the else branch // ends in stateBeforeValue. if c, d := nudge(a), nudge(b); !(c.eq(a) && d.eq(b)) { if e := join(c, d, node, nodeName); e.state != stateError { return e } } return context{ state: stateError, err: errorf(ErrBranchEnd, node, 0, "{{%s}} branches end in different contexts: %v, %v", nodeName, a, b), } } // escapeBranch escapes a branch template node: "if", "range" and "with". func (e *escaper) escapeBranch(c context, n *parse.BranchNode, nodeName string) context { c0 := e.escapeList(c, n.List) if nodeName == "range" && c0.state != stateError { // The "true" branch of a "range" node can execute multiple times. // We check that executing n.List once results in the same context // as executing n.List twice. c1, _ := e.escapeListConditionally(c0, n.List, nil) c0 = join(c0, c1, n, nodeName) if c0.state == stateError { // Make clear that this is a problem on loop re-entry // since developers tend to overlook that branch when // debugging templates. c0.err.Line = n.Line c0.err.Description = "on range loop re-entry: " + c0.err.Description return c0 } } c1 := e.escapeList(c, n.ElseList) return join(c0, c1, n, nodeName) } // escapeList escapes a list template node. func (e *escaper) escapeList(c context, n *parse.ListNode) context { if n == nil { return c } for _, m := range n.Nodes { c = e.escape(c, m) } return c } // escapeListConditionally escapes a list node but only preserves edits and // inferences in e if the inferences and output context satisfy filter. // It returns the best guess at an output context, and the result of the filter // which is the same as whether e was updated. func (e *escaper) escapeListConditionally(c context, n *parse.ListNode, filter func(*escaper, context) bool) (context, bool) { e1 := makeEscaper(e.ns) // Make type inferences available to f. for k, v := range e.output { e1.output[k] = v } c = e1.escapeList(c, n) ok := filter != nil && filter(&e1, c) if ok { // Copy inferences and edits from e1 back into e. for k, v := range e1.output { e.output[k] = v } for k, v := range e1.derived { e.derived[k] = v } for k, v := range e1.called { e.called[k] = v } for k, v := range e1.actionNodeEdits { e.editActionNode(k, v) } for k, v := range e1.templateNodeEdits { e.editTemplateNode(k, v) } for k, v := range e1.textNodeEdits { e.editTextNode(k, v) } } return c, ok } // escapeTemplate escapes a {{template}} call node. func (e *escaper) escapeTemplate(c context, n *parse.TemplateNode) context { c, name := e.escapeTree(c, n, n.Name, n.Line) if name != n.Name { e.editTemplateNode(n, name) } return c } // escapeTree escapes the named template starting in the given context as // necessary and returns its output context. func (e *escaper) escapeTree(c context, node parse.Node, name string, line int) (context, string) { // Mangle the template name with the input context to produce a reliable // identifier. dname := c.mangle(name) e.called[dname] = true if out, ok := e.output[dname]; ok { // Already escaped. return out, dname } t := e.template(name) if t == nil { // Two cases: The template exists but is empty, or has never been mentioned at // all. Distinguish the cases in the error messages. if e.ns.set[name] != nil { return context{ state: stateError, err: errorf(ErrNoSuchTemplate, node, line, "%q is an incomplete or empty template", name), }, dname } return context{ state: stateError, err: errorf(ErrNoSuchTemplate, node, line, "no such template %q", name), }, dname } if dname != name { // Use any template derived during an earlier call to escapeTemplate // with different top level templates, or clone if necessary. dt := e.template(dname) if dt == nil { dt = template.New(dname) dt.Tree = &parse.Tree{Name: dname, Root: t.Root.CopyList()} e.derived[dname] = dt } t = dt } return e.computeOutCtx(c, t), dname } // computeOutCtx takes a template and its start context and computes the output // context while storing any inferences in e. func (e *escaper) computeOutCtx(c context, t *template.Template) context { // Propagate context over the body. c1, ok := e.escapeTemplateBody(c, t) if !ok { // Look for a fixed point by assuming c1 as the output context. if c2, ok2 := e.escapeTemplateBody(c1, t); ok2 { c1, ok = c2, true } // Use c1 as the error context if neither assumption worked. } if !ok && c1.state != stateError { return context{ state: stateError, err: errorf(ErrOutputContext, t.Tree.Root, 0, "cannot compute output context for template %s", t.Name()), } } return c1 } // escapeTemplateBody escapes