% \iffalse meta-comment % %% File: l3fp.dtx % % Copyright (C) 2011-2024 The LaTeX Project % % It may be distributed and/or modified under the conditions of the % LaTeX Project Public License (LPPL), either version 1.3c of this % license or (at your option) any later version. The latest version % of this license is in the file % % https://www.latex-project.org/lppl.txt % % This file is part of the "l3kernel bundle" (The Work in LPPL) % and all files in that bundle must be distributed together. % % ----------------------------------------------------------------------- % % The development version of the bundle can be found at % % https://github.com/latex3/latex3 % % for those people who are interested. % %<*driver> \documentclass[full,kernel]{l3doc} \usepackage{amsmath} \begin{document} \DocInput{\jobname.dtx} \end{document} % % \fi % % ^^A need to provide this inside the file: % % \providecommand\nan{\texttt{NaN}} % % % \title{^^A % The \pkg{l3fp} module\\ Floating points^^A % } % % \author{^^A % The \LaTeX{} Project\thanks % {^^A % E-mail: % \href{mailto:latex-team@latex-project.org} % {latex-team@latex-project.org}^^A % }^^A % } % % \date{Released 2024-12-09} % % \maketitle % % \begin{documentation} % % A decimal floating point number is one which is stored as a significand and a % separate exponent. The module implements expandably a wide set of % arithmetic, trigonometric, and other operations on decimal floating point % numbers, to be used within floating point expressions. \emph{Floating point % expressions} (\enquote{\meta{fp expr}}) support the following operations with their usual % precedence. % \begin{itemize} % \item Basic arithmetic: addition $x+y$, subtraction $x-y$, % multiplication $x*y$, division $x/y$, square root~$\sqrt{x}$, % and parentheses. % \item Comparison operators: $x\mathop{\mathtt{<}}y$, % $x\mathop{\mathtt{<=}}y$, $x\mathop{\mathtt{>?}}y$, % $x\mathop{\mathtt{!=}}y$ \emph{etc.} % \item Boolean logic: sign $\operatorname{sign} x$, % negation $\mathop{!}x$, conjunction % $x\mathop{\&\&}y$, disjunction $x\mathop{\vert\vert}y$, ternary % operator $x\mathop{?}y\mathop{:}z$. % \item Exponentials: $\exp x$, $\ln x$, $x^y$, $\operatorname{logb} x$. % \item Integer factorial: $\operatorname{fact} x$. % \item Trigonometry: $\sin x$, $\cos x$, $\tan x$, $\cot x$, $\sec % x$, $\csc x$ expecting their arguments in radians, and % $\operatorname{sind} x$, $\operatorname{cosd} x$, % $\operatorname{tand} x$, $\operatorname{cotd} x$, % $\operatorname{secd} x$, $\operatorname{cscd} x$ expecting their % arguments in degrees. % \item Inverse trigonometric functions: $\operatorname{asin} x$, % $\operatorname{acos} x$, $\operatorname{atan} x$, % $\operatorname{acot} x$, $\operatorname{asec} x$, % $\operatorname{acsc} x$ giving a result in radians, and % $\operatorname{asind} x$, $\operatorname{acosd} x$, % $\operatorname{atand} x$, $\operatorname{acotd} x$, % $\operatorname{asecd} x$, $\operatorname{acscd} x$ giving a result % in degrees. % \item [\emph{(not yet)}] Hyperbolic functions and their inverse % functions: $\sinh x$, $\cosh x$, $\tanh x$, $\coth x$, % $\operatorname{sech} x$, $\operatorname{csch}$, and % $\operatorname{asinh} x$, $\operatorname{acosh} x$, % $\operatorname{atanh} x$, $\operatorname{acoth} x$, % $\operatorname{asech} x$, $\operatorname{acsch} x$. % \item Extrema: $\max(x_{1},x_{2},\ldots)$, $\min(x_{1},x_{2},\ldots)$, % $\operatorname{abs}(x)$. % \item Rounding functions, controlled by two optional % values, $n$ (number of places, $0$ by default) and % $t$ (behavior on a tie, $\nan$ by default): % \begin{itemize} % \item $\operatorname{trunc}(x,n)$ rounds towards zero, % \item $\operatorname{floor}(x,n)$ rounds towards~$-\infty$, % \item $\operatorname{ceil}(x,n)$ rounds towards~$+\infty$, % \item $\operatorname{round}(x,n,t)$ rounds to the closest value, with % ties rounded to an even value by default, towards zero if $t=0$, % towards $+\infty$ if $t>0$ and towards $-\infty$ if $t<0$. % \end{itemize} % And \emph{(not yet)} modulo, and \enquote{quantize}. % \item Random numbers: $\operatorname{rand}()$, $\operatorname{randint}(m,n)$. % \item Constants: \texttt{pi}, \texttt{deg} (one degree in radians). % \item Dimensions, automatically expressed in points, \emph{e.g.