\genericekv\expkvd{-def} Since the trend for the last couple of years goes to defining keys for a \kv\ interface using a \kv\ interface, I thought that maybe providing such an interface for \expkv\ will make it more attractive for actual use. But at the same time I didn't want to broaden \expkv's initial scope. So here is \expkvd, go define \kv\ interfaces with \kv\ interfaces. Unlike many of the other established \kv\ interfaces to define keys, \expkvd\ works using prefixes instead of suffixes (\emph{e.g.}, |.tl_set:N| of \pkg{l3keys}) or directory like handlers (\emph{e.g.}, |/.store in| of \pkg{pgfkeys}). This was decided as a personal preference, more over in \TeX\ parsing for the first spaces is way easier than parsing for the last one, so this should also turn out to be faster. \expkvd's prefixes are sorted into two categories: \prefixes, which are equivalent to \TeX's prefixes like |\long| and of which a \key\ can have multiple, and \types\ defining the basic behaviour of the \key\ and of which a \key\ must have one. For a description of the available \prefixes\ take a look at \autoref{sec:d:prefixes}, the \types\ are described in \autoref{sec:d:types}. \subsection{Macros\label{sec:d:macros}} The number of user-facing macros is quite manageable: \begin{function}{\ekvdefinekeys} \begin{syntax} \cs{ekvdefinekeys}\marg{set}\kvarg \end{syntax} In \meta{set}, define \key\ to have definition \val. The general syntax for \key\ should be \begin{quote} \ttfamily \meta{prefix} \meta{name} \end{quote} where \meta{prefix} is a space separated list of optional \prefixes\ followed by one \type. The syntax of \val\ is dependent on the used \type. \end{function} \begin{function}{\ekvdDate,\ekvdVersion} These two macros store the version and date of the package. \end{function} \subsection{Prefixes} As already said, prefixes are separated into two groups, \prefixes\ and \types. Not every \prefix\ is allowed for all \types. \subsubsection{\textit{Prefixes}\label{sec:d:prefixes}} \begin{function}[module=expkv-def prefix]{new} The following \key\ must be new (so previously undefined). An error is thrown if it is already defined and the new definition is ignored. |new| only asserts that there are no conflicts between \Nkey{}s and other \Nkey{}s or \Vkey{}s and other \Vkey{}s. \end{function} \begin{example}{The effects of the \texttt{new} \prefix} You can test the following (lines throwing an error are marked by a comment, error messages are printed in red for this example): \expkvdocPrintErrors[\par]% \begin{enverb}[below] \ekvdefinekeys{new-example} { new code key = \domystuffwitharg{#1} ,new noval KEY = \domystuffwithoutarg ,new bool key = \mybool % Error! ,new bool KEY = \mybool % Error! ,new meta key = {KEY} % Error! ,new nmeta KEY = {key} % Error! } \end{enverb} \end{example} \begin{function}[module=expkv-def prefix]{also} The following key \type\ will be \emph{added} to an existing \key's definition. You can't add a \type\ taking an argument at use time to an existing \key\ which doesn't take an argument and vice versa. Also you'll get an error if you try to add an action which isn't allowed to be either |\long| or |\protected| to a \key\ which already is |\long| or |\protected| (the opposite order would be suboptimal as well, but can't be really captured with the current code). A \key\ already defined as |\long| or |\protected| will stay that way, but you can add |\long| or |\protected| to a \key\ which isn't by using |also|. \end{function} \begin{example} {Overload a key \type\ with another with the \texttt{also} \prefix} Suppose you want to create a boolean \key, but additionally to setting a boolean value you want to execute some more code as well. For this you can use the following: \begin{enverb}[no-tcb] \ekvdefinekeys{also-example} { bool key = \ifmybool ,also code key = \domystuff{#1} } \end{enverb} \end{example} If you use |also| on a |choice|, |bool|, |invbool|, or |boolpair| \key\ it is tried to determine if the key already is of one of those types. If this test is