; Module header is generated automatically #cs(module SXML-tree-trans mzscheme (require "myenv.ss") ; XML/HTML processing in Scheme ; SXML expression tree transformers ; ; IMPORT ; A prelude appropriate for your Scheme system ; (myenv-bigloo.scm, myenv-mit.scm, etc.) ; ; EXPORT ; (provide SRV:send-reply ; post-order pre-post-order replace-range) ; ; See vSXML-tree-trans.scm for the validation code, which also ; serves as usage examples. ; ; $Id: SXML-tree-trans.scm,v 1.7 2004/11/09 20:22:26 sperber Exp $ ; procedure: SRV:send-reply FRAGMENT ... ; ; Output the 'fragments' ; The fragments are a list of strings, characters, ; numbers, thunks, #f, #t -- and other fragments. ; The function traverses the tree depth-first, writes out ; strings and characters, executes thunks, and ignores ; #f and '(). ; The function returns #t if anything was written at all; ; otherwise the result is #f ; If #t occurs among the fragments, it is not written out ; but causes the result of SRV:send-reply to be #t (define (SRV:send-reply . fragments) (let loop ((fragments fragments) (result #f)) (cond ((null? fragments) result) ((not (car fragments)) (loop (cdr fragments) result)) ((null? (car fragments)) (loop (cdr fragments) result)) ((eq? #t (car fragments)) (loop (cdr fragments) #t)) ((pair? (car fragments)) (loop (cdr fragments) (loop (car fragments) result))) ((procedure? (car fragments)) ((car fragments)) (loop (cdr fragments) #t)) (else (display (car fragments)) (loop (cdr fragments) #t))))) ; procedure: pre-post-order TREE BINDINGS ; ; Traversal of an SXML tree or a grove: ; a <Node> or a <Nodelist> ; ; A <Node> and a <Nodelist> are mutually-recursive datatypes that ; underlie the SXML tree: ; <Node> ::= (name . <Nodelist>) | "text string" ; An (ordered) set of nodes is just a list of the constituent nodes: ; <Nodelist> ::= (<Node> ...) ; Nodelists, and Nodes other than text strings are both lists. A ; <Nodelist> however is either an empty list, or a list whose head is ; not a symbol (an atom in general). A symbol at the head of a node is ; either an XML name (in which case it's a tag of an XML element), or ; an administrative name such as '@'. ; See SXPath.scm and SSAX.scm for more information on SXML. ; ; ; Pre-Post-order traversal of a tree and creation of a new tree: ; pre-post-order:: <tree> x <bindings> -> <new-tree> ; where ; <bindings> ::= (<binding> ...) ; <binding> ::= (<trigger-symbol> *preorder* . <handler>) | ; (<trigger-symbol> *macro* . <handler>) | ; (<trigger-symbol> <new-bindings> . <handler>) | ; (<trigger-symbol> . <handler>) ; <trigger-symbol> ::= XMLname | *text* | *default* ; <handler> :: <trigger-symbol> x [<tree>] -> <new-tree> ; ; The pre-post-order function visits the nodes and nodelists ; pre-post-order (depth-first). For each <Node> of the form (name ; <Node> ...) it looks up an association with the given 'name' among ; its <bindings>. If failed, pre-post-order tries to locate a ; *default* binding. It's an error if the latter attempt fails as ; well. Having found a binding, the pre-post-order function first ; checks to see if the binding is of the form ; (<trigger-symbol> *preorder* . <handler>) ; If it is, the handler is 'applied' to the current node. Otherwise, ; the pre-post-order function first calls itself recursively for each ; child of the current node, with <new-bindings> prepended to the ; <bindings> in effect. The result of these calls is passed to the ; <handler> (along with the head of the current <Node>). To be more ; precise, the handler is _applied_ to the head of the current node ; and its processed children. The result of the handler, which should ; also be a <tree>, replaces the current <Node>. If the current <Node> ; is a text string or other atom, a special binding with a symbol ; *text* is looked up. ; ; A binding can also be of a form ; (<trigger-symbol> *macro* . <handler>) ; This is equivalent to *preorder* described above. However, the result ; is re-processed again, with the current stylesheet. ; (define (pre-post-order tree bindings) (let* ((default-binding (assq '*default* bindings)) (text-binding (or (assq '*text* bindings) default-binding)) (text-handler ; Cache default and text bindings (and text-binding (if (procedure? (cdr text-binding)) (cdr text-binding) (cddr text-binding))))) (let loop ((tree tree)) (cond ((null? tree) '()) ((not (pair? tree)) (let ((trigger '*text*)) (if text-handler (text-handler trigger tree) (error "Unknown binding for " trigger " and no default")))) ((not (symbol? (car tree))) (map loop tree)) ; tree is a nodelist (else ; tree is an SXML node (let* ((trigger (car tree)) (binding (or (assq trigger bindings) default-binding))) (cond ((not binding) (error "Unknown binding for " trigger " and no default")) ((not (pair? (cdr binding))) ; must be a procedure: handler (apply (cdr binding) trigger (map loop (cdr tree)))) ((eq? '*preorder* (cadr binding)) (apply (cddr