%% ttb_en.sec4.tex %% Copyright 2003-2005 Nicolas Markey % % This work may be distributed and/or modified under the % conditions of the LaTeX Project Public License, either version 1.3 % of this license or (at your option) any later version. % The latest version of this license is in % http://www.latex-project.org/lppl.txt % and version 1.3 or later is part of all distributions of LaTeX % version 2003/12/01 or later. % % This work has the LPPL maintenance status "maintained". % The Current Maintainer of this work is Nicolas Markey % % This work consists of the files % ttb_en.tex % ttb_en.sec1.tex ttb_en.sec2.tex ttb_en.sec3.tex % ttb_en.sec4.tex ttb_en.sec5.tex ttb_style.sty % local.bib idxstyle.ist Makefile % and the derived ttb_en.dvi, ttb_en.ps and ttb_en.pdf \mypart{Bibliography style (\protect\niext{bst}) files}\label{bst} \parttoc \mtcskip \mysection{What's that?} The \ext{bst} file is responsible for building the reference list. It is crucial to distinguish between the role of \bt and the role of \LaTeX, and, inside the role of \bt, between what is done by the style file and what should be done in the \ext{bib} file. Roughly speaking, \bt reads three files, in the following order: The \ext{aux} file first, where it finds the name of the style file to be used, the name of the database(s), and the list of cited entries. The \ext{bst} file is read next, and the \ext{bib} file last. The \ext{bst} file tell \bt what to do with each cited entry. Namely: \begin{itemize} \item Which entry-type are defined; \item Which fields are mandatory, or just allowed, depending on the entry; \item And, mainly, how to handle all that stuff in order to produce a clean, \LaTeX-able bibliography. \end{itemize} In view of this, \bt uses a language with two types of instructions: The so-called \emph{commands}\index{bibtex}{command}, first, and the \emph{internal functions}\index{bibtex}{internal function}. The following section deals with commands, and the other ones with internal functions. \mysection{The structure of a \protect\niext{bst} file} Here is, roughly speaking, the structure of a \ext{bst} file: \begin{myexv} \begin{verbatimtab} ENTRY { ... } { ... } { ... } INTEGERS { ... } STRINGS { ... } MACRO { ... }{ ... } FUNCTION { ... }{ ... } READ EXECUTE { ... } ITERATE { ... } SORT ITERATE { ... } REVERSE { ... } EXECUTE { ... } \end{verbatimtab} \end{myexv} This example shows all the commands\index{bibtex}{command} understood by \bt. Here is their meaning: \begin{description} \item[\texttt{ENTRY}]\index{bibtex}{entry@\texttt{ENTRY}}: This command defines the list of all possible fields. More precisely, it takes three arguments (between braces), defining the list of possible ``external'' (string) entries\footnote{Except the \chp{crossref} field, which is added automatically by \bt.}, the list of ``internal'' integer variables, and a list of ``internal'' string variables. Those variables are used for internal computations of \bt, for instance when building the label with the \bst{alpha} style. Inside braces, variable names are separated with spaces. I shall also mention that \bt does not distinguish between upper- and lowercase in the names of functions and variables. I will generally write command names in uppercase, and everything else in lowercase. For instance, \bst{plain} starts with: \begin{myexv} \begin{verbatimtab} ENTRY { address author booktitle ... volume year } {} { label } \end{verbatimtab} \end{myexv} \noindent This defines the classical fields, plus an internal string variable for the label. In fact, \bst{plain} uses numbers as labels, but remember that the length of the longest label has to be evaluated and given as argument to the \env{thebibliography} environment. This is the only reason why this \verb+label+ variable is defined. Note that \texttt{ENTRY} must appear once and only once in each style file. \item[\texttt{INTEGERS}]\index{bibtex}{integers@\texttt{INTEGERS}}: This command declares integer variables\footnote{Those variables are not linked with any entry, contrary to variables defined in the second argument of \texttt{ENTRY}.