true the declared choices will be added to the possible choices but the key's definition will not be changed other than that. If that wouldn't have been done, the callbacks of the different choices could get called multiple times. \begin{function}[module=expkv-def prefix]{protected,protect} The following \key\ will be defined |\protected|. Note that \types\ which can't be defined expandable will always use |\protected|. This only affects the key at use time not the \key\ definition. \end{function} \begin{function}[module=expkv-def prefix]{long} The following \key\ will be defined |\long| (so can take an explicit |\par| token in its \val). Please note that this only changes the \key\ at use time. |long| being present or not doesn't limit you to use |\par| inside of the \key's definition (if the \type\ allows this). \end{function} \subsubsection{\textit{Types}\label{sec:d:types}} Since the \prefixes\ apply to some of the \types\ automatically but sometimes one might be disallowed we need some way to highlight this behaviour. In the following an enforced \prefix\ will be printed black (\texttt{\enfprefix{protected}}), allowed \prefixes\ will be grey (\texttt{\allprefix{protected}}), and disallowed \prefixes\ will be red (\texttt{\notprefix{protected}}). This will be put flush-right in the syntax showing line. \begin{function}[module=expkv-def type]{code,ecode} \begin{syntax} code \key\ = \marg{definition} \prefixes2222 \end{syntax} Define \key\ to be a \Vkey\ expanding to \meta{definition}. You can use |#1| inside \meta{definition} to access the \key's \val. The |ecode| variant will fully expand \meta{definition} inside an |\edef|. \end{function} \ekvset{enverb}{no-tcb,store}% affect all the next examples. \begin{example} {Defining a \Vkey\ with arbitrary effect with the \texttt{code} \type} The following defines the key |foo|, that'll count the number of tokens passed to it (we'll borrow a function from \pkg{expl3} for this). It'll accept explicit |\par| tokens. Also it'll flip the \TeX-if \cs[no-index]{iffoo} to true. The result of the counting will be stored in a count register. (Don't get confused, all the next examples are part of this |\ekvdefinekeys| call, so there is no closing brace here.) \begin{enverb} \ExplSyntaxOn \cs_new_eq:NN \exampleCount \tl_count_tokens:n \ExplSyntaxOff \newcount\examplefoocount \newif\iffoo \ekvdefinekeys{example} { protected long code foo = \footrue \examplefoocount=\exampleCount{#1}\relax \end{enverb} \end{example} \begin{function}[module=expkv-def type]{noval,enoval} \begin{syntax} noval \key\ = \marg{definition} \prefixes2223 \end{syntax} The |noval| \type\ defines \key\ as a \Nkey\ expanding to \meta{definition}. |enoval| fully expands \meta{definition} inside an |\edef|. \end{function} \begin{example}{An arbitrary \Nkey\ action with the \texttt{noval} \type} The following defines the \Nkey\ |foo| to toggle the \TeX-if \cs[no-index]{iffoo} to false and set |\examplecount| to |0|. It'll be |\protected| and mustn't override any existing key. \begin{enverb} ,new protected noval foo = \foofalse\examplefoocount=0\relax \end{enverb} \end{example} \begin{function}[module=expkv-def type]{default,odefault,fdefault,edefault} \begin{syntax} default \key\ = \marg{definition} \prefixes2223 \end{syntax} This serves to place a default \val\ for a \Vkey. Afterwards if you use \key\ as a \Nkey\ it will be the same as if \key\ got passed \meta{definition} as its \val. The |odefault| variant will expand the key-macro once, so will be slightly quicker, but not change if you redefine the \Vkey\ afterwards. The |fdefault| version will expand the key-code until a non-expandable token or a space is found, a space would be gobbled.