}, % \texttt{pc} is~$12$. % \item Automatic conversion (no need for \cs[no-index]{\meta{type}_use:N}) of % integer, dimension, and skip variables to floating point numbers, % expressing dimensions in points and ignoring the stretch and % shrink components of skips. % \item Tuples: $(x_1,\ldots{},x_n)$ that can be stored in variables, % added together, multiplied or divided by a floating point number, % and nested. % \end{itemize} % Floating point numbers can be given either explicitly (in a form such % as |1.234e-34|, or |-.0001|), or as a stored floating point variable, % which is automatically replaced by its current value. % A \enquote{floating point} is a floating point number or a tuple thereof. See % section~\ref{sec:l3fp:fp-floats} for a description of what a floating point is, % section~\ref{sec:l3fp:fp-precedence} for details about how an expression is % parsed, and section~\ref{sec:l3fp:fp-operations} to know what the various % operations do. Some operations may raise exceptions (error messages), % described in section~\ref{sec:l3fp:fp-exceptions}. % % An example of use could be the following. % \begin{verbatim} % \LaTeX{} can now compute: $ \frac{\sin (3.5)}{2} + 2\cdot 10^{-3} % = \ExplSyntaxOn \fp_to_decimal:n {sin(3.5)/2 + 2e-3} $. % \end{verbatim} % The operation \texttt{round} can be used to limit the result's % precision. Adding $+0$ avoids the possibly undesirable output |-0|, % replacing it by |+0|. However, the \pkg{l3fp} module is mostly meant % as an underlying tool for higher-level commands. For example, one % could provide a function to typeset nicely the result of floating % point computations. % \begin{verbatim} % \documentclass{article} % \usepackage{siunitx} % \ExplSyntaxOn % \NewDocumentCommand { \calcnum } { m } % { \num { \fp_to_scientific:n {#1} } } % \ExplSyntaxOff % \begin{document} % \calcnum { 2 pi * sin ( 2.3 ^ 5 ) } % \end{document} % \end{verbatim} % See the documentation of \pkg{siunitx} for various options of % \cs{num}. % % \section{Creating and initialising floating point variables} % % \begin{function}[updated = 2012-05-08, tested = m3fp001] % {\fp_new:N, \fp_new:c} % \begin{syntax} % \cs{fp_new:N} \meta{fp~var} % \end{syntax} % Creates a new \meta{fp~var} or raises an error if the name is % already taken. The declaration is global. The \meta{fp~var} is % initially~$+0$. % \end{function} % % \begin{function}[updated = 2012-05-08, tested = m3fp001] % {\fp_const:Nn, \fp_const:cn} % \begin{syntax} % \cs{fp_const:Nn} \meta{fp~var} \Arg{fp expr} % \end{syntax} % Creates a new constant \meta{fp~var} or raises an error if the name % is already taken. The \meta{fp~var} is set globally equal to % the result of evaluating the \meta{fp expr}. % \end{function} % % \begin{function}[updated = 2012-05-08, tested = m3fp001] % {\fp_zero:N, \fp_zero:c, \fp_gzero:N, \fp_gzero:c} % \begin{syntax} % \cs{fp_zero:N} \meta{fp~var} % \end{syntax} % Sets the \meta{fp~var} to~$+0$. % \end{function} % % \begin{function}[updated = 2012-05-08, tested = m3fp001] % {\fp_zero_new:N, \fp_zero_new:c, \fp_gzero_new:N, \fp_gzero_new:c} % \begin{syntax} % \cs{fp_zero_new:N} \meta{fp~var} % \end{syntax} % Ensures that the \meta{fp~var} exists globally % by applying \cs{fp_new:N} if necessary, then applies % \cs[index=fp_zero:N]{fp_(g)zero:N} to leave the \meta{fp~var} set to~$+0$. % \end{function} % % \section{Setting floating point variables} % % \begin{function}[updated = 2012-05-08, tested = m3fp002] % { % \fp_set:Nn, \fp_set:cn, \fp_set:NV, \fp_set:cV, % \fp_gset:Nn, \fp_gset:cn, \fp_gset:NV, \fp_gset:cV % } % \begin{syntax} % \cs{fp_set:Nn} \meta{fp~var} \Arg{fp expr} % \end{syntax} % Sets \meta{fp~var} equal to the result of computing the % \meta{fp expr}. % \end{function} % % \begin{function}[updated = 2012-05-08, tested = m3fp002] % { % \fp_set_eq:NN , \fp_set_eq:cN , \fp_set_eq:Nc , \fp_set_eq:cc , % \fp_gset_eq:NN, \fp_gset_eq:cN, \fp_gset_eq:Nc, \fp_gset_eq:cc % } % \begin{syntax} % \cs{fp_set_eq:NN} \meta{fp~var_1} \meta{fp~var_2} % \end{syntax} % Sets the floating