}. The argument of this command is a space-separated list of names. \item[\texttt{STRINGS}]\index{bibtex}{strings@\texttt{STRINGS}}: This commands defines string variables in the same way as \texttt{INTEGERS} defines integer variables. Contrary to integer variables, string variables are very ``expensive'', and \bt limits the number of such variables to twenty. You should really spare string variables if you plan to develop a large style file. \item[\texttt{MACRO}]\index{bibtex}{macro@\texttt{MACRO}}: This command defines abbreviations, in the same way as \ent{string} does\footnote{Note that \ent{string} has nothing to do with \texttt{STRINGS}\index{bibtex}{strings@\texttt{STRINGS}}...}. If an abbreviation is defined in both the \ext{bst} and in the \ext{bib} file, the definition in the \ext{bib} file is used. Also note that you can define \ent{string} definitions involving \texttt{MACRO} definitions. But this is probably not a good advice... As regards the syntax, \texttt{MACRO} requires two arguments, the first one being the name of the abbreviation to be defined, the second one being the definition itself. It must be a string surrounded with double-quotes. As an example, standard style files define the following: \begin{myexv} \begin{verbatimtab} MACRO {jan} {"January"} MACRO {feb} {"February"} MACRO {mar} {"March"} ... \end{verbatimtab} \end{myexv} \item[\texttt{FUNCTION}]\index{bibtex}{function@\texttt{FUNCTION}}: The most useful command: It allows to define macro functions that will be executed later on. The first argument is the name of the function, the second one is its definition. No example for the moment since there will be numerous ones in the following. \item[\texttt{READ}]\index{bibtex}{read@\texttt{READ}}: As for \texttt{ENTRY}, this command must occur exactly once in any \ext{bst} style file. This is not surprising since it tells \bt to read the \ext{bib} file: Reading it several time would not change anything, and not reading it would seriously limit the interest of the bibliography style. So, that command extracts from the \ext{bib}-file the entries that are cited in the \ext{aux} file. Commands \texttt{ENTRY} and \texttt{MACRO} should appear before \texttt{READ}, while \texttt{ITERATE} and \texttt{REVERSE} may only appear after. \item[\texttt{EXECUTE}]\index{bibtex}{execute@\texttt{EXECUTE}}: This executes the function whose name is given as argument. Note that the function must have been defined earlier. The argument could also be a sequence of \bt internal functions. For some more comments, see the description of \texttt{ITERATE} below. \item[\texttt{ITERATE}]\index{bibtex}{iterate@\texttt{ITERATE}}: This commands also execute the function given in the argument, but contrary to \texttt{EXECUTE}, the function is executed as many times as the number of entries imported by \texttt{READ}. The function may use the fields of each entry. \texttt{EXECUTE} only executes its argument once, and it can not use any field of any entry. \item[\texttt{SORT}]\index{bibtex}{sort@\texttt{SORT}}: This command sorts the entries according to the variable \fn{sort.key}. That special variable is a string variable, implicitly declared for each entry, and that can be set by \texttt{ITERATE}{}ing a function. The entries are then sorted alphabetically according to that string. Of course, some styles won't sort the entries, in which case they will appear in the same order as in the document. \item[\texttt{REVERSE}]\index{bibtex}{reverse@\texttt{REVERSE}}: Like \texttt{ITERATE}, but from the last entry to the first one. \end{description} That's all for the list of commands. You probably can imagine how this will be set up. It remains to define the relevant \texttt{FUNCTION}{}s... This is the subject of the next two sections: We will first see the notation used by \bt, and then how to define functions. \mysection{Reverse Polish Notation} \bt uses the so-called Reverse Polish Notation. This is the main reason why people say that \bt language is hard to understand. It is a stack-based language: You put arguments on a stack (think of a stack of plates), and each function takes as many arguments as necessary on the top of the stack, and replace them with its result. Addition, for instance, will take the first two elements on the stack, add them, and put the result on the top of the stack. Another example\footnote{This part is crucial, that's why I insist on it. But if you really understood how it works, you can skip the explanation.