2.5.3 New markup command definition

This section discusses the definition of new markup commands.


Markup command definition syntax

New markup commands can be defined using the define-markup-command Scheme macro, at top-level.

 
(define-markup-command (command-name layout props arg1 arg2 …)
    (arg1-type? arg2-type? …)
    [ #:properties ((property1 default-value1)
                    …) ]
    [ #:as-string expression ]
  …command body…)

The arguments are

command-name

the markup command name

layout

the ‘layout’ definition.

props

a list of associative lists, containing all active properties.

argi

ith command argument

argi-type?

a type predicate for the ith argument

If the command uses properties from the props arguments, the #:properties keyword can be used to specify which properties are used along with their default values.

Arguments are distinguished according to their type:

There is no limitation on the order of arguments (after the standard layout and props arguments). However, markup functions taking a markup as their last argument are somewhat special as you can apply them to a markup list, and the result is a markup list where the markup function (with the specified leading arguments) has been applied to every element of the original markup list.

Since replicating the leading arguments for applying a markup function to a markup list is cheap mostly for Scheme arguments, you avoid performance pitfalls by just using Scheme arguments for the leading arguments of markup functions that take a markup as their last argument.

Markup commands have a rather complex life cycle. The body of a markup command definition is responsible for converting the arguments of the markup command into a stencil expression which is returned. Quite often this is accomplished by calling the interpret-markup function on a markup expression, passing the layout and props arguments on to it. Those arguments are usually only known at a very late stage in typesetting. Markup expressions have their components assembled into markup expressions already when \markup in a LilyPond expression or the markup macro in Scheme is expanded. The evaluation and typechecking of markup command arguments happens at the time \markup/markup are interpreted.

But the actual conversion of markup expressions into stencil expressions by executing the markup function bodies only happens when interpret-markup is called on a markup expression.


On properties

The layout and props arguments of markup commands bring a context for the markup interpretation: font size, line width, etc.

The layout argument allows access to properties defined in paper blocks, using the ly:output-def-lookup function. For instance, the line width (the same as the one used in scores) is read using:

(ly:output-def-lookup layout 'line-width)

The props argument makes some properties accessible to markup commands. For instance, when a book title markup is interpreted, all the variables defined in the \header block are automatically added to props, so that the book title markup can access the book title, composer, etc. It is also a way to configure the behavior of a markup command: for example, when a command uses font size during processing, the font size is read from props rather than having a font-size argument. The caller of a markup command may change the value of the font size property in order to change the behavior. Use the #:properties keyword of define-markup-command to specify which properties shall be read from the props arguments.

The example in next section illustrates how to access and override properties in a markup command.


A complete example

The following example defines a markup command to draw a double box around a piece of text.

Firstly, we need to build an approximative result using markups. Consulting the Text markup commands shows us the \box command is useful:

\markup \box \box HELLO

[image of music]

Now, we consider that more padding between the text and the boxes is preferable. According to the \box documentation, this command uses a box-padding property, which defaults to 0.2. The documentation also mentions how to override it:

\markup \box \override #'(box-padding . 0.6) \box A

[image of music]

Then, the padding between the two boxes is considered too small, so we override it too:

\markup \override #'(box-padding . 0.4) \box
     \override #'(box-padding . 0.6) \box A

[image of music]

Repeating this lengthy markup would be painful. This is where a markup command is needed. Thus, we write a double-box markup command, taking one argument (the text). This draws the two boxes, with some padding.

 
#(define-markup-command (double-box layout props text) (markup?)
  "Draw a double box around text."
  (interpret-markup layout props
    #{\markup \override #'(box-padding . 0.4) \box
            \override #'(box-padding . 0.6) \box { #text }#}))

or, equivalently

 
#(define-markup-command (double-box layout props text) (markup?)
  "Draw a double box around text."
  (interpret-markup layout props
    (markup #:override '(box-padding . 0.4) #:box
            #:override '(box-padding . 0.6) #:box text)))

text is the name of the command argument, and markup? its type: it identifies it as a markup. The interpret-markup function is used in most of markup commands: it builds a stencil, using layout, props, and a markup. In the second case, this markup is built using the markup scheme macro, see Markup construction in Scheme. The transformation from \markup expression to scheme markup expression is straight-forward.