point variable \meta{fp~var_1} equal to the current % value of \meta{fp~var_2}. % \end{function} % % \begin{function}[updated = 2012-05-08, tested = m3fp002] % {\fp_add:Nn, \fp_add:cn, \fp_gadd:Nn, \fp_gadd:cn} % \begin{syntax} % \cs{fp_add:Nn} \meta{fp~var} \Arg{fp expr} % \end{syntax} % Adds the result of computing the \meta{fp expr} to % the \meta{fp~var}. % This also applies if \meta{fp~var} and \meta{floating point % expression} evaluate to tuples of the same size. % \end{function} % % \begin{function}[updated = 2012-05-08, tested = m3fp002] % {\fp_sub:Nn, \fp_sub:cn, \fp_gsub:Nn, \fp_gsub:cn} % \begin{syntax} % \cs{fp_sub:Nn} \meta{fp~var} \Arg{fp expr} % \end{syntax} % Subtracts the result of computing the \meta{floating point % expression} from the \meta{fp~var}. % This also applies if \meta{fp~var} and \meta{floating point % expression} evaluate to tuples of the same size. % \end{function} % % \section{Using floating points} % % \begin{function}[EXP, added = 2012-05-08, updated = 2012-07-08, % tested = m3fp-convert003]{\fp_eval:n} % \begin{syntax} % \cs{fp_eval:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and expresses the % result as a decimal number with no % exponent. Leading or trailing zeros may be inserted to compensate % for the exponent. Non-significant trailing zeros are trimmed, and % integers are expressed without a decimal separator. The values % $\pm\infty$ and \nan{} trigger an \enquote{invalid operation} % exception. % For a tuple, each item is converted using \cs{fp_eval:n} and they are combined as % |(|\meta{fp_1}\verb*|, |\meta{fp_2}\verb*|, |\ldots{}\meta{fp_n}|)| % if $n>1$ and |(|\meta{fp_1}|,)| or |()| for fewer items. % This function is identical to \cs{fp_to_decimal:n}. % \end{function} % % \begin{function}[EXP, added = 2018-11-03]{\fp_sign:n} % \begin{syntax} % \cs{fp_sign:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and leaves its sign in the input stream % using \cs{fp_eval:n} |{sign(|\meta{result}|)}|: $+1$ for positive % numbers and for $+\infty$, $-1$ for negative numbers and for % $-\infty$, $\pm 0$ for $\pm 0$. If the operand is a tuple or is % \nan{}, then \enquote{invalid operation} occurs and the result % is~$0$. % \end{function} % % \begin{function}[EXP, added = 2012-05-08, updated = 2012-07-08] % {\fp_to_decimal:N, \fp_to_decimal:c, \fp_to_decimal:n} % \begin{syntax} % \cs{fp_to_decimal:N} \meta{fp~var} % \cs{fp_to_decimal:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and expresses the % result as a decimal number with no % exponent. Leading or trailing zeros may be inserted to compensate % for the exponent. Non-significant trailing zeros are trimmed, and % integers are expressed without a decimal separator. The values % $\pm\infty$ and~\nan{} trigger an \enquote{invalid operation} % exception. % For a tuple, each item is converted using \cs{fp_to_decimal:n} and they are combined as % |(|\meta{fp_1}\verb*|, |\meta{fp_2}\verb*|, |\ldots{}\meta{fp_n}|)| % if $n>1$ and |(|\meta{fp_1}|,)| or |()| for fewer items. % \end{function} % % \begin{function}[EXP, updated = 2016-03-22] % {\fp_to_dim:N, \fp_to_dim:c, \fp_to_dim:n} % \begin{syntax} % \cs{fp_to_dim:N} \meta{fp~var} % \cs{fp_to_dim:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and expresses the % result as a dimension (in~\texttt{pt}) suitable for use in dimension % expressions. The output is identical to \cs{fp_to_decimal:n}, with % an additional trailing~\texttt{pt} (both letter tokens). % In particular, the result may % be outside the range $[- 2^{14} + 2^{-17}, 2^{14} - 2^{-17}]$ of % valid \TeX{} dimensions, leading to overflow errors if used as a % dimension. Tuples, as well as the values $\pm\infty$ and~\nan{}, % trigger an \enquote{invalid operation} exception. % \end{function} % % \begin{function}[EXP, updated = 2012-07-08] % {\fp_to_int:N, \fp_to_int:c, \fp_to_int:n} % \begin{syntax} % \cs{fp_to_int:N} \meta{fp~var} % \cs{fp_to_int:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr}, and rounds the % result to the closest integer, rounding exact ties to an even % integer. % The result may be outside the range $[- 2^{31} + 1, 2^{31} - 1]$ of % valid \TeX{}~integers, leading to overflow errors if used in an % integer expression. Tuples, as well as the values $\pm\infty$ % and~\nan{}, trigger an \enquote{invalid operation} exception. % \end{function} % % \begin{function}[EXP, added = 2012-05-08, updated = 2016-03-22] % {\fp_to_scientific:N, \fp_to_scientific:c, \fp_to_scientific:n} % \begin{syntax} % \cs{fp_to_scientific:N} \meta{fp~var} % \cs{fp_to_scientific:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and expresses the % result in scientific notation: % \begin{quote} % \meta{optional \texttt{-}}\meta{digit}\texttt{.