}: \verb/ 1 3 5 + 2 3 * - / is executed as follows: \begin{itemize} \item \verb+1+ is put on the stack. Assuming the stack was initially empty, it now contains \verb+1+; \item \verb+3+ is then put on the stack, which now contains \verb+1+ and \verb+3+ (\verb+3+ being on the top of the stack); \item \verb+5+ is added on the stack, which now contains \verb+1+, \verb+3+ and \verb+5+; \item \verb/+/ is a binary operator: it reads (and removes) the topmost two elements on the stack, which are \verb+5+ and \verb+3+, adds them, and put the resulting value, \verb+8+, on the top of the stack. The stack is now \verb+1+, \verb+8+, with \verb+8+ being on the top; \item \verb+2+ is put on the top of the stack; \item \verb+3+ is put on the stack. It now contains \verb+1+, \verb+8+, \verb+2+ and \verb+3+. \item \verb+*+ is applied to the topmost two elements, which are removed. The resulting value\footnote{We assume that $\mathtt *$ is the multiplication in that example, but it is not the case in \bt. In fact, there is no multiplication operator in \bt, as we will see later, and $\mathtt{*}$ is the concatenation on strings.}~$3\times 2=6$ is put on top of the stack, which is now made of \verb+1+, \verb+8+ and \verb+6+. \item \verb+-+ is now applied to \verb+6+ and \verb+8+. As defined in \bt\footnote{This operator is not commutative, and it could have been defined in the other way.}, the first value, \verb+6+, is subtracted to the second one, \verb+8+. Finally, the stack contains \verb+1+ and \verb+2+. \end{itemize} If you did not understand this example, you'd better re-read it, or try to find more informations somewhere. This is really the core of \bt language, and you'll probably won't understand anything below if you did not understand this example. But for most of you, it should be ok, and we can tackle the most exciting part. \mysection{Internal functions} The table below describes all internal functions\index{bibtex}{internal function}. For each of them, I give \begin{itemize} \item on the left, the items it requires to be present on the top of the stack, the rightmost item being the uppermost on the stack; \item on the right, what the function puts on the top of the stack. \end{itemize} I will use the following conventions: \el I represents an integer, \el S is a string, \el F is a function, \el N is a variable name\footnote{A variable name is a name that has been declared with \texttt{STRINGS} or \texttt{INTEGERS}, or with \texttt{ENTRY}. Moreover, it must be preceded with a single quote, so that \bt understands that you mean the name of the variable and not its value. For instance, \texttt{'label}.}, \el C is the name of a field declared with \texttt{ENTRY}\footnote{It could also be \chp{crossref}, which is implicitly declared by \bt.}, and \el E is an item that can be either a string or an integer.. \begin{longtable}{|>{\vrule height9pt depth5pt width0pt}rlr|p{.58\textwidth}<{\vrule height5pt depth7pt width0pt}|} \hline\endhead \hline\endfirsthead \hline\endfoot \hline\endlastfoot \eli I1 \eli I2 & \texttt+ & (\eli I1$+$\el I2) & integer addition\footnotemark; \\ \noalign{\footnotetext{Integers must be preceded with a \texttt\#. For instance, if you want to compute $2+5$, you'll enter \texttt{\#2 \#5 +}. Negative numbers are entered with \texttt{\#-3}, for instance. }} \eli I1 \eli I2 & \texttt- & (\eli I1$-$\eli I2) & integer subtraction; \\ \eli I1 \eli I2 & \texttt> & \el I & returns $1$ if \eli I1 is strictly greater than \eli I2, and~$0$ otherwise\footnotemark;\\ \noalign{\footnotetext{There is no boolean type in \bt, because integers are sufficient. Negative numbers (including $0$) mean \texttt{false}, and strictly positive mean \texttt{true}.}} \eli I1 \eli I2 & \texttt< & \el I & returns $1$ if \eli I2 is strictly greater than \eli I1, and $0$ otherwise; \\ \eli I1 \eli I2 & \texttt= & \el I & returns $1$ if both integers are equal, and $0$ otherwise;\\ \eli S1 \eli S2 & \texttt = & \el I & returns $1$ if both strings are equal, and $0$ otherwise;\\ \eli S1 \eli S2 & \texttt* & (\eli S1\eli S2) & concatenates both strings\footnotemark; \\ \noalign{\footnotetext{As mentioned earlier, there is not multiplication in \bt{}\footnotemark.