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Racket

#lang pollen/mode racket/base
#|
We can write a pollen.rkt file in any #lang. `#lang racket` is more convenient because it loads more
libraries by default. For the same reason, `#lang racket/base` with a minimal set of libraries is
slightly faster to load. The difference here is probably negligible.
In general, the more virtuous habit is `#lang racket/base`.
`pollen/mode` is a metalanguage that adds support for Pollen-mode commands in a source file.
So instead of `#lang racket/base` we write `#lang pollen/mode racket/base`. `pollen/mode` is optional.
BTW this file is heavily commented so it can serve as a Pollen learning tool. Rather than just read
along, you are encouraged to run this project with the project server active, and make changes to this
file and see how they affect the output.
We could avoid the next `require` if we were using `#lang racket`, because these libraries would
already
be available.
|#
(require
(for-syntax racket/base racket/syntax) ; enables macros
racket/list
racket/format
racket/string
racket/function
racket/contract
racket/match
racket/system)
#|
Other libraries we'll be using.
|#
(require
sugar
txexpr
pollen/decode
pollen/tag
hyphenate
"pricing-table.rkt")
#|
Everything provided from a pollen.rkt is automatically available to Pollen source files in the
same directory or subdirectories (unless superseded by another pollen.rkt, as in the "fonts" subdir)
Note that `all-defined-out` would only export the definitions that are created in this file. To make
imported definitions available too, we need to re-export them with `all-from-out`.
|#
(provide (all-defined-out) (all-from-out "pricing-table.rkt"))
#|
Pollen recognizes the environment variable POLLEN, which can take any value.
For instance, instead of starting the project server with
raco pollen start
You could do
POLLEN=SOME-STRING raco pollen start
And "SOME-STRING" would be loaded into the POLLEN environment variable.
We can retrieve this value with `(getenv "POLLEN")`. It can be used to create branching behavior.
Here, we'll create a `dev-mode?` test and use it later to change the behavior of certain functions.
|#
(define (dev-mode?)
(equal? (getenv "POLLEN") "DEV"))
#|
Definitions in a pollen.rkt can be functions or values.
Here are a couple values.
|#
(define content-rule-color "#444") ; for CSS classes
(define buy-url "http://typo.la/oc") ; link to buy the Typography for Lawyers paperback
#|
TAG FUNCTIONS
|#
#|
`link`: make a hyperlink
In Pollen notation, we'll invoke the tag function like so:
◊link[url]{text of link}
◊link[url #:class "name"]{text of link}
This will become, in Racket notation:
(link url "text of link")
(link url #:class "name" "text of link")
The definition of the tag function will follow this syntax.
Learning to see the duality of Pollen & Racket notation is a necessary part of the learning curve.
Pollen notation is optimized for embedding commands in text.
Racket notation is optimized for writing code.
The relationship between the two, however, is dependable and consistent.
By contrast, most "template languages" either make you use syntax that's different from the
underlying language, or restrict you to a subset of commands.
Whereas any Racket command can be expressed in Pollen notation. So having two equivalent notation
systems ultimately lets you do more, not less.
|#
#|
The definition of `link` follows the arguments above.
`url` is a mandatory argument.
`class` is a keyword argument (= must be introduced with #:class) and also optional (if it's not
provided, it will default to #f).
`xs` is a rest argument, as in "put the rest of the arguments here." Most definitions of
tag functions should end with a rest argument. Why? Because in Pollen notation, the `{text ...}`
in `◊func[arg]{text ...}` can return any number of arguments. Maybe one (e.g., if `text` is a word)
or maybe more (e.g, if `text ...` is a multiline block).
If you DON'T use a rest argument, and pass multiple text arguments to your tag function, you will get
an error (namely an "arity error", which means the function got more arguments than it expected).
The result of our tag function will be a tagged X-expression that looks like this:
'(a ((href "url")) "text to link")
'(a ((href "url")(class "name")) "text to link")
X-expressions and tagged X-expressions are introduced in the Pollen docs.
|#
(define (link url #:class [class-name #f] . text-args)
(define no-text-arguments? (empty? text-args))
(if no-text-arguments?
(let ([text-to-link url])
;; if we don't have any text to link, use `url` as the link text too.
(link #:class class-name url text-to-link))
;; otherwise, create the basic tagged X-expression,
;; and then add the `url` and (maybe) `class` attributes.
;; `let*` is the idiomatic Racket way to mutate a variable.
;; (Spoiler alert: you're not really mutating, you're creating copies.)
;; You could also use `set!` — not wrong, but not idiomatic.
(let*
([link-tx (make-txexpr 'a empty text-args)]
;; `attr-set` is from the `txexpr` module. It updates an attribute value
;; and returns an updated X-expression.