}\meta{15 digits}\texttt{e}\meta{optional sign}\meta{exponent} % \end{quote} % The leading \meta{digit} is non-zero except in the case of $\pm 0$. % The values $\pm\infty$ and~\nan{} trigger an \enquote{invalid % operation} exception. Normal category codes apply: thus the |e| is % category code~$11$ (a letter). % For a tuple, each item is converted using \cs{fp_to_scientific:n} and they are combined as % |(|\meta{fp_1}\verb*|, |\meta{fp_2}\verb*|, |\ldots{}\meta{fp_n}|)| % if $n>1$ and |(|\meta{fp_1}|,)| or |()| for fewer items. % \end{function} % % \begin{function}[EXP, updated = 2016-03-22] % {\fp_to_tl:N, \fp_to_tl:c, \fp_to_tl:n} % \begin{syntax} % \cs{fp_to_tl:N} \meta{fp~var} % \cs{fp_to_tl:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and expresses the % result in (almost) the shortest possible form. Numbers in the % ranges $(0,10^{-3})$ and $[10^{16},\infty)$ are expressed in % scientific notation with trailing zeros trimmed and no decimal % separator when there is a single significant digit (this differs from % \cs{fp_to_scientific:n}). Numbers in the range $[10^{-3},10^{16})$ % are expressed in a decimal notation without exponent, with trailing % zeros trimmed, and no decimal separator for integer values (see % \cs{fp_to_decimal:n}. Negative numbers start with~|-|. The % special values $\pm 0$, $\pm\infty$ and~\nan{} are rendered as % |0|, |-0|, \texttt{inf}, \texttt{-inf}, and~\texttt{nan} % respectively. Normal category codes apply and thus \texttt{inf} or % \texttt{nan}, if produced, are made up of letters. % For a tuple, each item is converted using \cs{fp_to_tl:n} and they are combined as % |(|\meta{fp_1}\verb*|, |\meta{fp_2}\verb*|, |\ldots{}\meta{fp_n}|)| % if $n>1$ and |(|\meta{fp_1}|,)| or |()| for fewer items. % \end{function} % % \begin{function}[EXP, updated = 2012-07-08] % {\fp_use:N, \fp_use:c} % \begin{syntax} % \cs{fp_use:N} \meta{fp~var} % \end{syntax} % Inserts the value of the \meta{fp~var} into the input stream as a % decimal number with no exponent. % Leading or trailing zeros may be inserted to compensate for the % exponent. Non-significant trailing zeros are trimmed. Integers are % expressed without a decimal separator. The values $\pm\infty$ % and~\nan{} trigger an \enquote{invalid operation} exception. % For a tuple, each item is converted using \cs{fp_to_decimal:n} and they are combined as % |(|\meta{fp_1}\verb*|, |\meta{fp_2}\verb*|, |\ldots{}\meta{fp_n}|)| % if $n>1$ and |(|\meta{fp_1}|,)| or |()| for fewer items. % This function is identical to \cs{fp_to_decimal:N}. % \end{function} % % \section{Floating point conditionals} % % \begin{function}[EXP, pTF, updated = 2012-05-08, tested = m3fp002] % {\fp_if_exist:N, \fp_if_exist:c} % \begin{syntax} % \cs{fp_if_exist_p:N} \meta{fp~var} % \cs{fp_if_exist:NTF} \meta{fp~var} \Arg{true code} \Arg{false code} % \end{syntax} % Tests whether the \meta{fp~var} is currently defined. This does not % check that the \meta{fp~var} really is a floating point variable. % \end{function} % % \begin{function}[EXP, pTF, updated = 2012-05-08, % tested = m3fp-logic001]{\fp_compare:nNn} % \begin{syntax} % \cs{fp_compare_p:nNn} \Arg{fp expr_1} \meta{relation} \Arg{fp expr_2} % \cs{fp_compare:nNnTF} \Arg{fp expr_1} \meta{relation} \Arg{fp expr_2} \Arg{true code} \Arg{false code} % \end{syntax} % Compares the \meta{fp expr_1} and the \meta{fp expr_2}, and returns % \texttt{true} if the \meta{relation} is obeyed. Two floating points % $x$ and~$y$ may obey four mutually exclusive relations: % $xy$, or $x?y$ (\enquote{not ordered}). The last % case occurs exactly if one or both operands is~\nan{} or is a tuple, % unless they are equal tuples. Note that a~\nan{} is distinct from % any value, even another~\nan{}, hence $x=x$ is not true for % a~\nan{}. To test if a value is~\nan{}, compare it to an arbitrary % number with the \enquote{not ordered} relation. % \begin{verbatim} % \fp_compare:nNnTF { } ? { 0 } % { } % is nan % { } % is not nan % \end{verbatim} % Tuples are equal if they have the same number of items and items % compare equal (in particular there must be no~\nan{}). % At present any other comparison with tuples yields |?