}}% \noalign{\footnotetext{We will define one later, since it may be useful.}} \el E \el N & \texttt{:=} & & assignment operation. Provided that variable \el N has the same type as item \el E, it is set to that value; \\ \el S & \fn{add.period} & \el S & adds a period at the end of string \el S, except if \el S already ends with a period, or an exclamation or question mark (after removing right braces); \\ & \fn{call.type} && executes the function whose name is the type of the current entry. For instance, for an entry \nient{book}, it runs the function \texttt{book}. Of course, this command cannot be executed through an \texttt{EXECUTE} command, it can only be called with \texttt{ITERATE} or \texttt{REVERSE}. This explains how to add new entry-types: you simply have to define a function whose name is the entry-type. If an entry-type is used and the corresponding function has not been defined before the \texttt{READ} command, \bt will complain; \\ \el S \texttt{"t"} & \fn{change.case} & \el S & turns \el S to lower case, except for the first letter and for letters that appear at brace-depth strictly positive. Remember that special characters are at depth~0; \\ \el S \texttt{"l"} & \fn{change.case} & \el S & turns \el S to lower case, except parts that are at strictly positive brace-depth; \\ \el S \texttt{"u"} & \fn{change.case} & \el S & turns \el S to upper case, except... \\ \el S & \fn{chr.to.int} & \el I & if \el S contains only one character (in the classical sense, \emph{i.e.} not considering special characters), returns its ASCII code; \\ & \fn{cite} & \el S & puts on the stack the internal key of the current entry. Only meant to be used with \texttt{ITERATE} or \texttt{REVERSE}, of course;\\ \el E & \fn{duplicate} & \el E \el E & adds a copy of the first item on the top of the stack;\\ \el E & \fn{empty} & \el I & adds $1$ on the top of the stack if \el E is an empty string or an empty (but defined) field, and $0$ otherwise; \\ \eli S1 \el I \eli S2 & \fn{format.name} & \el S & extract the \el I-th name of string \eli S1 (in which names are separated by \texttt{and}), and formats it according to specification given by string \eli S2. I can't explain all that here, see the next section for more details; \\ & \fn{global.max} & \el I & put on the stack the maximal length allowed for strings. This is useful to ensure that a string obtained by concatenation is not too long, but the value is generally quite high (5000~characters); \\ \el I \eli F1 \eli F2 & \fn{if} && execute \eli F1 if \el I is strictly positive, and \eli F2 otherwise; \\ \el I & \fn{int.to.chr} & \el S & turns \el I to its corresponding character in the ASCII table. \el I must be between $0$ and $127$; \\ \el I & \fn{int.to.str} & \el S & turns an integer to the equivalent string\footnotemark; \\ \noalign{\footnotetext{Scientists would remark that I did not define the equivalence relation I deal with. I think an example will be sufficient: if \el I is 147, the equivalent string is \texttt{"147"}.}} \el C & \fn{missing} & \el I & returns $1$ if field \el C has been defined in the current entry, and $0$ otherwise;\\ & \fn{newline} & & flushes the output buffer to the \ext{bbl} file, and starts a new line; \\ \el S & \fn{num.names} & \el I & returns the number of names in string \el S. This is done by counting the number of occurrences of \texttt{and}, surrounded with spaces and at level~$0$, and adding~$1$; \\ \el E & \fn{pop} & & removes the topmost item on the stack; \\ & \fn{preamble} & \el S & puts on the stack a string made of the concatenation of all \chp{preamble} declarations found in the \ext{bib} file; \\ \el S & \fn{purify} & \el S & removes all non-alphanumeric characters of string~\el S. More precisely, this functions preserves letters and numbers and spaces, replaces each tabulation, hyphen and tilde with a space, and removes other standard characters, namely characters not listed above and appearing in the table given in appendix~C of the \TeX{}book. Special characters are an exception: \LaTeX commands are removed, as well as spaces, tabulations, hyphens and tildes. Only numbers and letters appearing outside \LaTeX command names are preserved.