[link-tx (attr-set link-tx 'href url)]
[link-tx (if class-name
(attr-set link-tx 'class class-name)
link-tx)])
link-tx)))
#|
Making tagged X-expressions (txexprs)
In a "pollen.rkt" file you'll be making a lot of tagged X-expressions (txexprs for short).
A txexpr is just a Racket list, so you can make one with any of Racket's list-making functions
(which are plentiful). Let's run through a few of them, so they start to become familiar.
Suppose we want to generate the txexpr '(div ((class "big")) "text"). Here are some ways to do it.
1) `make-txexpr`
A utility function from the `txexpr` module. We used it in the `link` function above.
The major advantage of `make-txexpr` is that it will raise an error if your arguments are invalid
types for a tagged X-expression.
|#
(check-txexprs-equal? (make-txexpr 'div '((class "big")) '("text"))
'(div ((class "big")) "text"))
#|
The second and third arguments to `make-txexpr` are lists, so you can use any list notation.
If your txexpr doesn't have attributes, you can pass `empty` or `null` for the second argument.
|#
(check-txexprs-equal? (make-txexpr 'div (list '(class "big")) (list "text"))
'(div ((class "big")) "text"))
#|
2) `list` and `list*`
`list*` is particularly useful for making txexprs, because it automatically splices the last argument.
|#
(check-txexprs-equal? (list 'div '((class "big")) "text")
'(div ((class "big")) "text"))
(check-txexprs-equal? (list* 'div '((class "big")) '("text"))
'(div ((class "big")) "text"))
#|
3) `cons`
All lists are ultimately made of `cons` cells.
So you can make txexprs with it too, though it's more cumbersome than the other methods.
In most cases, `list*` is clearer & more flexible (`cons` can only take two arguments;
`list*` can take any number)
|#
(check-txexprs-equal? (cons 'div (cons '((class "big")) (cons "text" empty)))
'(div ((class "big")) "text"))
(check-txexprs-equal? (cons 'div (list '((class "big")) "text"))
'(div ((class "big")) "text"))
#|
4) `quasiquote`
As the name suggests, quasiquote works like quote, but lets you "unquote" variables within.
Quasiquote notation is pleasingly compact for simple cases, but can be unruly for complex ones.
The unquote operator (,) puts a variable's value into the list.
The unquote splicing operator (,@) does the same thing, but if the variable holds a list of items,
it merges those items into the list (i.e., does not leave them as a sublist).
|#
(check-txexprs-equal? (let ([tag 'div]
[attrs '((class "big"))]
[elements '("text")])
; we unquote `attrs` because we want them as a sublist
; but we splice `elements` because we don't want them in a sublist
`(,tag ,attrs ,@elements))
'(div ((class "big")) "text"))
#|
UNIT TESTS
Testing, as always, is optional, but strongly recommended. Unit tests are little one-line tests that
prove your function does what it says. As you refactor and reorganize your code, your unit tests will
let you know if you broke anything.
You can make unit tests with the `rackunit` library. Though you can put your unit tests in a separate
source file, I generally prefer to put them close to the function that they're testing. (For details
on the testing functions used below, see the docs for `rackunit`)
The ideal way to do this is with a `test` submodule. The code in a `test` submodule will only be used
a) when you run the file in DrRacket or
b) when `raco test` runs the file.
Otherwise, it is ignored.
We'll use the `module+` syntax for this. As the name suggests, `module+` creates a submodule that
incorporates everything else already in the source file. Moreover, all of our `module+ test` blocks
will be combined into a single submodule.
|#
(module+ test
(require rackunit) ;; always include this at the start of the test submodule
;; We use `check-txexprs-equal?` rather than `check-equal?` because it's a little more lenient:
;; it allows the attributes of two txexprs to be in a different order,
;; yet still be considered equal (because ordering of attributes is not semantically significant).
(check-txexprs-equal? (link "http://foo.com" "link text")
'(a ((href "http://foo.com")) "link text"))
;; The last test was fine, but it can be even better if we use a Pollen-mode command on the left.
;; That way, we can directly compare the command as it appears in Pollen input
;; with how it appears in the output.
(check-txexprs-equal? ◊link["http://foo.com"]{link text}
'(a ((href "http://foo.com")) "link text"))
;; It's wise to test as many valid input situations as you can.
(check-txexprs-equal? ◊link["http://foo.com" #:class 'main]{link text}
'(a ((href "http://foo.com")(class "main")) "link text"))
(check-txexprs-equal? ◊link["http://foo.com"]
'(a ((href "http://foo.com")) "http://foo.com"))
;; Strictly speaking, you could also write the last Pollen command like so:
(check-txexprs-equal? ◊link{http://foo.com} '(a ((href "http://foo.com")) "http://foo.com"))
;; That's not wrong. But in the interests of code readability,
;; I like to reserve the curly brackets in a Pollen command
;; for material that I expect to see displayed in the output
;; (e.g., textual and other content),
;; and use the square brackets for the other arguments.