binding) tree)) ((eq? '*macro* (cadr binding)) (loop (apply (cddr binding) tree))) (else ; (cadr binding) is a local binding (apply (cddr binding) trigger (pre-post-order (cdr tree) (append (cadr binding) bindings))) )))))))) ; procedure: post-order TREE BINDINGS ; post-order is a strict subset of pre-post-order without *preorder* ; (let alone *macro*) traversals. ; Now pre-post-order is actually faster than the old post-order. ; The function post-order is deprecated and is aliased below for ; backward compatibility. (define post-order pre-post-order) ;------------------------------------------------------------------------ ; Extended tree fold ; tree = atom | (node-name tree ...) ; ; foldts fdown fup fhere seed (Leaf str) = fhere seed str ; foldts fdown fup fhere seed (Nd kids) = ; fup seed $ foldl (foldts fdown fup fhere) (fdown seed) kids ; procedure fhere: seed -> atom -> seed ; procedure fdown: seed -> node -> seed ; procedure fup: parent-seed -> last-kid-seed -> node -> seed ; foldts returns the final seed (define (foldts fdown fup fhere seed tree) (cond ((null? tree) seed) ((not (pair? tree)) ; An atom (fhere seed tree)) (else (let loop ((kid-seed (fdown seed tree)) (kids (cdr tree))) (if (null? kids) (fup seed kid-seed tree) (loop (foldts fdown fup fhere kid-seed (car kids)) (cdr kids))))))) ; procedure: replace-range:: BEG-PRED x END-PRED x FOREST -> FOREST ; Traverse a forest depth-first and cut/replace ranges of nodes. ; ; The nodes that define a range don't have to have the same immediate ; parent, don't have to be on the same level, and the end node of a ; range doesn't even have to exist. A replace-range procedure removes ; nodes from the beginning node of the range up to (but not including) ; the end node of the range. In addition, the beginning node of the ; range can be replaced by a node or a list of nodes. The range of ; nodes is cut while depth-first traversing the forest. If all ; branches of the node are cut a node is cut as well. The procedure ; can cut several non-overlapping ranges from a forest. ; replace-range:: BEG-PRED x END-PRED x FOREST -> FOREST ; where ; type FOREST = (NODE ...) ; type NODE = Atom | (Name . FOREST) | FOREST ; ; The range of nodes is specified by two predicates, beg-pred and end-pred. ; beg-pred:: NODE -> #f | FOREST ; end-pred:: NODE -> #f | FOREST ; The beg-pred predicate decides on the beginning of the range. The node ; for which the predicate yields non-#f marks the beginning of the range ; The non-#f value of the predicate replaces the node. The value can be a ; list of nodes. The replace-range procedure then traverses the tree and skips ; all the nodes, until the end-pred yields non-#f. The value of the end-pred ; replaces the end-range node. The new end node and its brothers will be ; re-scanned. ; The predicates are evaluated pre-order. We do not descend into a node that ; is marked as the beginning of the range. (define (replace-range beg-pred end-pred forest) ; loop forest keep? new-forest ; forest is the forest to traverse ; new-forest accumulates the nodes we will keep, in the reverse ; order ; If keep? is #t, keep the curr node if atomic. If the node is not atomic, ; traverse its children and keep those that are not in the skip range. ; If keep? is #f, skip the current node if atomic. Otherwise, ; traverse its children. If all children are skipped, skip the node ; as well. (define (loop forest keep? new-forest) (if (null? forest) (values (reverse new-forest) keep?) (let ((node (car forest))) (if keep? (cond ; accumulate mode ((beg-pred node) => ; see if the node starts the skip range (lambda (repl-branches) ; if so, skip/replace the node (loop (cdr forest) #f (append (reverse repl-branches) new-forest)))) ((not (pair? node)) ; it's an atom, keep it (loop (cdr forest) keep? (cons node new-forest))) (else (let ((node? (symbol? (car node)))) ; or is it a nodelist? (call-with-values ; traverse its children (lambda () (loop (if node? (cdr node) node) #t '())) (lambda (new-kids keep?) (loop (cdr forest) keep? (cons (if node? (cons (car node) new-kids) new-kids) new-forest))))))) ; skip mode (cond ((end-pred node) => ; end the skip range (lambda (repl-branches) ; repl-branches will be re-scanned (loop (append repl-branches (cdr forest)) #t new-forest))) ((not (pair? node)) ; it's an atom, skip it (loop (cdr forest) keep? new-forest)) (else (let ((node? (symbol? (car node)))) ; or is it a nodelist? ; traverse its children (call-with-values (lambda () (loop (if node? (cdr node) node) #f '())) (lambda (new-kids keep?) (loop (cdr forest) keep? (if (or keep? (pair? new-kids)) (cons (if node? (cons (car node) new-kids) new-kids) new-forest) new-forest) ; if all kids are skipped )))))))))) ; skip the node too (call-with-values (lambda () (loop forest #t '())) (lambda (new-forest keep?) new-forest))) (provide (all-defined)))
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