% \label{purify} Practically, this commands is used for cleaning strings before comparing them, when sorting entries. This is why it is important to keep only ``known'' characters. I insists on the fact that ``\texttt{\bs'e}'' and ``\texttt{\'e}'' are different, from this point of view, since the first one will be transformed into an \texttt e, while the second one will be unchanged, but, when sorting, will be put after the standard 26~letters. \\ & \fn{quote} & \el S & adds the 1-character string \verb+"+ on the stack;\\ & \fn{skip} && does nothing; \\ & \fn{sort.key} & \el S & this function is in fact a string variable, implicitly declared for each entry, and that is used by \texttt{SORT}. It must therefore be defined accordingly before sorting; \\ ... \el E \el E& \fn{stack} && clears the stack, and prints its contents on standard output (not in the output file); \\ \el S \eli I1 \eli I2 & \fn{substring} & \el S & extracts from \el S the string of length \eli I2 starting at position~\eli I1. By convention, the first character is at position~$1$. Note that special characters and braces are not considered here, so that the substring of \verb+{\LaTeX}+ of length~3 starting at position~2 is \verb+\LaT+; \\ \eli E1 \eli E2 & \fn{swap} & \eli E2 \eli E1 & swaps both topmost items on the stack; \\ \el S & \fn{text.length} & \el I & returns the number of characters of \el S, special characters being considered as only one character, and braces being omitted; \label{textlength} \\ \el S \el I & \fn{text.prefix} & \el S & returns the first \el I characters of \el S, still considering special characters as only one character, and omitting braces. Braces are output, however. For instance, the prefix of length~3 of \verb+{{\LaTeX}}1234+ is \verb+{{\LaT}}+, while it is \verb+{\LaTeX}12+ for \verb+{\LaTeX}1234+; \\ \el E & \fn{top} && echoes the first item of the stack on standard output (not in the output file) and removes it from the stack; \\ & \fn{type} & \el S & adds on the stack the type of the current entry; \\ \el S & \fn{warning} && writes \el S in a warning message on the standard output; \\ \eli F1 \eli F2 & \fn{while} & & successively executes \eli F1 and \eli F2 while \eli F1 returns a strictly positive value. \eli F1 has to return an integer; \\ \el S & \fn{width} &\el I& returns the length of string \el S, in hundredths of a point, when written using font \emph{cmr}10 of June 1987. You probably don't mind the details... This function is used for comparing widths of labels, the longest label being passed as the argument of the \env{thebibliography} environment; \\ \el S & \fn{write} && write \el S in the output \ext{bbl} file. \end{longtable} We're done. This should be sufficient for defining plenty of functions for managing entries, sorting them, label them and typeset them. Before using them, I promised to explain how \fn{format.name} works. \mysection{The \protect\nifn{format.name} function}\label{noms-start} This function is quite complicated. The syntax is as follows: \begin{center} \begin{minipage}{.8\textwidth} \eli S1 \el I \eli S2 \ \fn{format.name}\ \el S \end{minipage} \end{center} The first argument \eli S1 is generally the content of fields \chp{author} or \chp{editor}. It is a list of names separated with \verb+and+. If names are in one of the three formats recognized by \bt (see section~\ref{author}), \bt will be able to detect the last name, first name, ``von'' and ``complement''. String \eli S2 defines the output format. Here is an example: \begin{center} \begin{minipage}{.8\textwidth} \begin{verbatimtab} "{ff }{vv }{ll}{, jj}" \end{verbatimtab} \end{minipage} \end{center} The format of such a specification is defined as follows: \begin{itemize} \item globally, it is a list of strings, each one being surrounded with braces; \item \verb+ff+ represents the \verb+First+ part, \emph{i.e.} the first name; \verb+ll+ is the \verb+Last+ part, \emph{i.e.