\footnotemark{} The |edefault| on the other hand fully expands the key-code with \meta{definition} as its argument in |\expanded|. The \prefix\ |new| means that there should be no \Nkey\ of that name yet. \end{function}% \footnotetext{For those familiar with \TeX-coding: This uses a \cs[no-index]{romannumeral}-expansion} \begin{example} {Setting a default value for a \Vkey\ with the \texttt{default} \type} We later decide that the above behaviour isn't what we need any more and instead redefine the \Nkey\ |foo| to pass some default value to the \Vkey\ |foo|. \begin{enverb} ,default foo = {Some creative default text} \end{enverb} \end{example} \begin{function}[module=expkv-def type]{initial,oinitial,finitial,einitial} \begin{syntax} initial \key\ = \marg{value} \prefixes3333 initial \key \end{syntax} With |initial| you can set an initial \val\ for an already defined \key. It'll just call the \key\ and pass it \val. The |einitial| variant will expand \val\ using |\expanded| prior to passing it to the \key\ and the |oinitial| variant will expand the first token in \val\ once. |finitial| will expand \val\ until a non-expandable token or a space is found, a space would be gobbled.\footnotemark If you don't provide a \val\ (and no equals sign) the \Nkey\ of the same name is called once (or, if you specified a |default| for a \Vkey\ that would be used). \end{function}% \footnotetext{Again using \cs[no-index]{romannumeral}} \begin{example}{Specifying initial values with the \texttt{initial} \type} We want to get a defined initial behaviour for our |foo|. So we count 0~tokens. \begin{enverb} ,initial foo = {} \end{enverb} \end{example} \begin{function}[module=expkv-def type]{bool,gbool,boolTF,gboolTF} \begin{syntax} bool \key\ = \meta{cs} \prefixes2223 \end{syntax} \singlecs{iffoo} This will define \key\ to be a boolean key, which only takes the values |true| or |false| and will throw an error for other values. If the \key\ is used as a \Nkey\ it'll have the same effect as if you use |true|. |bool| and |gbool| will behave like \TeX-ifs, so either be \cs[no-index]{iftrue} or \cs[no-index]{iffalse}. The \meta{cs} in the |boolTF| and |gboolTF| variants will take two arguments and if true the first will be used else the second, so they are always either |\@firstoftwo| or |\@secondoftwo|. The variants with a leading |g| will set the \meta{cs} globally, the other locally. If \meta{cs} is not yet defined it'll be initialised as the |false| version. Note that the initialisation is \emph{not} done with |\newif|, so you will not be able to do |\footrue| outside of the \kv\ interface, but you could use |\newif| yourself. Even if the \key\ will not be |\protected| the commands which execute the |true| or |false| choice will be, so the usage should be safe in an expansion context (\emph{e.g.}, you can use \texttt{edefault \key\ = false} without an issue to change the default behaviour to execute the |false| choice). Internally a |bool| is the same as a |choice| \type\ which is set up to handle |true| and |false| as choices. |new| will assert that neither the \Vkey\ nor the \Nkey\ are already defined. \end{function} \begin{example}{Defining Boolean keys with the \texttt{bool} \type} Also we want to have a direct way to set our \cs[no-index]{iffoo}, now that the \Nkey\ doesn't toggle it any longer. \begin{enverb} ,bool dofoo = \iffoo \end{enverb} \end{example} \begin{function}[module=expkv-def type]{invbool,ginvbool,invboolTF,ginvboolTF} \begin{syntax} invbool \key\ = \meta{cs} \prefixes2223 \end{syntax} These are inverse boolean keys, they behave like |bool| and friends but set the opposite meaning to the macro \meta{cs} in each case. So if |key=true| is used |invbool| will set \meta{cs} to \cs[no-index]{iffalse} and vice versa. \end{function} \begin{example} {Inversing the logic of a Boolean with the \texttt{invbool} \type} And since traditional interfaces lacked \kv\ support for packages, often a negated boolean key was used as well. \begin{enverb} ,invbool nofoo = \iffoo \end{enverb} \end{example} \begin{function}[module=expkv-def type]{boolpair,gboolpair,boolpairTF,gboolpairTF} \begin{syntax} boolpair \key\ = \meta{cs_1}\meta{cs_2} \prefixes2223 \end{syntax} The |boolpair| \type\ behaves like both |bool| and |invbool|, the \meta{cs_1} will be set to the meaning according to the rules of |bool|, and \meta{cs_2} will