;; You can also check that errors arise when they should.
;; Note that when testing for exceptions, you need to wrap your test expression in a function
;; (so that its evaluation can be delayed, otherwise you'd get the error immediately.)
;; The `(λ _ expression)` notation is a simple way.
;; (The `_` is the idiomatic way to notate something that will be ignored, in this case arguments.)
(check-exn exn:fail? (λ _ ◊link[])) ; no arguments
(check-exn exn:fail? (λ _ ◊link[#:invalid-keyword 42])) ; invalid keyword argument
(check-exn exn:fail? (λ _ ◊link[#f]))) ; invalid argument
;; For the sake of brevity, I'm going to write just one test for the remaining functions.
;; But you're encouraged to add more tests (or break the existing ones and see what happens).
#|
The next three tag functions are just convenience variations of `link`.
But they involve some crafty (and necessary) uses of `apply`.
|#
#|
`buy-book-link`: makes a link with a particular URL.
Notice that we have to use `apply` to correctly pass our `text-args` rest argument to `link`.
Why? Because `link` expects its text arguments to look like this:
(link url text-arg-1 text-arg-2 ...)
Not like this:
(link url (list text-arg-1 text-arg-2 ...))
But that's what will happen if we just do `(link text-args)`, and `link` will complain. (Try it!)
The role of `apply` is to take a list of arguments and append them to the end of the function call, so
(apply link url (list text-arg-1 text-arg-2 ...))
Is equivalent to:
(link url text-arg-1 text-arg-2 ...)
|#
(define (buy-book-link . text-args)
(apply link buy-url text-args))
(module+ test
;; notice that we use `buy-url` in our test result.
;; That way, if we change the value of `buy-url`, the test won't break.
(check-txexprs-equal? ◊buy-book-link{link text} `(a ((href ,buy-url)) "link text")))
#|
`buylink`: creates a link styled with the "buylink" class.
`home-link`: creates a link styled with the "home-link" class.
The difference here is that we're not providing a specific URL. Rather, we want to pass through
whatever URL we get from the Pollen source. So we add a `url` argument.
|#
(define (buylink url . text-args)
(apply link url #:class "buylink" text-args))
(module+ test
(check-txexprs-equal? ◊buylink["http://foo.com"]{link text}
'(a ((href "http://foo.com")(class "buylink")) "link text")))
(define (home-link url . text-args)
(apply link url #:class "home-link" text-args))
(module+ test
(check-txexprs-equal? ◊home-link["http://foo.com"]{link text}
'(a ((href "http://foo.com")(class "home-link")) "link text")))
#|
BTW we could also be let the rest argument capture the URL,
and just pass everything through with `apply`, which will work the same way:
(define (buylink . url-and-text-args)
(apply link #:class "buylink" url-and-text-args))
The other definition is more readable and explicit, however.
|#
#|
`image`: make an img tag
We proceed as we did with `link`. But in this case, we don't need a rest argument
because this tag function doesn't accept text arguments.
"Right, but shouldn't you use a rest argument just in case?" It depends on how you like errors
to be handled. You could capture the text arguments with a rest argument and then just silently
dispose of them. But this might be mysterious to the person editing the Pollen source (whether you
or someone else). "Where did my text go?"
Whereas if we omit the rest argument, and try to pass text arguments anyhow, `image` will immediately
raise an error, letting us know that we're misusing it.
|#
(define (image src #:width [width "100%"] #:border [border? #t])
(define img-tag (attr-set* '(img) 'style (format "width: ~a" width)
'src (build-path "images" src)))
(if border?
(attr-set img-tag 'class "bordered")
img-tag))
(module+ test
(check-txexprs-equal? ◊image["pic.gif"]
'(img ((style "width: 100%") (class "bordered")(src "images/pic.gif"))))
(check-txexprs-equal? ◊image[#:border #f "pic.gif"]
'(img ((style "width: 100%")(src "images/pic.gif"))))
(check-txexprs-equal? ◊image[#:width "50%" "pic.gif"]
'(img ((style "width: 50%")(class "bordered")(src "images/pic.gif")))))
#|
`div-scale`: wrap tag in a 'div' with a scaling factor
◊div-scale[.75]{text here ...}
|#
(define (div-scale factor . text-args)
; use `format` on factor because it might be either a string or a number
(define base (make-txexpr 'div null text-args))
(attr-set base 'style (format "width: ~a" factor)))
(module+ test
(check-txexprs-equal? ◊div-scale[.5]{Hello} '(div ((style "width: 0.5")) "Hello")))
#|
`font-scale`: wrap tag in a 'span' with a relative font-scaling factor
◊font-scale[.75]{text here ...}
|#
(define (font-scale ratio . text-args)
(define base (make-txexpr 'span null text-args))
(attr-set base 'style (format "font-size: ~aem" ratio)))
(module+ test
(check-txexprs-equal? ◊font-scale[.75]{Hello}
'(span ((style "font-size: 0.75em")) "Hello")))
#|
`home-image`: make an image with class "home-image"
◊home-image[image-path]
|#
(define (home-image image-path)
(attr-set (image image-path) 'class "home-image"))
(module+ test
(check-txexprs-equal? ◊home-image["pic.gif"]
'(img ((style "width: 100%") (class "home-image") (src "images/pic.gif")))))
#|
`home-overlay`: create nested divs where the text sits atop a background image.