} the last name, and \verb+vv+ and \verb+jj+ are the \verb+von+ and \verb+jr+ part of the name; \item \fn{format.name} replaces, in each string of list \el S2, strings \verb+ff+, \verb+ll+, \verb+vv+ and \verb+jj+, with their respective values. If a value is empty, the complete string is removed. Otherwise, the other characters in the string are output. In the example above, for instance, if the \verb+jr+ part is empty, the comma won't be output, and if the \verb+First+ part is not empty, it will be followed with a space. \end{itemize} This should be almost clear, now. I just mention, but you've probably already understood, that the integer \el I indicates that we are working on the \el I-th name of \eli S1. Last, there exists abbreviated forms for name formats. They are used to extract the first letter of first names, for instance. It suffices to replace \verb+{ff }+ with \verb+{f }+. For multiple names in one part (several first names, for instance), the first letter of each name is written, followed with a period. Different names must be separated with a space, a tabulation, a tilde or an hyphen. Tabulations are turned to spaces, tildes and hyphens are preserved. Note that there is no period at the end, and it must be specified by hand by writing \verb+{f. }+. For instance \begin{myexv} \begin{verbatimtab} "Goossens, Michel and Mittelbach, Franck and Samarin, Alexander" #2 "{f. }{vv }{ll}{, jj}" format.name$ \end{verbatimtab} \end{myexv} %$ \noindent returns \textit{F. Mittelbach}. Let's have a look at several other interesting examples: \begin{myexv} \begin{verbatimtab} "Charles Jean Gustave Nicolas de La Vall{\'e}e Poussin" #1 "{vv }{ll}{, f}" format.name$ \end{verbatimtab} \end{myexv} %$ \noindent yields \emph{de La Vall\'ee Poussin, C.J.G.N} without the final period, since we did not ask for it. \begin{myexv} \begin{verbatimtab} "Doppler, {\relax Ch}ristian Andreas" #1 "{f. }{vv }{ll}" format.name$ \end{verbatimtab} \end{myexv} %$ \noindent gives \emph{Ch.~A. Doppler}. Last, \begin{myexv} \begin{verbatimtab} "Jean-Baptiste Poquelin" #1 "{f. }{vv }{ll}" format.name$ \end{verbatimtab} \end{myexv} %$ \noindent outputs \emph{J.-B. Poquelin}. You probably remarked that one problem is still unsolved: For creating labels from author names, we will of course use \fn{format.name}, and we'd like to get \verb+LVP+, say, for a book by La Vall\'ee Poussin. The first idea, of course, is: \begin{myexv} \begin{verbatimtab} "Charles Jean Gustave Nicolas de La Vall{\'e}e Poussin" #1 "{l}" format.name$ \end{verbatimtab} \end{myexv} %$ \noindent which unfortunately gives \emph{L. V. P}, which would look awful as a label. But in fact, the period added between names is a default value, but can be explicitly given. In our case, we would like to replace the period with empty strings: \begin{myexv} \begin{verbatimtab} "Charles Jean Gustave Nicolas de La Vall{\'e}e Poussin" #1 "{l{}}" format.name$ \end{verbatimtab} \end{myexv} %$ \noindent which gives the expected \emph{LVP}. Braces following \verb+l+ mean that nothing should be put between names or letters. It is also possible to add some text only once, before or after the names. Spaces can be entered directly, while text and commands should be put between braces, so that \bt distinguished them with \verb+ff+, \verb+ll+,~... specifications. An example should make this clear: \begin{myexv} \begin{verbatimtab} "Charles Jean Gustave Nicolas de La Vall{\'e}e Poussin" #1 "{{\scshape\bgroup}ff{ }{\egroup}" format.name$ \end{verbatimtab} \end{myexv} %$ \noindent gives \verb+{\scshape\bgroup}Charles Jean Gustave Nicolas{\egroup}+, and thus <<~{\scshape\bgroup}Charles Jean Gustave Nicolas{\egroup}~>>. Note that we had to trick \bt and \LaTeX regarding the \cmd{bgroup}: braces, which are necessary in \bt name specifications, are copied verbatim in the output... \label{noms-end} \medskip Well... Once again, I could stop here, since you know everything, at least from the theoretical point of view. But this would not be a good idea. So the next sections are devoted to some examples and tricks that could be useful. \clearpage \mysection{Some practical tricks} In fact, the main trick to know is how to build a minimal file, in order to test \bt{}'s behavior, for instance for testing the encoding of a name. This basic style file will simply output its result on the standard output. Assume you want to see how \bt cuts the following name: %\begin{myexv} \begin{center} \begin{minipage}{.8\textwidth} \begin{verbatimtab} de