#lang scribble/manual @(require scribble/eval pollen/decode pollen/world (prefix-in html: pollen/html) txexpr (for-label racket (except-in pollen #%module-begin) pollen/world pollen/cache pollen/decode txexpr xml pollen/html)) @(define my-eval (make-base-eval)) @(my-eval `(require pollen pollen/decode xml racket/list txexpr)) @title{Decode} @defmodule[pollen/decode] The @racket[doc] export of a Pollen markup file is a simple X-expression. @italic{Decoding} refers to any post-processing of this X-expression. The @racket[pollen/decode] module provides tools for creating decoders. The decode step can happen separately from the compilation of the file. But you can also attach a decoder to the markup file's @racket[root] node, so the decoding happens automatically when the markup is compiled, and thus automatically incorporated into @racket[doc]. (Following this approach, you could also attach multiple decoders to different tags within @racket[doc].) You can, of course, embed function calls within Pollen markup. But since markup is optimized for authors, decoding is useful for operations that can or should be moved out of the authoring layer. One example is presentation and layout. For instance, @racket[detect-paragraphs] is a decoder function that lets authors mark paragraphs in their source simply by using two carriage returns. Another example is conversion of output into a particular data format. Most Pollen functions are optimized for HTML output, but one could write a decoder that targets another format. @defproc[ (decode [tagged-xexpr txexpr?] [#:txexpr-tag-proc txexpr-tag-proc (txexpr-tag? . -> . txexpr-tag?) (λ(tag) tag)] [#:txexpr-attrs-proc txexpr-attrs-proc (txexpr-attrs? . -> . txexpr-attrs?) (λ(attrs) attrs)] [#:txexpr-elements-proc txexpr-elements-proc (txexpr-elements? . -> . txexpr-elements?) (λ(elements) elements)] [#:block-txexpr-proc block-txexpr-proc (block-txexpr? . -> . xexpr?) (λ(tx) tx)] [#:inline-txexpr-proc inline-txexpr-proc (txexpr? . -> . xexpr?) (λ(tx) tx)] [#:string-proc string-proc (string? . -> . xexpr?) (λ(str) str)] [#:symbol-proc symbol-proc (symbol? . -> . xexpr?) (λ(sym) sym)] [#:valid-char-proc valid-char-proc (valid-char? . -> . xexpr?) (λ(vc) vc)] [#:cdata-proc cdata-proc (cdata? . -> . xexpr?) (λ(cdata) cdata)] [#:exclude-tags tags-to-exclude (listof symbol?) null] ) txexpr?] Recursively process a @racket[_tagged-xexpr], usually the one exported from a Pollen source file as @racket[doc]. This function doesn't do much on its own. Rather, it provides the hooks upon which harder-working functions can be hung. Recall from [future link: Pollen mechanics] that any tag can have a function attached to it. By default, the @racket[_tagged-xexpr] from a source file is tagged with @racket[root]. So the typical way to use @racket[decode] is to attach your decoding functions to it, and then define @racket[root] to invoke your @racket[decode] function. Then it will be automatically applied to every @racket[doc] during compile. For instance, here's how @racket[decode] is attached to @racket[root] in @italic{Butterick's Practical Typography}. There's not much to it — @racketblock[ (define (root . items) (decode (make-txexpr 'root '() items) #:txexpr-elements-proc detect-paragraphs #:block-txexpr-proc (compose1 hyphenate wrap-hanging-quotes nonbreaking-last-space) #:string-proc (compose1 smart-quotes smart-dashes) #:exclude-tags '(style script))) ] This illustrates another important point: even though @racket[decode] presents an imposing list of arguments, you're unlikely to use all of them at once. These represent possibilities, not requirements. For instance, let's see what happens when @racket[decode] is invoked without any of its optional arguments. @examples[#:eval my-eval (define tx '(root "I wonder" (em "why") "this works.")) (decode tx) ] Right — nothing. That's because the default value for the decoding arguments is the identity function, @racket[(λ(x)x)]. So all the input gets passed through intact unless another action is specified. The @racket[_*-proc] arguments of @racket[decode] take procedures that are applied to specific categories of elements within @racket[_txexpr]. The @racket[_txexpr-tag-proc] argument is a procedure that handles X-expression tags. @examples[#:eval my-eval (define tx '(p "I'm from a strange" (strong "namespace"))) (code:comment @#,t{Tags are symbols, so a tag-proc should return a symbol}) (decode tx #:txexpr-tag-proc (λ(t) (string->symbol (format "ns:~a" t)))) ] The @racket[_txexpr-attrs-proc] argument is a procedure that handles lists of X-expression attributes. (The @racketmodname[txexpr] module, included at no extra charge with Pollen, includes useful helper functions for dealing with these attribute lists.) @examples[#:eval my-eval (define tx '(p [[id "first"]] "If I only had a brain.")) (code:comment @#,t{Attrs is a list, so cons is OK for simple cases}) (decode tx #:txexpr-attrs-proc (λ(attrs) (cons '[class "PhD"] attrs ))) ] Note that @racket[_txexpr-attrs-proc] will change the attributes of every tagged X-expression, even those that don't have attributes. This is useful, because sometimes you want to add attributes where none existed before. But be careful, because the behavior may make your processing function overinclusive. @examples[#:eval my-eval (define tx '(div (p [[id "first"]] "If I only had a brain.") (p "Me too."))) (code:comment @#,t{This will insert the new attribute everywhere}) (decode tx #:txexpr-attrs-proc (λ(attrs) (cons '[class "PhD"] attrs ))) (code:comment @#,t{This will add the new attribute only to non-null attribute lists}) (decode tx #:txexpr-attrs-proc (λ(attrs) (if (null? attrs) attrs (cons '[class "PhD"] attrs )))) ] The @racket[_txexpr-elements-proc] argument is a procedure that operates on the list of elements that represents the content of each tagged X-expression. Note that each element of an X-expression is subject to two passes through the decoder: once now, as a member of the list of elements, and also later, through its type-specific decoder (i.e., @racket[_string-proc], @racket[_symbol-proc], and so on). @examples[#:eval my-eval (define tx '(div "Double" "\n" "toil" amp "trouble")) (code:comment @#,t{Every element gets doubled ...}) (decode tx #:txexpr-elements-proc (λ(es) (append-map (λ(e) `(,e ,e)) es))) (code:comment @#,t{... but only strings get capitalized}) (decode tx #:txexpr-elements-proc (λ(es) (append-map (λ(e) `(,e ,e)) es)) #:string-proc (λ(s) (string-upcase s))) ] So why do you need @racket[_txexpr-elements-proc]? Because some types of element decoding depend on context, thus it's necessary to handle the elements as a group. For instance, the doubling function above, though useless, requires handling the element list as a whole, because elements are being added. A more useful example: paragraph detection. The behavior is not merely a @racket[map] across each element: @examples[#:eval my-eval (define (paras tx) (decode tx #:txexpr-elements-proc detect-paragraphs)) (code:comment @#,t{Context matters. Trailing whitespace is ignored ...}) (paras '(body "The first paragraph." "\n\n")) (code:comment @#,t{... but whitespace between strings is converted to a break.}) (paras '(body "The first paragraph." "\n\n" "And another.")) (code:comment @#,t{A combination of both types}) (paras '(body "The first paragraph." "\n\n" "And another." "\n\n")) ] The @racket[_block-txexpr-proc] argument and the @racket[_inline-txexpr-proc] arguments are procedures that operate on tagged X-expressions. If the X-expression meets the @racket[block-txexpr?] test, it is processed by @racket[_block-txexpr-proc]. Otherwise, it is processed by @racket[_inline-txexpr-proc]. Thus every tagged X-expression will be handled by one or the other. Of course, if you want block and inline elements to be handled the same way, you can set @racket[_block-txexpr-proc] and @racket[_inline-txexpr-proc] to be the same procedure. @examples[#:eval my-eval (define tx '(div "Please" (em "mind the gap") (h1 "Tuesdays only"))) (define add-ns (λ(tx) (make-txexpr (string->symbol (format "ns:~a" (get-tag tx))) (get-attrs tx) (get-elements tx)))) (code:comment @#,t{div and h1 are block elements, so this will only affect them}) (decode tx #:block-txexpr-proc add-ns) (code:comment @#,t{em is an inline element, so this will only affect it}) (decode tx #:inline-txexpr-proc add-ns) (code:comment @#,t{this will affect all elements}) (decode tx #:block-txexpr-proc add-ns #:inline-txexpr-proc add-ns) ] The @racket[_string-proc], @racket[_symbol-proc], @racket[_valid-char-proc], and @racket[_cdata-proc] arguments are procedures that operate on X-expressions that are strings, symbols, valid-chars, and CDATA, respectively. Deliberately, the output contracts for these procedures accept any kind of X-expression (meaning, the procedure can change the X-expression type). @examples[#:eval my-eval (code:comment @#,t{A div with string, entity, character, and cdata elements}) (define tx `(div "Moe" amp 62 ,(cdata #f #f "3 > 2;"))) (define rulify (λ(x) '(hr))) (code:comment @#,t{The rulify function is selectively applied to each}) (print (decode tx #:string-proc rulify)) (print (decode tx #:symbol-proc rulify)) (print (decode tx #:valid-char-proc rulify)) (print (decode tx #:cdata-proc rulify)) ] Finally, the @racket[_tags-to-exclude] argument is a list of tags that will be exempted from decoding. Though you could get the same result by testing the input within the individual decoding functions, that's tedious and potentially slower. @examples[#:eval my-eval (define tx '(p "I really think" (em "italics") "should be lowercase.")) (decode tx #:string-proc (λ(s) (string-upcase s))) (decode tx #:string-proc (λ(s) (string-upcase s)) #:exclude-tags '(em)) ] The @racket[_tags-to-exclude] argument is useful if you're decoding source that's destined to become HTML. According to the HTML spec, material within a @racket[