The new command can be used as follow:

\markup \double-box A

It would be nice to make the double-box command customizable: here, the box-padding values are hard coded, and cannot be changed by the user. Also, it would be better to distinguish the padding between the two boxes, from the padding between the inner box and the text. So we will introduce a new property, inter-box-padding, for the padding between the two boxes. The box-padding will be used for the inner padding. The new code is now as follows:

 
#(define-markup-command (double-box layout props text) (markup?)
  #:properties ((inter-box-padding 0.4)
                (box-padding 0.6))
  "Draw a double box around text."
  (interpret-markup layout props
    #{\markup \override #`(box-padding . ,inter-box-padding) \box
               \override #`(box-padding . ,box-padding) \box
               { #text } #}))

Again, the equivalent version using the markup macro would be:

 
#(define-markup-command (double-box layout props text) (markup?)
  #:properties ((inter-box-padding 0.4)
                (box-padding 0.6))
  "Draw a double box around text."
  (interpret-markup layout props
    (markup #:override `(box-padding . ,inter-box-padding) #:box
            #:override `(box-padding . ,box-padding) #:box text)))

Here, the #:properties keyword is used so that the inter-box-padding and box-padding properties are read from the props argument, and default values are given to them if the properties are not defined.

Then, these values are used to override the box-padding properties used by the two \box commands. Note the backquote and the comma in the \override argument: they allow you to introduce a variable value into a literal expression.

Now, the command can be used in a markup, and the boxes padding be customized:

#(define-markup-command (double-box layout props text) (markup?)
  #:properties ((inter-box-padding 0.4)
                (box-padding 0.6))
  "Draw a double box around text."
  (interpret-markup layout props
    #{\markup \override #`(box-padding . ,inter-box-padding) \box
              \override #`(box-padding . ,box-padding) \box
              { #text } #}))

\markup \double-box A
\markup \override #'(inter-box-padding . 0.8) \double-box A
\markup \override #'(box-padding . 1.0) \double-box A

[image of music]


Adapting builtin commands

A good way to start writing a new markup command, is to take example on a builtin one. Most of the markup commands provided with LilyPond can be found in file ‘scm/define-markup-commands.scm’.

For instance, we would like to adapt the \draw-line command, to draw a double line instead. The \draw-line command is defined as follow (documentation stripped):

 
(define-markup-command (draw-line layout props dest)
  (number-pair?)
  #:category graphic
  #:properties ((thickness 1))
  "…documentation…"
  (let ((th (* (ly:output-def-lookup layout 'line-thickness)
               thickness))
        (x (car dest))
        (y (cdr dest)))
    (make-line-stencil th 0 0 x y)))

To define a new command based on an existing one, copy the definition, and change the command name. The #:category keyword can be safely removed, as it is only used for generating LilyPond documentation, and is of no use for user-defined markup commands.

 
(define-markup-command (draw-double-line layout props dest)
  (number-pair?)
  #:properties ((thickness 1))
  "…documentation…"
  (let ((th (* (ly:output-def-lookup layout 'line-thickness)
               thickness))
        (x (car dest))
        (y (cdr dest)))
    (make-line-stencil th 0 0 x y)))

Then, a property for setting the gap between two lines is added, called line-gap, defaulting, e.g., to 0.6:

 
(define-markup-command (draw-double-line layout props dest)
  (number-pair?)
  #:properties ((thickness 1)
                (line-gap 0.6))
  "…documentation…"
  …

Finally, the code for drawing two lines is added. Two calls to make-line-stencil are used to draw the lines, and the resulting stencils are combined using ly:stencil-add:

#(define-markup-command (my-draw-line layout props dest)
  (number-pair?)
  #:properties ((thickness 1)
                (line-gap 0.6))
  "..documentation.."
  (let* ((th (* (ly:output-def-lookup layout 'line-thickness)
                thickness))
         (dx (car dest))
         (dy (cdr dest))
         (w (/ line-gap 2.0))
         (x (cond ((= dx 0) w)
                  ((= dy 0) 0)
                  (else (/ w (sqrt (+ 1 (* (/ dx dy) (/ dx dy))))))))
         (y (* (if (< (* dx dy) 0) 1 -1)
               (cond ((= dy 0) w)
                     ((= dx 0) 0)
                     (else (/ w (sqrt (+ 1 (* (/ dy dx) (/ dy dx))))))))))
     (ly:stencil-add (make-line-stencil th x y (+ dx x) (+ dy y))
                     (make-line-stencil th (- x) (- y) (- dx x) (- dy y)))))

\markup \my-draw-line #'(4 . 3)
\markup \override #'(line-gap . 1.2) \my-draw-line #'(4 . 3)

[image of music]


Converting markups to strings

Markups are occasionally converted to plain strings, such as when outputting PDF metadata based on the title header field or for converting lyrics to MIDI. This conversion is inherently lossy, but tries to as accurate as feasible. The function used for this is markup->string.

composerName = \markup \box "Arnold Schönberg"

\markup \composerName

\markup \typewriter #(markup->string composerName)

[image of music]

For custom markup commands, the default behavior is to convert all markup or markup list arguments first, and join the results by spaces.

#(define-markup-command (authors-and layout props authorA authorB)
                        (markup? markup?)
   (interpret-markup layout props
    #{
      \markup \fill-line { \box #authorA and \box #authorB }
    #}))

defaultBehavior = \markup \authors-and "Bertolt Brecht" "Kurt Weill"

\markup \defaultBehavior

\markup \typewriter #(markup->string defaultBehavior)

[image of music]

markup->string can also receive the named arguments #:layout layout and #:props props, with the same meaning as in the definition of a markup command. However, they are optional because they cannot always be provided (such as the layout argument when converting to MIDI).

To support special conversions in custom markup commands, the #:as-string parameter can be given to define-markup-command. It expects an expression, which is evaluated by markup->string in order to yield the string result.

#(define-markup-command (authors-and layout props authorA authorB)
                        (markup? markup?)
   #:as-string (format #f "~a and ~a"
                       (markup->string authorA #:layout layout #:props props)
                       (markup->string authorB #:layout layout #:props props))
   (interpret-markup layout props
    #{
      \markup \fill-line { \box #authorA and \box #authorB }
    #}))

customized = \markup \authors-and "Bertolt Brecht" "Kurt Weill"

\markup \customized

\markup \typewriter #(markup->string customized)

[image of music]

Within the expression, the same bindings are available as in the main markup command body, namely layout and props, the command argument, and optionally the properties.

#(define-markup-command (authors-and layout props authorA authorB)
                        (markup? markup?)
   #:properties ((author-separator " and "))
   #:as-string (format #f "~a~a~a"
                       (markup->string authorA #:layout layout #:props props)
                       (markup->string author-separator #:layout layout #:props props)
                       (markup->string authorB #:layout layout #:props props))
   (interpret-markup layout props
    #{
      \markup { \box #authorA #author-separator \box #authorB }
    #}))

customized = \markup \override #'(author-separator . ", ")
                     \authors-and "Bertolt Brecht" "Kurt Weill"

\markup \customized

\markup \typewriter #(markup->string customized)

[image of music]

Most often, a custom handler only needs to call markup->string recursively on certain arguments, as demonstrated above. However, it can also make use of the layout and props directly, in the same way as in the main body. Care must be taken that the layout argument is #f if no #:layout has been given to markup->string. The props argument defaults to the empty list.


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