the given template assuming the given output // context, and returns the best guess at the output context and whether the // assumption was correct. func (e *escaper) escapeTemplateBody(c context, t *template.Template) (context, bool) { filter := func(e1 *escaper, c1 context) bool { if c1.state == stateError { // Do not update the input escaper, e. return false } if !e1.called[t.Name()] { // If t is not recursively called, then c1 is an // accurate output context. return true } // c1 is accurate if it matches our assumed output context. return c.eq(c1) } // We need to assume an output context so that recursive template calls // take the fast path out of escapeTree instead of infinitely recursing. // Naively assuming that the input context is the same as the output // works >90% of the time. e.output[t.Name()] = c return e.escapeListConditionally(c, t.Tree.Root, filter) } // delimEnds maps each delim to a string of characters that terminate it. var delimEnds = [...]string{ delimDoubleQuote: `"`, delimSingleQuote: "'", // Determined empirically by running the below in various browsers. // var div = document.createElement("DIV"); // for (var i = 0; i < 0x10000; ++i) { // div.innerHTML = "<span title=x" + String.fromCharCode(i) + "-bar>"; // if (div.getElementsByTagName("SPAN")[0].title.indexOf("bar") < 0) // document.write("<p>U+" + i.toString(16)); // } delimSpaceOrTagEnd: " \t\n\f\r>", } var doctypeBytes = []byte("<!DOCTYPE") // escapeText escapes a text template node. func (e *escaper) escapeText(c context, n *parse.TextNode) context { s, written, i, b := n.Text, 0, 0, new(bytes.Buffer) for i != len(s) { c1, nread := contextAfterText(c, s[i:]) i1 := i + nread if c.state == stateText || c.state == stateRCDATA { end := i1 if c1.state != c.state { for j := end - 1; j >= i; j-- { if s[j] == '<' { end = j break } } } for j := i; j < end; j++ { if s[j] == '<' && !bytes.HasPrefix(bytes.ToUpper(s[j:]), doctypeBytes) { b.Write(s[written:j]) b.WriteString("<") written = j + 1 } } } else if isComment(c.state) && c.delim == delimNone { switch c.state { case stateJSBlockCmt: // https://es5.github.com/#x7.4: // "Comments behave like white space and are // discarded except that, if a MultiLineComment // contains a line terminator character, then // the entire comment is considered to be a // LineTerminator for purposes of parsing by // the syntactic grammar." if bytes.ContainsAny(s[written:i1], "\n\r\u2028\u2029") { b.WriteByte('\n') } else { b.WriteByte(' ') } case stateCSSBlockCmt: b.WriteByte(' ') } written = i1 } if c.state != c1.state && isComment(c1.state) && c1.delim == delimNone { // Preserve the portion between written and the comment start. cs := i1 - 2 if c1.state == stateHTMLCmt { // "<!--" instead of "/*" or "//" cs -= 2 } b.Write(s[written:cs]) written = i1 } if i == i1 && c.state == c1.state { panic(fmt.Sprintf("infinite loop from %v to %v on %q..%q", c, c1, s[:i], s[i:])) } c, i = c1, i1 } if written != 0 && c.state != stateError { if !isComment(c.state) || c.delim != delimNone { b.Write(n.Text[written:]) } e.editTextNode(n, b.Bytes()) } return c } // contextAfterText starts in context c, consumes some tokens from the front of // s, then returns the context after those tokens and the unprocessed suffix. func contextAfterText(c context, s []byte) (context, int) { if c.delim == delimNone { c1, i := tSpecialTagEnd(c, s) if i == 0 { // A special end tag (`</script>`) has been seen and // all content preceding it has been consumed. return c1, 0 } // Consider all content up to any end tag. return transitionFunc[c.state](c, s[:i]) } // We are at the beginning of an attribute value. i := bytes.IndexAny(s, delimEnds[c.delim]) if i == -1 { i = len(s) } if c.delim == delimSpaceOrTagEnd { // https://www.w3.org/TR/html5/syntax.html#attribute-value-(unquoted)-state // lists the runes below as error characters. // Error out because HTML parsers may differ on whether // "<a id= onclick=f(" ends inside id's or onclick's value, // "<a class=`foo " ends inside a value, // "<a style=font:'Arial'" needs open-quote fixup. // IE treats '`' as a quotation character. if j := bytes.IndexAny(s[:i], "\"'<=`"); j >= 0 { return context{ state: stateError, err: errorf(ErrBadHTML, nil, 0, "%q in unquoted attr: %q", s[j:j+1], s[:i]), }, len(s) } } if i == len(s) { // Remain inside the attribute. // Decode the value so non-HTML rules can easily handle // <button onclick="alert("Hi!")"