% \iffalse % -------------------------------------------------------------------- % <*chit> % \fi % % \subsubsection{The \texttt{chit} key namespace} % % Some stuff to consider wrt.~line widths. Setting the line width in % the \texttt{chit} scope overrides frame settings. The frame stroke % can be larger but not smaller. Setting the stroke width in the % symbol scope sets it for the symbol only. Thus, to get a thin % border, we need to % \begin{itemize} % \item Set a small line width in the top chit scope. % \item Possible set a larger line width in the frame sub-scope. % \item Set a larger line width in the symbol sub-scope. % \end{itemize} % I do not know why this is. % % \begin{TikzKey}{/chit/full, % /chit/symbol, % /chit/left, % /chit/right, % /chit/upper left, % /chit/upper right, % /chit/lower left, % /chit/lower right, % /chit/factors, % /chit/extra, % /chit/setup, % /chit/bevel, % /chit/id} % % The parts of a chit % % \begin{macrocode} \newif\ifchit@clip\chit@cliptrue \tikzset{% /chit/.search also={/tikz}, /chit/.cd, full/.store in=\chit@full, full/.initial=,% symbol/.store in=\chit@symbol, symbol/.initial=,% left/.store in=\chit@left, left/.initial=,% unique/.style={/chit/left={#1}},% right/.store in=\chit@right, right/.initial=,% parent/.style={/chit/right={#1}},% upper left/.store in=\chit@upper@left, upper left/.initial=,% upper right/.store in=\chit@upper@right, upper right/.initial=,% lower left/.store in=\chit@lower@left, lower left/.initial=,% lower right/.store in=\chit@lower@right, lower right/.initial=,% factors/.store in=\chit@factors, factors/.initial=,% setup/.store in=\chit@setup, setup/.initial=,% id/.store in=\chit@id, id/.initial=,% frame/.store in=\chit@frame, frame/.initial=,% extra/.store in=\chit@extra, extra/.initial=,% bev/.store in=\chit@bevel, bev/.initial=, bevel fraction/.store in=\chit@bevel@frac,bevel fraction/.initial=10, bevel/.is choice, bevel/none/.style = {/chit/bev=}, bevel/north west/.style = {/chit/bev=1}, bevel/north east/.style = {/chit/bev=2}, bevel/south west/.style = {/chit/bev=3}, bevel/south east/.style = {/chit/bev=4}, bevel/NW/.style = {/chit/bev=1}, bevel/NE/.style = {/chit/bev=2}, bevel/SW/.style = {/chit/bev=3}, bevel/SE/.style = {/chit/bev=4}, bevel/.default = north west, clip/.is if=chit@clip% } % \end{macrocode} % \end{TikzKey} % % \begin{TikzKey}{/tikz/chit/full, % /tikz/chit/symbol, % /tikz/chit/left, % /tikz/chit/right, % /tikz/chit/upper left, % /tikz/chit/upper right, % /tikz/chit/lower left, % /tikz/chit/lower right, % /tikz/chit/factors, % /tikz/chit/setup, % /tikz/chit/id} % % Styles of each element in a chit. Users may override these at their % own peril. That is, it is OK to override them, but the user should % be careful. % % \begin{macrocode} \tikzset{ chit/symbol/.style={scale=.4,transform shape}, chit/parts/.style={shape=rectangle,transform shape}, chit/factors/.style={chit/parts,anchor=south}, chit/left/.style={chit/parts,anchor=base,rotate=90},%Anchor was south chit/right/.style={chit/parts,anchor=north,rotate=90}, chit/upper left/.style={chit/parts,anchor=north west}, chit/upper right/.style={chit/parts,anchor=north east}, chit/lower left/.style={chit/parts,anchor=south west}, chit/lower right/.style={chit/parts,anchor=south east}, chit/setup/.style={chit/parts}, chit/full/.style={chit/parts}, chit/frame/.try={draw=pgfstrokecolor}, chit/bevel highlight/.style={fill=white,opacity=.25}, chit/bevel shadow/.style={fill=black,opacity=.25}, } \def\chit@bevel@frac{10} \newif\ifchit@draw@frame\chit@draw@frametrue \tikzset{ chit/frame style/.search also={/tikz}, chit/frame style/.cd, none/.code={\chit@draw@framefalse}, draw/.code={% \chit@dbg{2}{Frame draw option `#1'} \edef\tikz@temp{#1}% \ifx\tikz@temp\tikz@nonetext% \chit@draw@framefalse% \else% \chit@draw@frametrue% \tikzset{/tikz/draw=#1} \fi } } % \end{macrocode} % \end{TikzKey} % % \iffalse % -------------------------------------------------------------------- % \fi % % \subsubsection{The \texttt{chit} styles} % % \begin{TikzKey}{/tikz/chit} % This key sets up a node to make a chit. The key takes a single % argument which in turn must contain key--value pairs in the % \texttt{/chit} (or \texttt{/tikz}) namespace(s). We set the % \texttt{shape} parameter of the node, and calls the passed keys in % the \texttt{/chit} namespace to set-up elements of the chit. % % \begin{macrocode} \tikzset{% chit/.code={% \chit@dbg{2}{chit arguments are `#1'}% \pgfkeys{/tikz/transform shape,/tikz/shape=chit}% \pgfkeys{/chit/.cd,#1}}} % \end{macrocode} % \end{TikzKey} % % We define a counter to set-up unique names for chit nodes. % % \begin{macrocode} \newcounter{chit@id}\setcounter{chit@id}{0} % \end{macrocode} % % \iffalse % -------------------------------------------------------------------- % \fi % \subsubsection{The \cs{chit} shape} % % \begin{Macro}{\chit@n@to,\@chit@n@to,\@@chit@n@to,\@chit@n@to@} % % These macros puts the NATO App6(c) symbol into a chit. The first % macro takes the identifier and position of the symbol, and then % scans for options. If no options are given, then we go directly % to the rendering (\cs{@chit@n@to@}). Otherwise, we may also need % to scan for an offset given as \parg{delta-x,delta-y}. % % \begin{macrocode} \def\chit@n@to#1#2{% %% Without a following start square bracket '[' by-pass to final \chit@dbg{1}{Chit NATO App6(c) first step `#1' `#2'} \@ifnextchar[{% %\message{^^JStart square bracket}% \@chit@n@to{#1}{#2}}{% %\message{^^JNo start square bracket}% \@chit@n@to@{#1}{#2}}%]] } % \end{macrocode} % % The following macro is called if we had no options. % % \begin{macrocode} \def\@chit@n@to@#1#2#3\@end@chit@n@to{% \chit@dbg{1}{Chit NATO App6(c) w/o offset: ^^J Options: #3 ^^J ID: #1 ^^J Position: #2} \node[chit/symbol,natoapp6c={#3,id=#1}] (#1) at (#2) {}; \chit@dbg{4}{Chit NATO App6(c) ended}% } % \end{macrocode} % % This is called if we had an option-like argument. Check if we have % an offset % % \begin{macrocode} \def\@chit@n@to#1#2[#3]{% \chit@dbg{1}{Chit NATO App6(c) second step `#1' `#2' `#3'} \@ifnextchar({\@@chit@n@to{#1}{#2}{#3}}{\@@chit@n@to{#1}{#2}{#3}(0,0)}%) } % \end{macrocode} % % This called if we had option-like argument. % % \begin{macrocode} \def\@@chit@n@to#1#2#3(#4)\@end@chit@n@to{% \chit@dbg{1}{Chit NATO App6(c) w/offset: ^^J Options: #3 ^^J ID: #1 ^^J Position: #2 ^^J Offset: #4} \node[chit/symbol,natoapp6c={#3,id=#1}] (#1) at ($(#2)+(#4)$) {};} % \end{macrocode} % \end{Macro} % % \begin{Macro}{\chit@tr@ns@nchor,\chit@nchor} % % Get anchor of sub-symbol element in chit. We need to do this, % because the symbol is translated and scaled. % % \begin{macrocode} \def\chit@tr@ns@nchor#1{% \pgf@x=0.4\pgf@x% \pgf@y=0.4\pgf@y\advance\pgf@y#1} % \end{macrocode} % % \begin{macrocode} \def\chit@nchor#1#2#3{% \wg@sub@nchor{#1}{#2} \chit@tr@ns@nchor{#3}} \def\chit@report{} \tikzset{ zone turn/.style={}, zone mult/.style={} } % \end{macrocode} % \end{Macro} % % Now follows the actual \text{chit} shape. This is rather long, so % we will break it up a bit % \begin{macrocode} \def\chit@bevel@path#1{ \scope[#1] \wg@tmpc=\wg@tmpa\multiply\wg@tmpc