◊home-overlay[image-name]{text}
This is an example of how fiddly HTML chores can be encapsulated / hidden inside a tag function.
This makes your source files tidier.
It also makes it possible to change the fiddly HTML markup from one central location.
|#
(define (home-overlay img-path . text-args)
`(div ((class "home-overlay")(style ,(format "background-image: url('~a')" img-path)))
(div ((class "home-overlay-inner")) ,@text-args)))
(module+ test
(check-txexprs-equal? ◊home-overlay["pic.gif"]{Hello}
'(div ((class "home-overlay") (style "background-image: url('pic.gif')"))
(div ((class "home-overlay-inner")) "Hello"))))
#|
`glyph`: create a span with the class "glyph".
◊glyph{text}
Here, I'll use `make-default-tag-function`, which is an easy way to make a simple tag function.
Any keywords passed in will be propagated to every use of the tag function.
|#
(define glyph (make-default-tag-function 'span #:class "glyph"))
(module+ test
(check-txexprs-equal? ◊glyph{X}
'(span ((class "glyph")) "X"))
(check-txexprs-equal? ◊glyph[#:id "top"]{X}
'(span ((class "glyph")(id "top")) "X")))
#|
`image-wrapped`: like `image` but with some extra attributes
◊image-wrapped[img-path]
|#
(define (image-wrapped img-path)
(attr-set* (image img-path) 'class "icon" 'style "width: 120px;" 'align "left"))
(module+ test
(check-txexprs-equal? ◊image-wrapped{my-path}
'(img ((class "icon")
(style "width: 120px;")
(align "left")
(src "images/my-path")))))
#|
`detect-list-items`: helper function for other tag functions that make HTML lists.
The idea is to automatically convert a sequence of three (or more) linebreaks
into a new list item (i.e., <li> tag).
Why three? Because later on, we'll make one linebreak = new line and two linebreaks = new paragraph.
This function will be used within a `decode` function (more on that below)
in a position where it will be passed a list of X-expresssion elements,
and needs to return a list of X-expression elements.
The idiomatic Racket way to enforce requirements on input & output values is with a function contract.
For simplicity, I'm not using them here.
|#
(define (detect-list-items elems)
;; We need to do some defensive preprocessing here.
;; Our list of elements could contain sequences like "\n" "\n" "\n"
;; that should mean the same thing as "\n\n\n".
;; So we combine adjacent newlines with `merge-newlines`.
(define elems-merged (merge-newlines elems))
;; Then, a list item break is denoted by any element that matches three or more newlines.
(define (list-item-break? elem)
(define list-item-separator-pattern (regexp "\n\n\n+"))
;; Python people will object to the `(string? elem)` test below
;; as a missed chance for "duck typing".
;; You can do duck typing in Racket (see `with-handlers`) but it's not idiomatic.
;; IMO this is wise. Duck typing is an anti-pattern: it substitutes an explicit, readable test
;; for an implicit test ("I know if such-and-such isn't true, then a certain error will arise."
(and (string? elem) (regexp-match list-item-separator-pattern elem)))
;; `filter-split` will divide a list into sublists based on a certain test.
;; the result will be a list of lists, each representing the contents of an 'li tag.
(define list-of-li-elems (filter-split elems-merged list-item-break?))
;; We convert any paragraphs that are inside the list items.
(define list-of-li-paragraphs (map (λ(li) (detect-paragraphs li #:force? #t)) list-of-li-elems))
;; Finally we wrap each of these lists of paragraphs in an 'li tag.
(define li-tag (make-default-tag-function 'li))
(map (λ(lip) (apply li-tag lip)) list-of-li-paragraphs))
(module+ test
(check-equal? (detect-list-items '("foo" "\n" "bar")) ; linebreak, not list item break
'((li (p "foo" (br) "bar"))))
(check-equal? (detect-list-items '("foo" "\n" "\n" "bar")) ; paragraph break, not list item break
'((li (p "foo") (p "bar"))))
(check-equal? (detect-list-items '("foo" "\n" "\n" "\n" "bar")) ; list item break
'((li (p "foo")) (li (p "bar"))))
(check-equal? (detect-list-items '("foo" "\n\n\n" "bar")) ; list item break, concatenated
'((li (p "foo")) (li (p "bar"))))
(check-equal? (detect-list-items '("foo" "\n" "\n" "\n\n\n" "bar")) ; list item break
'((li (p "foo")) (li (p "bar")))))
#|
`make-list-function`: helper function that makes other tag functions that make lists.