| (not ordered). % This is experimental. % % This function is less flexible than \cs{fp_compare:nTF} but slightly % faster. It is provided for consistency with \cs{int_compare:nNnTF} % and \cs{dim_compare:nNnTF}. % \end{function} % % \begin{function}[EXP, pTF, updated = 2013-12-14, % tested = m3fp-logic001]{\fp_compare:n} % \begin{syntax} % \cs{fp_compare_p:n} \\ % ~~\{ \\ % ~~~~\meta{fp expr_1} \meta{relation_1} \\ % ~~~~\ldots{} \\ % ~~~~\meta{fp expr_N} \meta{relation_N} \\ % ~~~~\meta{fp expr_{N+1}} \\ % ~~\} \\ % \cs{fp_compare:nTF} % ~~\{ \\ % ~~~~\meta{fp expr_1} \meta{relation_1} \\ % ~~~~\ldots{} \\ % ~~~~\meta{fp expr_N} \meta{relation_N} \\ % ~~~~\meta{fp expr_{N+1}} \\ % ~~\} \\ % ~~\Arg{true code} \Arg{false code} % \end{syntax} % Evaluates the \meta{fp exprs} as described for % \cs{fp_eval:n} and compares consecutive result using the % corresponding \meta{relation}, namely it compares \meta{fp expr_1} % and \meta{fp expr_2} using the \meta{relation_1}, then % \meta{fp expr_2} and \meta{fp expr_3} using the \meta{relation_2}, % until finally comparing \meta{fp expr_N} and \meta{fp expr_{N+1}} % using the \meta{relation_N}. The test yields \texttt{true} if all % comparisons are \texttt{true}. Each \meta{floating point % expression} is evaluated only once. Contrarily to % \cs{int_compare:nTF}, all \meta{fp exprs} are % computed, even if one comparison is \texttt{false}. Two floating % points $x$ and~$y$ may obey four mutually exclusive % relations: $xy$, or $x?y$ (\enquote{not ordered}). % The last case occurs exactly if one or both operands is~\nan{} or is % a tuple, unless they are equal tuples. Each \meta{relation} % can be any (non-empty) combination of |<|, |=|, |>|, and~|?|, plus % an optional leading~|!| (which negates the \meta{relation}), with % the restriction that the \meta{relation} may not start with~|?|, as % this symbol has a different meaning (in combination with~|:|) within % floating point expressions. The comparison $x$~\meta{relation}~$y$ % is then \texttt{true} if the \meta{relation} does not start with~|!| % and the actual relation (|<|, |=|, |>|, or~|?|) between $x$ and~$y$ % appears within the \meta{relation}, or on the contrary if the % \meta{relation} starts with~|!| and the relation between $x$ and~$y$ % does not appear within the \meta{relation}. Common choices of % \meta{relation} include |>=|~(greater or equal), |!=|~(not equal), % |!?|~or~|<=>| (comparable). % % This function is more flexible than \cs{fp_compare:nNnTF} and only % slightly slower. % \end{function} % % \begin{function}[pTF, added = 2019-08-25]{\fp_if_nan:n} % \begin{syntax} % \cs{fp_if_nan_p:n} \Arg{fp expr} % \cs{fp_if_nan:nTF} \Arg{fp expr} \Arg{true code} \Arg{false code} % \end{syntax} % Evaluates the \meta{fp expr} and tests whether the result is exactly % \nan{}. The test returns \texttt{false} for any other result, even % a tuple containing \nan{}. % \end{function} % % \section{Floating point expression loops} % % \begin{function}[rEXP, added = 2012-08-16, tested = m3fp-logic003] % {\fp_do_until:nNnn} % \begin{syntax} % \cs{fp_do_until:nNnn} \Arg{fp expr_1} \meta{relation} \Arg{fp expr_2} \Arg{code} % \end{syntax} % Places the \meta{code} in the input stream for \TeX{} to process, % and then evaluates the relationship between the two \meta{floating % point expressions} as described for \cs{fp_compare:nNnTF}. If the % test is \texttt{false} then the \meta{code} is inserted into % the input stream again and a loop occurs until the % \meta{relation} is \texttt{true}. % \end{function} % % \begin{function}[rEXP, added = 2012-08-16, tested = m3fp-logic003] % {\fp_do_while:nNnn} % \begin{syntax} % \cs{fp_do_while:nNnn} \Arg{fp expr_1} \meta{relation} \Arg{fp expr_2} \Arg{code} % \end{syntax} % Places the \meta{code} in the input stream for \TeX{} to process, % and then evaluates the relationship between the two \meta{floating % point expressions} as described for \cs{fp_compare:nNnTF}. If the % test is \texttt{true} then the \meta{code} is inserted into the % input stream again and a loop occurs until the \meta{relation} % is \texttt{false}. % \end{function} % % \begin{function}[rEXP, added = 2012-08-16, tested = m3fp-logic003] % {\fp_until_do:nNnn} % \begin{syntax} % \cs{fp_until_do:nNnn} \Arg{fp expr_1} \meta{relation} \Arg{fp expr_2} \Arg{code} % \end{syntax} % Evaluates the relationship between the two \meta{floating point % expressions} as described for \cs{fp_compare:nNnTF}, and then % places the \meta{code} in the input stream if the \meta{relation} is % \texttt{false}. After the \meta{code} has been processed by \TeX{} % the test is repeated, and a loop occurs until the test is % \texttt{true}. % \end{function} % % \begin{function}[rEXP, added = 2012-08-16, tested = m3fp-logic003] % {\fp_while_do:nNnn} % \begin{syntax} % \cs{fp_while_do:nNnn} \Arg{fp expr_1} \meta{relation} \Arg{fp expr_2} \Arg{code} % \end{syntax} % Evaluates the relationship between the two \meta{floating point % expressions} as described for \cs{fp_compare:nNnTF}, and then % places the \meta{code} in the input stream if the \meta{relation} is % \texttt{true}. After the \meta{code} has been processed by \TeX{} % the test is repeated, and a loop occurs until the test is % \texttt{false}. % \end{function} % % \begin{function}[rEXP, added = 2012-08-16, updated = 2013-12-14, tested = m3fp-logic003] % {\fp_do_until:nn} % \begin{syntax} % \cs{fp_do_until:nn} \{ \meta{fp expr_1} \meta{relation} \meta{fp expr_2} \} \Arg{code} % \end{syntax} % Places the \meta{code} in the input stream for \TeX{} to process, % and then evaluates the relationship between the two \meta{floating % point expressions} as described for \cs{fp_compare:nTF}. If the % test is \texttt{false} then the \meta{code} is inserted into % the input stream again and a loop occurs until the % \meta{relation} is \texttt{true}. % \end{function} % % \begin{function}[rEXP, added = 2012-08-16, updated = 2013-12-14, tested = m3fp-logic003] % {\fp_do_while:nn} % \begin{syntax} % \cs{fp_do_while:nn} \{ \meta{fp expr_1} \meta{relation} \meta{fp expr_2} \} \Arg{code} % \end{syntax} % Places the \meta{code} in the input stream for \TeX{} to process, % and then evaluates the relationship between the two \meta{floating % point expressions} as described for \cs{fp_compare:nTF}. If the % test is \texttt{true} then the \meta{code} is inserted into the % input stream again and a loop occurs until the \meta{relation} % is \texttt{false}. % \end{function} % % \begin{function}[rEXP, added = 2012-08-16, updated = 2013-12-14, tested = m3fp-logic003] % {\fp_until_do:nn} % \begin{syntax} % \cs{fp_until_do:nn} \{ \meta{fp expr_1} \meta{relation} \meta{fp expr_2} \} \Arg{code} % \end{syntax} % Evaluates the relationship between the two \meta{floating point % expressions} as described for \cs{fp_compare:nTF}, and then places % the \meta{code} in the input stream if the \meta{relation} is % \texttt{false}. After the \meta{code} has been processed by \TeX{} % the test is repeated, and a loop occurs until the test is % \texttt{true}. % \end{function} % % \begin{function}[rEXP, added = 2012-08-16, updated = 2013-12-14, tested = m3fp-logic003] % {\fp_while_do:nn} % \begin{syntax} % \cs{fp_while_do:nn} \{ \meta{fp expr_1} \meta{relation} \meta{fp expr_2} \} \Arg{code} % \end{syntax} % Evaluates the relationship between the two \meta{floating point % expressions} as described for \cs{fp_compare:nTF}, and then places % the \meta{code} in the input stream if the \meta{relation} is % \texttt{true}. After the \meta{code} has been processed by \TeX{} % the test is repeated, and a loop occurs until the test is % \texttt{false}. % \end{function} % % \begin{function}[added = 2016-11-21, updated = 2016-12-06, rEXP] % {\fp_step_function:nnnN, \fp_step_function:nnnc} % \begin{syntax} % \cs{fp_step_function:nnnN} \Arg{initial value} \Arg{step} \Arg{final value} \meta{function} % \end{syntax} % This function first evaluates the \meta{initial value}, \meta{step} % and \meta{final value}, each of which should be a floating point % expression evaluating to a floating point number, not a tuple. % The \meta{function} is then placed in front of each \meta{value} % from the \meta{initial value} to the \meta{final value} in turn % (using \meta{step} between each \meta{value}). The \meta{step} must % be non-zero. If the \meta{step} is positive, the loop stops when % the \meta{value} becomes larger than the \meta{final value}. If the % \meta{step} is negative, the loop stops when the \meta{value} % becomes smaller than the \meta{final value}. The \meta{function} % should absorb one numerical argument. For example % \begin{verbatim} % \cs_set:Npn \my_func:n #1 { [I~saw~#1] \quad } % \fp_step_function:nnnN { 1.0 } { 0.1 } { 1.5 } \my_func:n % \end{verbatim} % would print % \begin{quote} % [I saw 1.0] \quad % [I saw 1.1] \quad % [I saw 1.2] \quad % [I saw 1.3] \quad % [I saw 1.4] \quad % [I saw 1.5] \quad % \end{quote} % \begin{texnote} % Due to rounding, it may happen that adding the \meta{step} to the % \meta{value} does not change the \meta{value}; such cases give an % error, as they would otherwise lead to an infinite loop. % \end{texnote} % \end{function} % % \begin{function}[added = 2016-11-21, updated = 2016-12-06] % {\fp_step_inline:nnnn} % \begin{syntax} % \cs{fp_step_inline:nnnn} \Arg{initial value} \Arg{step} \Arg{final value} \Arg{code} % \end{syntax} % This function first evaluates the \meta{initial value}, \meta{step} % and \meta{final value}, all of which should be floating point % expressions evaluating to a floating point number, not a tuple. % Then for each \meta{value} from the \meta{initial value} to the % \meta{final value} in turn (using \meta{step} between each % \meta{value}), the \meta{code} is inserted into the input stream % with |#1| replaced by the current \meta{value}. Thus the % \meta{code} should define a function of one argument~(|#1|). % \end{function} % % \begin{function}[added = 2017-04-12]{\fp_step_variable:nnnNn} % \begin{syntax} % \cs{fp_step_variable:nnnNn} \\ % ~~\Arg{initial value} \Arg{step} \Arg{final value} \meta{tl~var} \Arg{code} % \end{syntax} % This function first evaluates the \meta{initial value}, \meta{step} % and \meta{final value}, all of which should be floating point % expressions evaluating to a floating point number, not a tuple. % Then for each \meta{value} from the \meta{initial value} to the % \meta{final value} in turn (using \meta{step} between each % \meta{value}), the \meta{code} is inserted into the input stream, % with the \meta{tl~var} defined as the current \meta{value}. Thus % the \meta{code} should make use of the \meta{tl~var}. % \end{function} % % \section{Symbolic expressions} % % Floating point expressions support variables: these can only be set locally, % so act like standard \cs[no-index]{l_\dots} variables. % \begin{quote}\let\obeyedline=\newline\obeylines^^A % \cs{fp_new_variable:n} |{ A }| % \cs{fp_set:Nn} \cs{l_tmpb_fp} |{ 1 * sin(A) + 3**2 }| % \cs{fp_show:n} |{| \cs{l_tmpb_fp} |}| % \cs{fp_show:N} \cs{l_tmpb_fp} % \cs{fp_set_variable:nn} |{ A }| |{ pi/2 }| % \cs{fp_show:n} |{| \cs{l_tmpb_fp} |}| % \cs{fp_show:N} \cs{l_tmpb_fp} % \cs{fp_set_variable:nn} |{ A }| |{ 0 }| % \cs{fp_show:n} |{| \cs{l_tmpb_fp} |}| % \cs{fp_show:N} \cs{l_tmpb_fp} % \end{quote} % defines~|A| to be a variable, then defines \cs{l_tmpb_fp} to stand for % |1*sin(A)+9| (note that |3**2| is evaluated, but the |1*|~product is % not simplified away). Until \cs{l_tmpb_fp} is changed, \cs{fp_show:N} % \cs{l_tmpb_fp} will show |((1*sin(A))+9)| regardless of the value % of~|A|. The next step defines~|A| to be equal to~|pi/2|: then % \cs{fp_show:n} |{| \cs{l_tmpb_fp} |}| will evaluate \cs{l_tmpb_fp} and % show~|10|. We then redefine~|A| to be~|0|: since \cs{l_tmpb_fp} still % stands for |1*sin(A)+9|, the value shown is then~|9|. Variables can % be