by \chit@bevel@frac \wg@tmpd=\wg@tmpb\multiply\wg@tmpd by \chit@bevel@frac \divide\wg@tmpc100 \divide\wg@tmpd100 \pgfpathmoveto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% % Move down along edge \wg@tmpb=-\wg@tmpb \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% % Move left along edge \wg@tmpa=-\wg@tmpa \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% % Move in and up \advance\wg@tmpa\wg@tmpc% \advance\wg@tmpb\wg@tmpd% \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% % Move right, but in \advance\wg@tmpa-\wg@tmpc\wg@tmpa=-\wg@tmpa% \advance\wg@tmpa-\wg@tmpc% \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% % Move up but down \advance\wg@tmpb-\wg@tmpd\wg@tmpb=-\wg@tmpb% \advance\wg@tmpb-\wg@tmpd% \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \pgfclosepath% \pgfusepath{fill} \endscope } % \end{macrocode} % % The first thing is we declare some saved anchors. These are % computed (and defined as internal macros) when the shape is % instantised. The anchors give the centre and north east corner of % the node, the place to put the NATO App6(c) symbol and factors. We % also set a dimension for the margins (corner and factors elements). % % \begin{macrocode} \pgfdeclareshape{chit}{ \savedanchor\center{\pgf@x=0cm\pgf@y=0cm} \savedanchor\northeast{\pgf@x=0.6cm\pgf@y=0.6cm} \savedanchor\symbol{\pgf@x=0cm\pgf@y=0.2cm} \savedanchor\factors{\pgf@x=0cm\pgf@y=-0.5cm} \saveddimen\margin{\pgf@x=0.04cm} % \end{macrocode} % % Next, we define some saved macros. These are called (and declares % internal macros) when the shape is instantised. We define macros % for the identifier, % % % \begin{macrocode} \savedmacro\id{% \chit@dbg{4}{Chit ID: \meaning\chit@id}% \@ifundefined{chit@id}{\let\chit@id\pgfutil@empty}{}% \ifx\chit@id\pgfutil@empty% \wg@r@ndom@id% \edef\id{chit\wg@uuid}% \else% \edef\id{\chit@id}% \fi% \chit@dbg{4}{Chit ID stored: \meaning\chit@id} } \savedmacro\chitframeopt{% \let\chitframeopt\pgfutil@empty% \@ifundefined{chit@frame}{}{% \edef\chitframeopt{\chit@frame}} \chit@dbg{3}{Chit Frame options: \meaning\chitframeopt}% } % \end{macrocode} % % We define the regular anchors of the shape. That is, the centre, % corners, and edges. % % \begin{macrocode} \anchor{center}{\center} \anchor{north east}{\northeast} \anchor{north west}{\northeast\pgf@x=-\pgf@x} \anchor{south west}{\northeast\pgf@x=-\pgf@x\pgf@y=-\pgf@y} \anchor{south east}{\northeast\pgf@y=-\pgf@y} \anchor{north} {\northeast\pgf@x=0cm} \anchor{south} {\northeast\pgf@x=0cm\pgf@y=-\pgf@y} \anchor{east} {\northeast\pgf@y=0cm} \anchor{west} {\northeast\pgf@x=-\pgf@x\pgf@y=0cm} % \end{macrocode} % % Next, we want to be able to reference the symbol anchors too. So we % define these anchors from the embedded node anchors. Note, these % anchors will not exist if the chit is made with % \texttt{full=}\meta{args}. % % \begin{macrocode} \anchor{symbol north east}{\chit@nchor{M\id symbol}{north east}{0.2cm}} \anchor{symbol north west}{\chit@nchor{M\id symbol}{north west}{0.2cm}} \anchor{symbol south east}{\chit@nchor{M\id symbol}{south east}{0.2cm}} \anchor{symbol south west}{\chit@nchor{M\id symbol}{south west}{0.2cm}} \anchor{symbol north} {\chit@nchor{M\id symbol}{north}{0.2cm}} \anchor{symbol west} {\chit@nchor{M\id symbol}{west}{0.2cm}} \anchor{symbol south} {\chit@nchor{M\id symbol}{south}{0.2cm}} \anchor{symbol east} {\chit@nchor{M\id symbol}{east}{0.2cm}} \anchor{symbol upper} {\chit@nchor{M\id symbol}{upper}{0.2cm}} \anchor{symbol lower} {\chit@nchor{M\id symbol}{lower}{0.2cm}} \anchor{symbol