la Cierva y Codorn{\'\i}u, Juan \end{verbatimtab} \end{minipage} \end{center} %\end{myexv} %$ The minimal \ext{bst} file must contain \texttt{ENTRY}\index{bibtex}{entry@\texttt{ENTRY}} and \texttt{READ}\index{bibtex}{read@\texttt{READ}} commands, even if we won't use any entry. It must also compute the desired result. Our style file, \verb+min.bst+, will be: \begin{myexv} \begin{verbatimtab} ENTRY {}{}{} FUNCTION {test} {"de la Cierva y Codorn{\'\i}u, Juan" #1 "{ff - }{vv - }{ll}" format.name$ top$} READ EXECUTE{test} \end{verbatimtab} \end{myexv} \noindent This will split the name and write the different parts, separated with hyphens. The \ext{aux} file now: it will simply define the style file to be used: \begin{myexv} \begin{verbatimtab} \bibstyle{min} \end{verbatimtab} \end{myexv} This file, called \verb+min.aux+, contains neither the \cmd{bibdata} precising the \ext{bib} file to use, nor the \cmd{citation}{}s declaring the entries to be extracted. \bt will, of course, complain about that, but will continue the execution anyway. The result is as follows: \begin{myexv} \begin{verbatimtab} % bibtex min This is BibTeX, Version 0.99c (Web2C 7.4.5) The top-level auxiliary file: min.aux The style file: min.bst I found no \citation commands---while reading file min.aux I found no \bibdata command---while reading file min.aux Warning--I didn't find any fields--line 1 of file min.bst Juan - de~la Cierva~y - Codorn{\'\i}u (There were 2 error messages) \end{verbatimtab} \end{myexv} We get the error messages, but also the result, showing that our encoding is not correct (since the \verb+von+ part should only contain \verb+de la+). As regards unbreakable spaces: \bt automatically adds unbreakable spaces instead of the first and last spaces. This provides you with a way to test all your future \bt functions, which can be quite useful since \bt error messages are generally difficult to understand. You can also try to test if \fn{purify} behaves as I said previously. \mysection{Some small simple functions} \mysubsection{Boolean functions} As you know, \bt does not know about booleans. In particular, there is no negation, conjunction or disjunction, while it would be quite useful. Those operations are defined on figure~\ref{fig1}. \begin{figure}[!htbp] \begin{myexv} \begin{verbatimtab} FUNCTION {not} { { #0 } { #1 } if$ } FUNCTION {and} { 'skip$ { pop$ #0 } if$ } FUNCTION {or} { { pop$ #1 } 'skip$ if$ } \end{verbatimtab} \end{myexv} %$ \caption{Basic boolean functions}\label{fig1} \end{figure} Let me just explain the first two: For negation, you assume there is a boolean (\emph{i.e.} an integer) on the top of the stack. Function \fn{if} will test that boolean. If it evaluates to \verb+true+, the function returns \verb+#0+ (\emph{i.e.} \verb+false+), and otherwise it returns \verb+#1+ (\emph{i.e.} \verb+true+). This is precisely what we wanted. For the conjunction: we have two booleans on the stack. Function \fn{if} tests the first one. If it is \verb+true+, then we do nothing (thus leaving the second boolean on the top of the stack, it's value being the result of the conjunction). If it is \verb+false+, the conjunction is false: We remove the second argument and put \verb+#0+ on the top of the stack. \mysubsection{Multiplication} Figure~\ref{fig2} shows how to compute the multiplication of two integers. I won't enter into the details, comments should be sufficient. In the same way, you can try to define integer division, gcd, primality testing,~... But I'm not sure if it is useful. Multiplication can be, as you'll see below. \begin{figure}[!htbp] \begin{myexv} \begin{verbatimtab} INTEGERS { a b } FUNCTION {mult} { 'a := %% we store the first value 'b := %% we store the second value b #0 < %% We remember the sign of b, and {#-1 #0 b - 'b :=} %% then consider its absolute value. {#1} %% if$ %% #0 %% Put 0 on the stack. {b #0 >} %% While b is strictly positive, { %% we add a to the value on the stack a + %% and decrement b. b #1 - 'b := %% } %% while$ %% swap$ %% Last, we take the opposite 'skip$ %% if b was negative. {#0 swap$ -} %% if$ %% } \end{verbatimtab} \end{myexv} \caption{The ``multiplication'' function}\label{fig2} \end{figure} \mysubsection{Converting