(make-list-function 'list-tag-name)
(make-list-function 'list-tag-name '((attr-key "attr-value") ...))
In Racket you will often see functions that make other functions.
This is a good way to avoid making a bunch of functions that have small variations.
One way to write this function is like so:
(define (listifier . args)
(list* tag attrs (detect-list-items args)))
listifier
That is, explicitly define a new function called `listifier` and then return that function.
That's the best way to do it in many programming languages.
In Racket, it's not wrong, but you should feel comfortable
with the idea that any function can be equivalently expressed in lambda notation,
which is the more Rackety idiom.
The code below has the same meaning, but without having to `define` an intermediate variable.
|#
(define (make-list-function tag [attrs empty])
(λ args (list* tag attrs (detect-list-items args))))
#|
Now we can define `bullet-list` and `numbered-list` using our helper function.
|#
(define bullet-list (make-list-function 'ul))
(define numbered-list (make-list-function 'ol))
(module+ test
(check-txexprs-equal? ◊bullet-list{foo} '(ul (li (p "foo"))))
(check-txexprs-equal? ◊numbered-list{foo} '(ol (li (p "foo")))))
#|
`btw`: make the "By the Way" list at the bottom of many pages,
e.g. http://typographyforlawyers.com/what-is-typography.html
◊btw{text ...}
Another example of using a tag function to handle fiddly HTML markup.
The `btw` tag expands to an HTML list, which we will then crack open and add a headline div.
|#
(define (btw . text-args)
(define btw-tag-function (make-list-function 'ul '((class "btw"))))
;; Why is `apply` needed here? See the explanation for `buy-book-link` above.
(define btw-list (apply btw-tag-function text-args))
(list* (get-tag btw-list)
(get-attrs btw-list)
'(div ((id "btw-title")) "by the way")
(get-elements btw-list)))
(module+ test
(check-txexprs-equal? ◊btw{foo
bar}
'(ul ((class "btw"))
(div ((id "btw-title")) "by the way")
(li (p "foo"))
(li (p "bar")))))
#|
`xref`: create a styled cross-reference link, with optional destination argument.
◊xref{target}
◊xref["url"]{target}
For this tag function, we will assume that target is a single text argument,
because that's how it will be used.
But to be safe, we'll raise an arity error if we get too many arguments.
|#
(define xref
;; What makes this function a little tricky is that the url argument is optional,
;; but if it appears, it appears first.
;; This is a good job for `case-lambda`, which lets you define separate branches for your function
;; depending on the total number of arguments provided.
(case-lambda
;; one argument: must be a target. Note the Rackety recursive technique here:
;; we'll create a second argument and then call `xref` again.
[(target) (xref (target->url target) target)]
;; two arguments: must be a url followed by a target.
[(url target) (apply attr-set* (link url target) 'class "xref" no-hyphens-attr)]
;; more than two arguments: raise an arity error.
[more-than-two-args (apply raise-arity-error 'xref (list 1 2) more-than-two-args)]))
(module+ test
(check-txexprs-equal? ◊xref{target}
`(a ((class "xref") (href "target.html") ,no-hyphens-attr) "target"))
(check-txexprs-equal? ◊xref["url"]{target}
`(a ((class "xref") (href "url") ,no-hyphens-attr) "target"))
(check-exn exn:fail:contract:arity? (λ _ (xref "url" "target" "spurious-third-argument"))))
#|
`target->url`: convert the target text of an xref into a url.
This function depends on my commitment to name my source files in a logical, predictable way,
e.g., "Why Does Typography Matter?" becomes "why-does-typography-matter.html".
If you needed to associate targets with URLs arbitrarily, you could store the targets and URLs
in an association list or hashtable.
I do it this way so that it's easy to add new pages and xrefs, without the extra housekeeping step
The name of the source file for a page is determined by its title.
|#
(define (target->url target)
(define nonbreaking-space (~a #\u00A0))
(let* ([xn target]
[xn (string-trim xn "?")] ; delete a question mark at the end
[xn (string-downcase xn)] ; put string in all lowercase
[xn (regexp-replace* #rx"é" xn "e")] ; remove accented é
[xn (if (regexp-match #rx"^foreword" xn) "foreword" xn)] ; special rule for foreword
[xn (if (regexp-match #rx"^table of contents" xn) "toc" xn)] ; special rule for toc
[xn (string-replace xn nonbreaking-space "-")] ; replace nbsp with hyphen
[xn (string-replace xn " " "-")]) ; replace word space with hyphen
(format "~a.html" xn)))
(module+ test
(check-equal? (target->url "foo?") "foo.html")
(check-equal? (target->url "FOO") "foo.html")
(check-equal? (target->url "foé") "foe.html")
(check-equal? (target->url "Foreword Lengthy Title") "foreword.html")
(check-equal? (target->url "Table of Contents and Other Nonsense") "toc.html")
(check-equal? (target->url "Nonbreaking Space and Spaces") "nonbreaking-space-and-spaces.html"))
#|
`xref-font`: special version of `xref` for the fontrec directory
|#
(define (xref-font font-name)
(xref (format "fontrec/~a" (target->url font-name)) font-name))
#|
`no-hyphens-attr`: an attribute we'll use to signal that some X-expression should not be hyphenated.
|#
(define no-hyphens-attr '(hyphens "none"))
#|
`define-heading`: macro for defining a function that makes a heading.