left} {\chit@nchor{M\id symbol}{left}{0.2cm}} \anchor{symbol right} {\chit@nchor{M\id symbol}{right}{0.2cm}} \anchor{symbol echelon} {\chit@nchor{M\id symbol}{north}{0.2cm}} \anchor{symbol below} {\chit@nchor{M\id symbol}{south}{0.1cm}} % \end{macrocode} % % Some anchors to sub-elements. Some of them only exists if we have % NATO App6(c) symbol in the chit. % % \begin{macrocode} \anchor{symbol} {\symbol} \anchor{factors} {\factors} \anchor{left} {\chit@nchor{M\id symbol}{west}{.2cm}\advance\pgf@x-\margin} \anchor{right}{\chit@nchor{M\id symbol}{east}{.2cm}\advance\pgf@x+\margin} \anchor{upper right} {% \northeast \advance\pgf@x-\margin \advance\pgf@y-\margin% } \anchor{upper left}{ \northeast \advance\pgf@x-\margin \advance\pgf@y-\margin \pgf@x=-\pgf@x% } \anchor{lower right} {% \northeast \advance\pgf@x-\margin \advance\pgf@y-\margin \pgf@y=-\pgf@y% } \anchor{lower left}{ \northeast \advance\pgf@x-\margin \advance\pgf@y-\margin% \pgf@x=-\pgf@x \pgf@y=-\pgf@y% } % \end{macrocode} % % Now for the actual path. For the background path, we simply specify % the frame. This is so that this will get drawn (and possibly % filled) using the appropriate options. % % \begin{macrocode} \backgroundpath{% %% This is the outline of the chit only. The rest of the chit is %% made on the foreground "path". \chit@dbg{1}{Chit drawing background path} \northeast% \wg@tmpa=\pgf@x\wg@tmpb=\pgf@y% \pgfpathmoveto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpa=-\wg@tmpa \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpb=-\wg@tmpb \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpa=-\wg@tmpa \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \pgfclosepath } % \end{macrocode} % % Finally, we make the foreground rendered path. This is where we do % the most stuff. We do it in the \emph{behind} foreground path so % that we can ensure things are drawn the way we want it. % % The first thing is to set-up the clipping to the chit frame. % % \begin{macrocode} \behindforegroundpath{% \chit@dbg{1}{Chit drawing foreground path} % \chit@dbg{4}{% % Chit foreground: \meaning\id % ^^J ID (set): \meaning\chit@id % ^^J Symbol: \meaning\chit@symbol % ^^J Full: \meaning\chit@full % ^^J Factors: \meaning\chit@factors % ^^J Left: \meaning\chit@left % ^^J Right: \meaning\chit@right % ^^J Upper left: \meaning\chit@upper@left % ^^J Lower left: \meaning\chit@lower@left % ^^J Upper right: \meaning\chit@upper@right % ^^J Lower right: \meaning\chit@lower@right % ^^J Extra: \meaning\chit@extra % ^^J Bevel: \meaning\chit@bevel % ^^J Frame: \meaning\chit@frame} \chit@dbg{1}{Chit report} \chit@report{} \chit@dbg{1}{Chit start scope} \pgfscope % \ifchit@clip% \chit@dbg{1}{Chit clip path} \northeast% \wg@tmpa=\pgf@x\wg@tmpb=\pgf@y% \pgfpathmoveto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpa=-\wg@tmpa \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpb=-\wg@tmpb \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpa=-\wg@tmpa \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \pgfclosepath% \pgfusepath{clip}% \fi% % \end{macrocode} % % If we do not have the \texttt{symbol} key set, then we set the % \texttt{full} key as a picture. % % \begin{macrocode} \@ifundefined{chit@symbol}{% %% Draw full stuff \@ifundefined{chit@full}{}{% \chit@dbg{1}{Chit draw full image: `\meaning\chit@full'} \center\wg@tmpa=\pgf@x\wg@tmpb=\pgf@y% \wg@pic@all{\chit@full}{}{\the\wg@tmpa,\the\wg@tmpb}{chit/full}}% }{% With NATO symbol % \end{macrocode} % % Otherwise, we put in a node with shape \texttt{natoapp6c} and