be set to the opposite. \end{function} \begin{function}[module=expkv-def type]{store,estore,gstore,xstore} \begin{syntax} store \key\ = \meta{cs} \prefixes2212 \end{syntax} \singlecs{foo} This will define a \Vkey\ to store \val\ inside of the control sequence. If \meta{cs} isn't yet defined it will be initialised as empty. The variants behave similarly to their |\def|, |\edef|, |\gdef|, and |\xdef| counterparts, but will allow you to store macro parameters inside them without needing to double them. So |estore foo = \foo, initial foo = #1| will not result in a low level \TeX\ error. \end{function} \begin{example} {Also store the \val\ of an existing \key\ in a macro using the \texttt{also} \prefix\ and the \texttt{store} \type} Not only do we want to count the tokens handed to |foo|, but we want to also store them inside of a macro (and we don't need to specify |long| here, since |foo| is already |\long| from our |code| definition above). \begin{enverb} ,also store foo = \examplefoostore \end{enverb} \end{example} \begin{function}[module=expkv-def type]{data,edata,gdata,xdata} \begin{syntax} data \key\ = \meta{cs} \prefixes2212 \end{syntax} \singlecs{foo} This will define a \Vkey\ to store \val\ inside of the control sequence. But unlike the |store| \type\ the macro \meta{cs} will be a switch at the same time, it'll take two arguments and if \meta{key} was used expands to the first argument followed by \val\ in braces, if \key\ was not used \meta{cs} will expand to the second argument (so behave like |\@secondoftwo|). The idea is that with this type you can define a key which should be typeset formatted. The |edata| and |xdata| variants will fully expand \val, the |gdata| and |xdata| variants will store \val\ inside \meta{cs} globally. Juts like with |store| you can use macro parameters without having to double them. The \prefixes\ only affect the key-macro, \meta{cs} will always be expandable and |\long|. \end{function} \begin{example}{Define a key using the \texttt{data} \type} Next we start to define other keys, now that our |foo| is pretty much exhausted. The following defines a key |bar| to be a |data| key. \begin{enverb} ,data bar = \examplebar \end{enverb} \end{example} \begin{function}[module=expkv-def type]{dataT,edataT,gdataT,xdataT} \begin{syntax} dataT \key\ = \meta{cs} \prefixes2212 \end{syntax} Just like |data|, but instead of \meta{cs} grabbing two arguments it'll only grab one, so by default it'll behave like |\@gobble|, and if \val\ was given to \key\ the \meta{cs} will behave like |\@firstofone| appended by \marg{value}. \end{function} \begin{example}{Define a key using the \texttt{dataT} \type} Another key we want to use is |baz|. \begin{enverb} ,dataT baz = \examplebaz \end{enverb} \end{example} \begin{function}[module=expkv-def type]{int,eint,gint,xint} \begin{syntax} int \key\ = \meta{cs} \prefixes2212 \end{syntax} \singlecs{foo} An |int| key will be a \Vkey\ setting a \TeX\ count register. If \meta{cs} isn't defined yet, |\newcount| will be used to initialise it. The |eint| and |xint| variants will use |\numexpr| to allow basic computations in their \val. The |gint| and |xint| variants set the register globally. \end{function} \begin{function}[module=expkv-def type]{dimen,edimen,gdimen,xdimen} \begin{syntax} dimen \key\ = \meta{cs} \prefixes2212 \end{syntax} \singlecs{foo} This is just like |int| but uses a dimen register, |\newdimen|, and |\dimexpr| instead. \end{function} \begin{function}[module=expkv-def type]{skip,eskip,gskip,xskip} \begin{syntax} skip \key\ = \meta{cs} \prefixes2212 \end{syntax} \singlecs{foo} This is just like |int| but uses a skip register, |\newskip|, and |\glueexpr| instead. \end{function} \begin{example} {Define keys that use \TeX\ registers, here a skip with the \texttt{eskip} \type} Exemplary for the different register keys, the following defines |distance| so that we can store some distance. \begin{enverb} ,eskip distance = \exampledistance \end{enverb} \end{example} \begin{function}[module=expkv-def