This could also be done with `make-default-tag-function`. And as a rule of thumb, it's wise to reserve
macros for the times you can't avoid using them. Otherwise, use a function.
We'll bend that rule here because this is a quick & easy example macro. What makes it suitable to be
handled as a macro is that we want to use the name of the identifier (for instance 'topic') as an
argument to the function. Ordinarily we can't do that, but with a macro, we can.
`define-syntax-rule` is the easiest macro form: essentially you're writing a code template
with arguments that will be filled in when you invoke the macro.
|#
(define-syntax-rule (define-heading heading-name tag)
; first, heading-name is used as an identifier
(define heading-name
; then it's used as a symbol that is converted to a string.
(make-default-tag-function tag #:class (symbol->string 'heading-name))))
(define-heading topic 'h3)
(define-heading subhead 'h3)
(define-heading font-headline 'h3)
(define-heading section 'h2)
(define-heading chapter 'h1)
(module+ test
(check-txexprs-equal? ◊topic{foo}
'(h3 ((class "topic")) "foo"))
(check-txexprs-equal? ◊subhead{foo}
'(h3 ((class "subhead")) "foo"))
(check-txexprs-equal? ◊font-headline{foo}
'(h3 ((class "font-headline")) "foo"))
(check-txexprs-equal? ◊section{foo}
'(h2 ((class "section")) "foo"))
(check-txexprs-equal? ◊chapter{foo}
'(h1 ((class "chapter")) "foo")))
#|
`define-heading-from-metas`: macro for defining a function that makes a heading
by relying on data in the metas.
This macro relies on `syntax-case` rather than `define-syntax-rule`.
It's a little more complicated, but also more flexible (and more idiomatic in Racket).
`define-syntax-rule` is actually a special simplified version of `syntax-case`.
The best advice on learning macros is to start with `syntax-case`, because you can't live without it.
Good tutorial: http://www.greghendershott.com/fear-of-macros/pattern-matching.html
Otherwise this macro is similar to `define-heading`, except that we want to introduce a new identifier
based on the name given to the macro. So if we pass `topic` to the macro, it will define
an identifier called `topic-from-metas`. You can't do that with `define-syntax-rule`.
For fun, I used Pollen notation inside the macro just to show you that it will work.
|#
(define meta-key-for-page-title 'title)
(define-syntax (define-heading-from-metas stx)
(syntax-case stx ()
[(_ heading-name)
(with-syntax ([heading-from-metas (format-id stx "~a-from-metas" #'heading-name)])
#'(define (heading-from-metas metas)
◊heading-name{(hash-ref metas meta-key-for-page-title)}))]))
(define-heading-from-metas topic)
(define-heading-from-metas section)
(define-heading-from-metas chapter)
(module+ test
(let ([my-fake-metas (hash 'title "Fake Title" 'white "noise")])
(check-txexprs-equal? ◊topic-from-metas[my-fake-metas]
'(h3 ((class "topic")) "Fake Title"))
(check-txexprs-equal? ◊section-from-metas[my-fake-metas]
'(h2 ((class "section")) "Fake Title"))
(check-txexprs-equal? ◊chapter-from-metas[my-fake-metas]
'(h1 ((class "chapter")) "Fake Title"))))
#|
`hanging-topic`: convert a topic + subhead into one HTML markup unit
◊hanging-topic["Topic name"]{One-line explanation}
|#
(define (hanging-topic topic-xexpr . text-args)
(make-txexpr 'div (list '(class "hanging-topic") no-hyphens-attr)
(list topic-xexpr (list* 'p (list no-hyphens-attr) text-args))))
(module+ test
(check-txexprs-equal? ◊hanging-topic["Topic name"]{One-line explanation}
`(div ((class "hanging-topic") ,no-hyphens-attr) "Topic name"
(p (,no-hyphens-attr) "One-line explanation"))))
#|
`quick-table`: make little HTML tables with simplified notation
◊quick-table{heading left | heading center | heading right
upper left | upper center | upper right
lower left | lower center | lower right}
In HTML, wrapping every paragraph in <p> tags is a terrible and dull task.
But formatting tables is even worse.
This function lets you make simple tables using "|" to signify columns,
and line breaks to signify rows.