a string to an integer} There is no direct way for converting a string (made of digits) to the corresponding integer. We will define a function achieving this, and returning an error message whenever the string is not a number. This is done recursively, as shown on figure~\ref{fig3}. \begin{figure}[!htbp] \begin{myexv} \begin{verbatimtab} FUNCTION {chr.to.value} %% The ASCII code of a character { chr.to.int$ #48 - %% ASCII value of "0" -> 48 duplicate$ duplicate$ %% "1" -> 49 #0 < swap$ #9 > or %% ... { %% "9" -> 57 #48 + int.to.chr$ " is not a number..." * warning$ %% Return 0 if it is not a number pop$ #0 %% } {} if$ } FUNCTION {str.to.int.aux} %% The auxiliary function { {duplicate$ empty$ not} %% While the string is not empty { %% consider its first char swap$ #10 mult 'a := %% and ``add'' it at the end of duplicate$ #1 #1 substring$ %% the result. chr.to.value a + swap$ #2 global.max$ substring$ } while$ pop$ } FUNCTION {str.to.int} { %% Handling negative values duplicate$ #1 #1 substring$ "-" = {#1 swap$ #2 global.max$ substring$} {#0 swap$} if$ %% Initialization, and then #0 swap$ str.to.int.aux %% call to the aux. funtion swap$ {#0 swap$ -} %% And handle the sign. {} if$ } \end{verbatimtab} \end{myexv} %$ \caption{Converting a string to an integer}\label{fig3} \end{figure} There are several interesting points: first, it requires boolean functions, and multiplications. Those functions must thus be added before the above definitions. Moreover, function \verb+chr.to.value+ emphasizes an important rule of thumb: A function must always behave in the same way as regards the stack: Same type and numbers of inputs, same type and number of outputs. For instance, here, if the character is not an integer, we complain, but we return an integer, as if everything was ok. This rule is very important unless you want to spend some time in debugging. \mysubsection{Counting the number of characters in a string} As we saw on page~\pageref{textlength}, \fn{text.length} counts the number of characters in a string, but assuming \bt's meaning of ``character''. In fact, the only function that assumes the standard definition of a character is \fn{substring}. We will use it repeatedly for counting the number of characters of a string, by computing the successive prefixes until they equal the original string. \begin{figure}[!htbp] \begin{myexv} \begin{verbatimtab} INTEGERS{ l } FUNCTION{ string.length } { #1 'l := {duplicate$ duplicate$ #1 l substring$ = not} {l #1 + 'l :=} while$ pop$ l } \end{verbatimtab} \end{myexv} %$ \caption{A function for counting the \emph{real} number of characters}\label{fig4} \end{figure} As an exercise, the reader can try to implement another algorithm: removing one after the other the first characters of the string until the resulting string is empty. \mysubsection{A ``search-and-replace'' function} With the function above, we can now design an algorithm for searching and replacing the occurrences of a string in a given text. Once again, we cannot use \fn{text.length} and \fn{text.prefix} since they assume a special definition of a character. We only use the function \verb+string.length+ and \fn{substring}. The idea is to successively extract the first $n$ characters of the text, compare them with the pattern, and replace it or drop the first character, depending on the result of the comparison. \begin{figure}[!htbp] \begin{myexv} \begin{verbatimtab} STRINGS{replace find text} INTEGERS{find_length} FUNCTION{find.replace} { 'replace := 'find := 'text := find string.length 'find_length := "" { text empty$ not } { text #1 find_length substring$ find = { replace * text #1 find_length + global.max$ substring$ 'text := } { text #1 #1 substring$ * text #2 global.max$ substring$ 'text := } if$ } while$ } \end{verbatimtab} \end{myexv} %$ \caption{Search-and-replacing with \bt}\label{fig5} \end{figure} This function replaces all the occurrences of the pattern, but it can easily be adapted for replacing only the first occurrence. As an exercise, the reader can try to implement the same algorithm using only two string variables\footnote{Hint: try to leave \texttt{find} on the stack.} (it may be important to spare string variables since their number is very limited).