type]{toks,gtoks,apptoks,gapptoks,pretoks,gpretoks} \begin{syntax} toks \key\ = \meta{cs} \prefixes2212 \end{syntax} \singlecs{foo} Store \val\ inside of a toks-register. The |g| variants use |\global|, the |app| variants append \val\ to the contents of that register, the |pre| variants will prepend \val. If \meta{cs} is not yet defined it will be initialised with |\newtoks|. \end{function} \begin{function}[module=expkv-def type]{box,gbox} \begin{syntax} box \key\ = \meta{cs} \prefixes2212 \end{syntax} \singlecs{foo} Typesets \val\ into a |\hbox| and stores the result in a box register. The boxes are colour safe. \expkvd\ currently doesn't provide a |vbox| type. \end{function} \begin{function}[module=expkv-def type]{meta} \begin{syntax} meta \key\ = \kvarg \prefixes2222 \end{syntax} This key \type\ can set other keys, you can access the \val\ given to the created \Vkey\ inside the \kv\ list using |#1|. This works by injecting the \kv\ list into the currently parsed list, so behaves just as if the \kv\ list was directly used instead of \key. \end{function} \begin{example} {Define a \Vkey\ as a shortcut to set multiple other keys with the \texttt{meta} \type} And we want to set a full set of keys with just this single one called |all|. \begin{enverb} ,meta all = {distance=5pt,baz=cheese cake,bar=cocktail bar,foo={#1}} \end{enverb} \end{example} \begin{function}[module=expkv-def type]{nmeta} \begin{syntax} nmeta \key\ = \kvarg \prefixes2223 \end{syntax} This \type\ sets other keys, but unlike |meta| this defines a \Nkey, so the \kv\ list is static. \end{function} \begin{example} {Set multiple other keys from a \Nkey\ with the \texttt{nmeta} \type} and if |all| is set without a value we want to do something about it as well. \begin{enverb} ,nmeta all = {distance=10pt,baz=nothing,bar=Waikiki bar,foo} \end{enverb} \end{example} \begin{function}[module=expkv-def type]{smeta} \begin{syntax} smeta \key\ = \marg{set}\kvarg \prefixes2222 \end{syntax} Yet another |meta| variant. |smeta| will define a \Vkey, you can access the given \val\ in the provided \kv\ list using |#1|. Unlike |meta| this will process that \kv\ list inside of \meta{set} using a nested |\ekvset| call, so this is equal to \texttt{\cs[no-index]{ekvset}\marg{set}\kvarg}. As a result you can't use |\ekvsneak| using keys or similar macros in the way you normally could. \end{function} \begin{function}[module=expkv-def type]{snmeta} \begin{syntax} snmeta \key\ = \marg{set}\kvarg \prefixes2223 \end{syntax} And the last |meta| variant. |snmeta| combines |smeta| and |nmeta|, so parses the \kv\ list inside of \meta{set} and defines a \Nkey\ with a static list. \end{function} \begin{function}[module=expkv-def type]{set} \begin{syntax} set \key\ = \marg{set} \prefixes2233 set \key \end{syntax} This will define a \Nkey\ that will change the current set to \meta{set}. If you give no value to this definition (omit |= |\marg{set}) the set name will be the same as \key\ so |set |\key\ is equivalent to |set |\key| = |\marg{key}. Note that just like in \expkv\ it'll not be checked whether \meta{set} is defined and you'll get a low-level \TeX\ error if you use an undefined \meta{set}. \end{function} \begin{function}[module=expkv-def type]{choice} \begin{syntax} choice \key\ = \{\val=\meta{definition}, \ldots\} \prefixes2223 \end{syntax} |choice| defines a \Vkey\ that will only accept a limited set of values. You should define each possible \meta{value} inside of the \val=\meta{definition} list. If a defined \meta{value} is passed to \meta{key} the \meta{definition} will be left in the input stream. You can make individual values |protected| inside the \val=\meta{definition} list by using that \prefix. To also allow choices that shouldn't be |\protected| but which start with the word |protected| you can also use |unprotected| as a special \prefix. By default a |choice| key and all its choices are expandable, an undefined \meta{value} will throw an error in an expandable way. You can add additional choices after the \meta{key} was created by