Let's uncork a few more whizzy Racket commands while we're at it.
This function assumes that each row has the same number of columns.
You could improve it to fill in blank cells in rows that need them.
|#
(define (quick-table . text-args)
;; In Pollen, a multiline text-args block arrives as a list of lines and linebreak characters.
;; (A situation we already encountered in `detect-list-items`.)
(define rows-of-text-cells
(let ([text-rows (filter-not whitespace? text-args)]) ; throw out the linebreak characters
;; `for/list` is very handy: a `for` loop that gathers the results into a list.
;; Think of it as a more flexible version of `map`.
(for/list ([text-row (in-list text-rows)])
;; the cells are delimited within a row by "|", so split on this char
(for/list ([text-cell (in-list (string-split text-row "|"))])
(string-trim text-cell))))) ; trim remaining whitespace from cell text
;; Racket's `match` functions are very useful.
;; Among other things, they can be used for Python-style data unpacking.
;; The expression on the right will produce three tag functions;
;; the `match-define` assigns them to three new identifiers.
(match-define (list tr-tag td-tag th-tag) (map make-default-tag-function '(tr td th)))
;; now we'll take our rows of text cells and apply cell-level HTML tags.
;; the first row will get 'th tags; the other rows get 'td tags.
(define html-rows
;; another use of `match`. Notice how this `cons` is used to separate a list into parts ...
(match-let ([(cons header-row other-rows) rows-of-text-cells])
;; ... whereas this `cons` is used to combine parts into a list
(cons (map th-tag header-row)
(for/list ([row (in-list other-rows)])
(map td-tag row)))))
;; With the cells tagged up, add the row tags and finally the table tag.
;; Notice that we use `apply` with `tr-tag` to unpack the list of cells in each html-row.
;; Remember that `apply` does something very simple:
;; Converts an expression of the form `(apply func (list arg1 arg2 ...))`
;; Into `(func arg1 arg2 ...)`
(cons 'table (for/list ([html-row (in-list html-rows)])
(apply tr-tag html-row))))
(module+ test
(check-txexprs-equal?
(quick-table "heading-one | heading-two" "\n"
" three | four" "\n"
"five | six ")
'(table (tr (th "heading-one") (th "heading-two"))
(tr (td "three") (td "four"))
(tr (td "five") (td "six")))))
#|
`pdf-thumbnail-link`: create a thumbnail of a PDF that links to the PDF
This function will only work properly if you have `sips` on your system
(command-line image-processing program, included with OS X).
This shows how you can fold other kinds of project housekeeping into Pollen commands.
Here, the function generates the thumbnail it needs when the page is compiled.
One disadvantage of this approach is that the thumbnail will *always* be generated on recompile,
though you could put in some logic to avoid this (e.g., check the modification date of the PDF).
In this case, `sips` is fast enough that it's not bothersome.
|#
(define (pdf-thumbnail-link pdf-pathstring)
(define img-extension "gif")
(define img-pathstring (->string (add-ext (remove-ext pdf-pathstring) img-extension)))
(define sips-command
(format "sips -Z 2000 -s format ~a --out '~a' '~a' > /dev/null"
img-extension img-pathstring pdf-pathstring))
◊link[pdf-pathstring]{(if (system sips-command)
`(img ((src ,img-pathstring)))
;; usually one would raise an error on the next line,
;; but for instructional purposes, we'll have a graceful fail
"sips not available")})
#|
A few convenience variants of `pdf-thumbnail-link`
|#
(define (pdf-thumbnail-link-from-metas metas)
(define-values (dir fn _) (split-path (add-ext (remove-ext* (hash-ref metas 'here-path)) "pdf")))
(pdf-thumbnail-link (->string fn)))
(define (before-and-after-pdfs base-name)
`(div
(div ((class "pdf-thumbnail"))
"before" (br)
,(pdf-thumbnail-link (format "pdf/sample-doc-~a-before.pdf" base-name)))
(div ((class "pdf-thumbnail"))
"after" (br)
,(pdf-thumbnail-link (format "pdf/sample-doc-~a-after.pdf" base-name)))))
(define (alternate-after-pdf base-name)
`(div ((class "pdf-thumbnail"))
"after (alternate)" (br)
,(pdf-thumbnail-link (format "pdf/sample-doc-~a-after-alternate.pdf" base-name))))
#|
`root`: decode page content
In a Pollen markup source, the output is a tagged X-expression that starts with `root`:
(root (div ((class "headline")) "Page title") ...)
Recall that every Pollen tag calls a function with the same name (if it exists, otherwise it just
becomes a tag). This is also true of `root`.
`root` has slightly special status inasmuch as it is the top tag of the X-expression,
and thus the last tag function that will get called. Therefore, `root` is a good place to put any
processing that should happen once all the page content has been filled in.