pass % the \texttt{symbol} key--value pairs as options. % % \begin{macrocode} \chit@dbg{1}{Chit draw symbol image} \edef\symid{\id symbol}% \symbol% \edef\args{{\symid}{\the\pgf@x,\the\pgf@y}\chit@symbol}% \chit@dbg{6}{Arguments to chit NATO symbol: \meaning\args}% \chit@dbg{1}{Chit draw nato image} \expandafter\chit@n@to\args\@end@chit@n@to% \chit@dbg{6}{After making NATO symbol in chit}% % \end{macrocode} % % Having made the NATO App6(c) symbol, which we gave the node name % \meta{id}\texttt{symbol} where \meta{id} is the ID of this chit, we % can make the rest of the chit elements. These are the left and % right elements, which are set west and east of the symbol, % respectively; the factors; and the four corner elements. % % If the respective elements have not been specified, we do not make % them. % % First the left and right elements. Note that these uses the anchors % of the embedded \texttt{natoapp6c} node for placement. % % \begin{macrocode} % Put in left of symbol \@ifundefined{chit@left}{}{% \chit@dbg{1}{Chit draw left: `\meaning\chit@left'} \begin{scope}[] \pgfpointanchor{\symid}{west}% \wg@tmpa=\pgf@x\advance\wg@tmpa-\margin% \wg@tmpb=\pgf@y% \wg@pic@all{\chit@left}{}{\the\wg@tmpa,\the\wg@tmpb}{chit/left}% \end{scope}}% % Put in right of symbol \@ifundefined{chit@right}{}{% \chit@dbg{1}{Chit draw left: `\meaning\chit@right'} \begin{scope}[] \pgfpointanchor{\symid}{east}% \wg@tmpa=\pgf@x\advance\wg@tmpa+\margin% \wg@tmpb=\pgf@y% \wg@pic@all{\chit@right}{}{\the\wg@tmpa,\the\wg@tmpb}{chit/right}% \end{scope}}% % \end{macrocode} % % Next, we want to put in the corner elements. But before we do % that, we use our saved anchors and dimensions to calculate the % coordinates. Note that the corner elements are anchored to the % corners (plus margin) of the chit frame. % % \begin{macrocode} % Get coordinates \northeast% \wg@tmpa=\pgf@x% \wg@tmpb=\pgf@y% \advance\wg@tmpa-\margin% \advance\wg@tmpb-\margin% % \end{macrocode} % % With the coordinates extracted, we set the four corner % elements. Note, for the anchoring to work, we should specify % pictures that have anchors (e.g., nodes). If not, we must take care % to give offsets or the like. % % \begin{macrocode} % Put in upper left corner \@ifundefined{chit@upper@left}{}{% \chit@dbg{1}{Chit draw upper left: `\meaning\chit@upper@left'} \begin{scope}[] \wg@pic@all{\chit@upper@left}{}{-\the\wg@tmpa,\the\wg@tmpb}{% chit/upper left}% \end{scope}} % Put in upper right corner \@ifundefined{chit@upper@right}{}{% \chit@dbg{1}{Chit draw upper right: `\meaning\chit@upper@right'} \begin{scope}[] \wg@pic@all{\chit@upper@right}{}{\the\wg@tmpa,\the\wg@tmpb}{% chit/upper right}% \end{scope}} % Put in lower left corner \@ifundefined{chit@lower@left}{}{% \chit@dbg{1}{Chit draw lower left: `\meaning\chit@lower@left'} \begin{scope}[] \wg@pic@all{\chit@lower@left}{}{-\the\wg@tmpa,-\the\wg@tmpb}{% chit/lower left}% \end{scope}} % Put in lower right corner \@ifundefined{chit@lower@right}{}{% \chit@dbg{1}{Chit draw lower right: `\meaning\chit@lower@right'} \begin{scope}[] \wg@pic@all{\chit@lower@right}{}{\the\wg@tmpa,-\the\wg@tmpb}{% chit/lower right}% \end{scope}} % \end{macrocode} % % Finally, we put in the unit factors. They are put at the bottom of % the chit frame (plus margin) and are typically anchored to the south % anchor of the element. Note, we can put in several factors if need % be. % % \begin{macrocode} % Put in factors \@ifundefined{chit@factors}{}{% \chit@dbg{1}{Chit draw factors: `\meaning\chit@factors'} \advance\wg@tmpb-\margin% \begin{scope}[] \wg@pic@all{\chit@factors}{}{0,-\the\wg@tmpb}{chit/factors}% \end{scope}}% % Put in extra \@ifundefined{chit@extra}{}{% \chit@dbg{1}{Chit draw extra: `\meaning\chit@extra'} \begin{scope}[] \wg@pic@all{\chit@extra}{}{0,0}{chit/factors}% \end{scope}}% }% End of full or symbol \endpgfscope% % Make bevel? \@ifundefined{chit@bevel}{\let\chit@bevel\empty}{} \ifx\chit@bevel\empty\else% \chit@dbg{1}{Chit draw bevel} %% South east bevel \northeast% \wg@tmpa=-\pgf@x\wg@tmpb=-\pgf@y% \ifcase\chit@bevel\relax% \or% 1 \or\wg@tmpa=-\wg@tmpa% 2 \or\wg@tmpb=-\wg@tmpb% 3 \or\wg@tmpa=-\wg@tmpa\wg@tmpb=-\wg@tmpb%4 \fi \chit@bevel@path{chit/bevel highlight} %% North west bevel \northeast% \wg@tmpa=\pgf@x\wg@tmpb=\pgf@y% \ifcase\chit@bevel\relax% \or% 1 \or\wg@tmpa=-\wg@tmpa% 2 \or\wg@tmpb=-\wg@tmpb% 3 \or\wg@tmpa=-\wg@tmpa\wg@tmpb=-\wg@tmpb%4 \fi \chit@bevel@path{chit/bevel shadow} \fi % Draw frame? \chit@dbg{1}{Chit draw frame: `\meaning\chitframeopt'} \edef\tmp@opt{[chit/frame style/.cd,chit/frame/.try,\chitframeopt]} \chit@dbg{1}{Chit draw frame: `\meaning\tmp@opt} \expandafter\scope\tmp@opt \northeast% \wg@tmpa=\pgf@x\wg@tmpb=\pgf@y% \pgfpathmoveto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpa=-\wg@tmpa \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpb=-\wg@tmpb \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \wg@tmpa=-\wg@tmpa \pgfpathlineto{\pgfqpoint{\wg@tmpa}{\wg@tmpb}}% \pgfclosepath% \chit@dbg{3}{Line width for frame: `\the\pgflinewidth'} \ifchit@draw@frame\pgfusepath{stroke}\fi% \chit@draw@frametrue% %\iftikz@mode@fill\pgfusepath{fill}\fi% \endscope% \chit@dbg{1}{Chit end of shape} } } % \end{macrocode} % % \iffalse % -------------------------------------------------------------------- % \fi % \subsubsection{The \cs{chit} wrapper macro} % % \begin{Macro}{\chit,\chit@,\chit@@} % % The macro to make the chits. This is a wrapper around a % \texttt{node} with shape \texttt{chit}. The syntax of this macro % is % % \begin{Syntax} % \cs{chit}\oarg{chit options}\parg{position}\parg{identifier}; % \end{Syntax} % % Note that the trailing semi-colon is optional. Here \meta{chit % options} are any key-value pairs in the \texttt{/chit} (and % \texttt{/tikz}) namespace. % % The first macro parses for options. % % \begin{macrocode} \def\chit{% \chit@dbg{5}{Chit} \@ifnextchar[{\chit@}{\chit@[]}%] } % \end{macrocode} % % Parse for coordinates. % % \begin{macrocode} \def\chit@[#1]{% \chit@dbg{5}{Chit second: `#1'} \@ifnextchar({\chit@@{#1}}{\chit@@{#1}(0,0)}%) } % \end{macrocode} % % Parse for name. % % \begin{macrocode} \def\chit@@#1(#2){% \@ifnextchar({\chit@@@{#1}{#2}}{\chit@@@{#1}{#2}()}%) } % \end{macrocode} % % The work horse. This simply makes a \cs{node} with the shape % \texttt{chit}. Note, we allow for a trailing semi-colon % (\texttt{;}) to have a similar feel to other \TikZ{} macros. % % The macro will execute the style \texttt{/tikz/every chit} if % defined. Note that this will be executed \emph{before} the usual % \texttt{every chip node} style. % % \begin{macrocode} \def\chit@@@#1#2(#3){% \chit@dbg{5}{Chit final: ^^J Options: #1 ^^J Position: #2 ^^J Name: `#3'} \let\name\pgfutil@empty% \chit@dbg{1}{=== Before chit node}% \node[chit={/tikz/every chit/.try,id=#3,#1}] (tmp) at (#2) {}; \chit@dbg{2}{=== After chit node}% \ifx|#3|\relax% \else% \chit@dbg{3}{=== Renaming chit to user defined name `#3'}% \pgfnoderename{#3}{tmp}% \fi% \@ifnextchar;{\@gobble}{}% } % \end{macrocode} % \end{Macro} % \iffalse % % -------------------------------------------------------------------- % \fi