using |choice| again for the same \key, redefining choices is possible the same way, but there is no interface to remove certain choices. To change the behaviour of unknown choices see also the |unknown-choice| \type. \end{function} \begin{example} {Define a choice with arbitrary code using the \texttt{choice} \type} We give the users a few choices. \begin{enverb} ,choice choose = { protected lemonade = \def\exampledrink{something sour} ,protected water = \def\exampledrink{something boring} } \end{enverb} \end{example} \begin{function}[module=expkv-def type]{choice-store} \begin{syntax} choice-store \key\ = \meta{cs}\{\val=\meta{definition}, \ldots\} \prefixes2223 \end{syntax} \singlecs{foo} This is a special \type\ of the |choice| \type\ that'll store the given choice inside the macro \meta{cs}. Since storing inside a macro can't be done expandably every choice-code is |\protected|, and you might define the |choice-store| key itself as |\protected| as well if you want. Inside the \val|=|\meta{definition} list the |=|\meta{definition} part is optional, if you omit it the \val\ will be stored as given during define-time inside of \meta{cs} (during use-time the \val\ needs to be matched |\detokenize|d), and if you specify |=|\meta{definition} that \meta{definition} will be stored inside of \meta{cs} instead. If \meta{cs} doesn't yet exist it's initialised as empty. \end{function} \begin{example} {Show the equivalent setup for a \texttt{choice} \type\ to mimic a \texttt{choice-store} \type} The following keys |key1| and |key2| are equivalent at use time (this doesn't continue the |\ekvdefinekeys|-call for the set |example| above): \begin{enverb}[no-store,no-tcb] \newcommand*\mya{}% initialise \mya \ekvdefinekeys{choice-store-example} { choice key1 = { protected a = \def\mya{a} ,protected b = \def\mya{b} ,protected c = \def\mya{c} ,protected d = \def\mya{FOO} } ,choice-store key2 = \myb{a,b,c,d=FOO} } \end{enverb} \end{example} \begin{example} {Store the user's choices in a macro with the \texttt{choice-store} \type} (this continues the |\ekvdefinekeys|-call for the set |example| from above) After the above drinks we define a few more choices which are directly stored. \begin{enverb} ,choice-store choose = \exampledrink{beer,wine} \end{enverb} One might notice that the entire setup of the |choose| key could've been done using only |choice-store|. \end{example} \begin{function}[module=expkv-def type]{choice-enum} \begin{syntax} choice-enum \key\ = \meta{cs}\{\val, \ldots\} \prefixes2223 \end{syntax} \singlecs{foo} This is similar to |choice-store|, the differences are: \meta{cs} should be a count register or is initialised as such using |\newcount|; instead of the \val\ itself being stored its position in the list of choices is stored (zero-based). It is not possible to specify a \meta{definition} to store something else than the numerical position inside the list. \end{function} \begin{example} {Show the equivalent setup for a \texttt{choice} \type\ to mimic a \texttt{choice-enum} \type} The following keys |key1| and |key2| are equivalent at use time (another example not using the |example| set of above's |\ekvdefinekeys|): \begin{enverb}[no-store,no-tcb] \newcount\myc \ekvdefinekeys{choice-enum-example} { choice key1 = { protected a={\myc=0 } ,protected b={\myc=1 } ,protected c={\myc=2 } } ,choice-enum key2 = \myd{a,b,c} } \end{enverb} \end{example} \begin{function}[module=expkv-def type]{unknown-choice} \begin{syntax} unknown-choice \key\ = \marg{definition} \prefixes2323 \end{syntax} By default an unknown \val\ passed to a |choice| or |bool| \type\ (and all their variants) will throw an error. However, with this prefix you can define an alternative action which should be executed if \key\ received an unknown choice. In \meta{definition} you can refer to the given invalid choice with |#1|. \end{function} \begin{example} {Handle unknown choices without throwing an error with the \texttt{unknown-choice} \type} If a drink was chosen with |choose| that's not defined we don't