Often, you'll want to use a `decode` function, which can recursively perform different kinds of
processing on different types of page elements.
|#
(define (root . elems)
;; We will do the decoding in two steps.
;; Detect paragraphs first so that they're treated as block-txexprs in next phase.
(define elements-with-paragraphs (decode-elements elems #:txexpr-elements-proc detect-paragraphs))
;; Then do the rest of the decoding normally.
(list* 'div '((id "doc"))
(decode-elements elements-with-paragraphs
#:block-txexpr-proc hyphenate-block
#:string-proc (compose1 make-quotes-hangable
fix-em-dashes
smart-quotes)
#:exclude-tags '(style script))))
#|
`hyphenate-block`: helper function for root decoder
|#
(define (hyphenate-block block-tx)
;; The basic `hyphenate` function comes from the `hyphenate` module.
;; We could attach `hyphenate` to our decoder as a string processor rather than block processor.
;; But we want to be able to handle our "no-hyphens" flag (aka `no-hyphens-attr`).
;; So we want to look at blocks, not strings.
(define (no-hyphens? tx)
(or (member (get-tag tx) '(th h1 h2 h3 h4 style script)) ; don't hyphenate these, no matter what
(member no-hyphens-attr (get-attrs tx)))) ; also don't hyphenate blocks with `no-hyphens-attr`
(hyphenate block-tx
#:min-left-length 3
#:min-right-length 3
#:omit-txexpr no-hyphens?))
(module+ test
(check-txexprs-equal? (hyphenate-block `(div "snowman" (span (,no-hyphens-attr) "snowman")))
`(div "snow\u00ADman" (span (,no-hyphens-attr) "snowman"))))
#|
`make-quotes-hangable`: perform tricky processing on quotation marks.
Because I'm a typography snob I like to push quotation marks into the margin a little bit
when they appear at the left edge of a line (aka "hanging quotes").
This function just wraps left-hand quote marks in two little tags ("push" and "pull")
that I can then manipulate in CSS to get the effect.
|#
(define (make-quotes-hangable str)
;; using `regexp-match*` with #:gap-select? makes it act like a funny kind of string splitter
(define substrs (regexp-match* #px"\\s?[“‘]" str #:gap-select? #t))
(if (= (length substrs) 1) ; no submatches
(car substrs)
(cons 'quo (append-map (λ(str)
(let ([strlen (string-length str)])
(if (> strlen 0)
(case (substring str (sub1 strlen) strlen)
[("") (list '(squo-push) `(squo-pull ,str))]
[("") (list '(dquo-push) `(dquo-pull ,str))]
[else (list str)])
(list str)))) substrs))))
(module+ test
(check-txexprs-equal? (make-quotes-hangable "“Who is it?”")
'(quo "" (dquo-push) (dquo-pull "") "Who is it?”")))
#|
`fix-em-dashes`: helper function for root decoder
When I type an em dash in my sources, I will often leave a space around it,
but I don't want spaces in the output, so this function removes them.
|#
(define (fix-em-dashes str)
;; \u00A0 = nbsp, \u2009 = thinsp (neither included in \s)
(let* ([str (regexp-replace* #px"(?<=\\w)[\u00A0\u2009\\s]—" str "")]
[str (regexp-replace* #px"—[\u00A0\u2009\\s](?=\\w)" str "")])
str))
(module+ test
(check-equal? (fix-em-dashes "Hey — you!") "Hey—you!")
(check-equal? (fix-em-dashes "Hey—you!") "Hey—you!"))
#|
`capitalize-first-letter`: utility function for use in HTML templates.
|#
(define (capitalize-first-letter str)
(regexp-replace #rx"^." str string-upcase))
(module+ test
(check-equal? (capitalize-first-letter "foo dog") "Foo dog"))
#|
Miscellaneous tag functions. Obvious at this point what they do.
|#
(define omission (make-default-tag-function 'div #:class "omission"))
(define mono (make-default-tag-function 'span #:class "mono"))
(define font-details (make-default-tag-function 'div #:class "font-details"))
(define mb-font-specimen
(make-default-tag-function 'div #:class "mb-font-specimen" #:contenteditable "true"))
(define (margin-note . xs)
`(div ((class "margin-note") ,no-hyphens-attr) ,@xs))
(define os (make-default-tag-function 'span #:class "os"))
(define (gap [size 1.5])
`(div ((style ,(format "height: ~arem" size)))))
(define (center . xs)
`(div ((style "text-align:center")) ,@xs))
(define (indented #:hyphenate [hyphenate #t] . xs)
`(p ((class "indented"),@(if (not hyphenate) (list no-hyphens-attr) null)) ,@xs))
(define caption-runin (make-default-tag-function 'span #:class "caption-runin"))
(define caption (make-default-tag-function 'span #:class "caption"))
(define (captioned name . xs)
`(table ((class "captioned indented"))
(tr (td ((style "text-align:left")) ,@xs) (td ,(caption name)))))