> // without having to entity decode token boundaries. for u := []byte(html.UnescapeString(string(s))); len(u) != 0; { c1, i1 := transitionFunc[c.state](c, u) c, u = c1, u[i1:] } return c, len(s) } element := c.element // If this is a non-JS "type" attribute inside "script" tag, do not treat the contents as JS. if c.state == stateAttr && c.element == elementScript && c.attr == attrScriptType && !isJSType(string(s[:i])) { element = elementNone } if c.delim != delimSpaceOrTagEnd { // Consume any quote. i++ } // On exiting an attribute, we discard all state information // except the state and element. return context{state: stateTag, element: element}, i } // editActionNode records a change to an action pipeline for later commit. func (e *escaper) editActionNode(n *parse.ActionNode, cmds []string) { if _, ok := e.actionNodeEdits[n]; ok { panic(fmt.Sprintf("node %s shared between templates", n)) } e.actionNodeEdits[n] = cmds } // editTemplateNode records a change to a {{template}} callee for later commit. func (e *escaper) editTemplateNode(n *parse.TemplateNode, callee string) { if _, ok := e.templateNodeEdits[n]; ok { panic(fmt.Sprintf("node %s shared between templates", n)) } e.templateNodeEdits[n] = callee } // editTextNode records a change to a text node for later commit. func (e *escaper) editTextNode(n *parse.TextNode, text []byte) { if _, ok := e.textNodeEdits[n]; ok { panic(fmt.Sprintf("node %s shared between templates", n)) } e.textNodeEdits[n] = text } // commit applies changes to actions and template calls needed to contextually // autoescape content and adds any derived templates to the set. func (e *escaper) commit() { for name := range e.output { e.template(name).Funcs(funcMap) } // Any template from the name space associated with this escaper can be used // to add derived templates to the underlying text/template name space. tmpl := e.arbitraryTemplate() for _, t := range e.derived { if _, err := tmpl.text.AddParseTree(t.Name(), t.Tree); err != nil { panic("error adding derived template") } } for n, s := range e.actionNodeEdits { ensurePipelineContains(n.Pipe, s) } for n, name := range e.templateNodeEdits { n.Name = name } for n, s := range e.textNodeEdits { n.Text = s } // Reset state that is specific to this commit so that the same changes are // not re-applied to the template on subsequent calls to commit. e.called = make(map[string]bool) e.actionNodeEdits = make(map[*parse.ActionNode][]string) e.templateNodeEdits = make(map[*parse.TemplateNode]string) e.textNodeEdits = make(map[*parse.TextNode][]byte) } // template returns the named template given a mangled template name. func (e *escaper) template(name string) *template.Template { // Any template from the name space associated with this escaper can be used // to look up templates in the underlying text/template name space. t := e.arbitraryTemplate().text.Lookup(name) if t == nil { t = e.derived[name] } return t } // arbitraryTemplate returns an arbitrary template from the name space // associated with e and panics if no templates are found. func (e *escaper) arbitraryTemplate() *Template { for _, t := range e.ns.set { return t } panic("no templates in name space") } // Forwarding functions so that clients need only import this package // to reach the general escaping functions of text/template. // HTMLEscape writes to w the escaped HTML equivalent of the plain text data b. func HTMLEscape(w io.Writer, b []byte) { template.HTMLEscape(w, b) } // HTMLEscapeString returns the escaped HTML equivalent of the plain text data s. func HTMLEscapeString(s string) string { return template.HTMLEscapeString(s) } // HTMLEscaper returns the escaped HTML equivalent of the textual // representation of its arguments. func HTMLEscaper(args ...interface{}) string { return template.HTMLEscaper(args...) } // JSEscape writes to w the escaped JavaScript equivalent of the plain text data b. func JSEscape(w io.Writer, b []byte) { template.JSEscape(w, b) } // JSEscapeString returns the escaped JavaScript equivalent of the plain text data s. func JSEscapeString(s string) string { return template.JSEscapeString(s) } // JSEscaper returns the escaped JavaScript equivalent of the textual // representation of its arguments. func JSEscaper(args ...interface{}) string { return template.JSEscaper(args...) } // URLQueryEscaper returns the escaped value of the textual representation of // its arguments in a form suitable for embedding in a URL query. func URLQueryEscaper(args ...interface{}) string { return template.URLQueryEscaper(args...) }