want to throw an error, but store something else instead. \begin{enverb} ,protected unknown-choice choose = \def\exampledrink{something unavailable} }% closing brace for \ekvdefinekeys \end{enverb} \end{example} \begin{function}[module=expkv-def type]{unknown code} \begin{syntax} unknown code = \marg{definition} \prefixes2322 \end{syntax} By default \expkv\ throws errors when it encounters unknown keys in a set. With the |unknown| \type\ you can define handlers that deal with undefined keys, instead of a \key\ name you have to specify a subtype for this, here the subtype is |code|. With |unknown code| the \meta{definition} is used for unknown keys which were provided a value (so corresponds to |\ekvdefunknown|), you can access the unknown \key\ name with |#1| (|\detokenize|d), the given \val\ with |#2|, and the unprocessed \key\ name with |#3| (in case you want to further expand it).\footnotemark \end{function}% \footnotetext{There is some trickery involved to get this more intuitive argument order without any performance hit if you compare this to \cs[no-index]{ekvdefunknown} directly} \begin{function}[module=expkv-def type]{unknown noval} \begin{syntax} unknown noval = \marg{definition} \prefixes2323 \end{syntax} This is like |unknown code| but uses \meta{definition} for unknown keys to which no value was passed (so corresponds to |\ekvdefunknownNoVal|). You can access the |\detokenize|d \key\ name with |#1| and the unprocessed one with |#2|. \end{function} \begin{function}[module=expkv-def type]{unknown redirect-code} \begin{syntax} unknown redirect-code = \marg{set-list} \prefixes2331 \end{syntax} This uses a predefined action for |unknown code|. Instead of throwing an error, it is tried to find the \meta{key} in each \meta{set} in the comma separated \meta{set-list}. The first found match will be used and the remaining options from the list discarded. If the \meta{key} isn't found in any \meta{set} an expandable error will be thrown eventually. Internally \expkv's |\ekvredirectunknown| will be used. \end{function} \begin{function}[module=expkv-def type]{unknown redirect-noval} \begin{syntax} unknown redirect-noval = \marg{set-list} \prefixes2333 \end{syntax} This behaves just like |unknown redirect-code| but will set up means to forward keys for |unknown noval|. Internally \expkv's |\ekvredirectunknownNoVal| will be used. \end{function} \begin{function}[module=expkv-def type]{unknown redirect} \begin{syntax} unknown redirect = \marg{set-list} \prefixes2333 \end{syntax} This is a short cut to apply both, |unknown redirect-code| and |unknown redirect-noval|, as a result you might get doubled error messages, one from each. \end{function} \bigskip Time to use all those keys defined in the different examples! % undo the global no-tcb setting \ekvset{enverb}{no-store,undo-no-tcb}% \begin{enverb}[restore,below,inter=Which results in three paragraphs of text:] \newcommand\defexample[1][] {% \ekvset{example}{#1}% After walking \the\exampledistance\space we finally reached \examplebar{\emph}{no particular place}. There I ordered \iffoo a drink called \examplefoostore\space (that has \the\examplefoocount\space tokens in it)% \else nothing of particular interest% \fi \examplebaz{ and ate \emph}. Then a friend of mine also chose \exampledrink. \par } \defexample[nofoo] \defexample[all,choose=lemonade] \defexample [all=wheat beer,bar=Biergarten,baz=pretzel,choose=champagne] \end{enverb} \subsection{Another Example} This picks up the standard use case from \autoref{sec:expkv:standard}, but defines the keys using |\ekvdefinekeys|. \begin{enverb} \makeatletter \ekvdefinekeys{myrule} { store ht = \myrule@ht ,initial ht = 1ex ,store wd = \myrule@wd ,initial wd = 0.1em ,store raise = \myrule@raise ,initial raise = \z@ ,meta lower = {raise={-#1}} } \ekvsetdef\myruleset{myrule} \newcommand*\myrule[1][] {% \begingroup \myruleset{#1}% \rule[\myrule@raise]{\myrule@wd}{\myrule@ht}% \endgroup } \makeatother a\myrule\par a\myrule[ht=2ex,lower=.5ex]\par \myruleset{wd=5pt} a\myrule \end{enverb}