set with \cs{fp_set_variable:nn} to arbitrary floating point % expressions including other variables. % % \begin{function}[added = 2023-10-19]{\fp_new_variable:n} % \begin{syntax} % \cs{fp_new_variable:n} \Arg{identifier} % \end{syntax} % Declares the \meta{identifier} as a variable, which allows it to be % used in floating point expressions. For instance, % \begin{quote} % \cs{fp_new_variable:n} |{ A }| \\ % \cs{fp_show:n} |{ A**2 - A + 1 }| % \end{quote} % shows |(((A^2)-A)+1)|. If the declaration was missing, the parser % would complain about an \enquote{\texttt{Unknown fp word 'A'}}. The % \meta{identifier} must consist entirely of Latin letters among % |[a-zA-Z]|. % \end{function} % % \begin{function}[added = 2023-10-19]{\fp_set_variable:nn} % \begin{syntax} % \cs{fp_set_variable:nn} \Arg{identifier} \Arg{fp expr} % \end{syntax} % Defines the \meta{identifier} to stand in any further expression for % the result of evaluating the \meta{floating point expression} as % much as possible. The result may contain other variables, which are % then replaced by their values if they have any. For instance, % \begin{quote}\let\obeyedline=\newline\obeylines^^A % \cs{fp_new_variable:n} |{ A }| % \cs{fp_new_variable:n} |{ B }| % \cs{fp_new_variable:n} |{ C }| % \cs{fp_set_variable:nn} |{ A } { 3 }| % \cs{fp_set_variable:nn} |{ C } { A ** 2 + B * 1 }| % \cs{fp_show:n} |{ C + 4 }| % \cs{fp_set_variable:nn} |{ A } { 4 }| % \cs{fp_show:n} |{ C + 4 }| % \end{quote} % shows |((9+(B*1))+4)| twice: changing the value of~|A| to~|4| does % not alter~|C| because |A|~was replaced by its value~|3| when % evaluating |A**2+B*1|. % \end{function} % % \begin{function}[added = 2023-10-19]{\fp_clear_variable:n} % \begin{syntax} % \cs{fp_clear_variable:n} \Arg{identifier} % \end{syntax} % Removes any value given by \cs{fp_set_variable:nn} to the variable % with this \meta{identifier}. For instance, % \begin{quote}\let\obeyedline=\newline\obeylines^^A % \cs{fp_new_variable:n} |{ A }| % \cs{fp_set_variable:nn} |{ A } { 3 }| % \cs{fp_show:n} |{ A ^ 2 }| % \cs{fp_clear_variable:n} |{ A }| % \cs{fp_show:n} |{ A ^ 2 }| % \end{quote} % shows~|9|, then~|(A^2)|. % \end{function} % % \section{User-defined functions} % % It is possible to define new user functions which can be used inside % the argument to \cs{fp_eval:n}, etc. These functions may take one or % more named arguments, and should be implemented using expansion methods % only. % % \begin{function}[added = 2023-10-19]{\fp_new_function:n} % \begin{syntax} % \cs{fp_new_function:n} \Arg{identifier} % \end{syntax} % Declares the \meta{identifier} as a function, which allows it to be % used in floating point expressions. For instance, % \begin{quote} % \cs{fp_new_function:n} |{ foo }| \\ % \cs{fp_show:n} |{ foo ( 1 + 2 , foo(3), A ) ** 2 } }| % \end{quote} % shows |(foo(3, foo(3), A))^(2)|. If the declaration was missing, % the parser would complain about an \enquote{\texttt{Unknown fp word 'foo'}}. % The \meta{identifier} must consist entirely of Latin letters |[a-zA-Z]|. % \end{function} % % \begin{function}[added = 2023-10-19]{\fp_set_function:nnn} % \begin{syntax} % \cs{fp_set_function:nnn} \Arg{identifier} \Arg{vars} \Arg{fp expr} % \end{syntax} % Defines the \meta{identifier} to stand in any further expression for % the result of evaluating the \meta{floating point expression}, with % the \meta{identifier} accepting the \meta{vars} (a non-empty % comma-separated list). % The result may contain other functions, which are % then replaced by their results if they have any. For instance, % \begin{quote} % \cs{fp_new_function:n} |{ npow }| \\ % \cs{fp_set_function:nnn} |{ npow } { a,b } { a**b }| \\ % \cs{fp_show:n} |{ npow(16,0.25) }| % \end{quote} % shows |2|. The names of the \meta{vars} must % consist entirely of Latin letters |[a-zA-Z]|, but are otherwise not % restricted: in particular, they are independent of any variables % declared by \cs{fp_new_variable:n}. % \end{function} % % \begin{function}[added = 2023-10-19]{\fp_clear_function:n} % \begin{syntax} % \cs{fp_clear_function:n} \Arg{identifier} % \end{syntax} % Removes any definition given by \cs{fp_set_function:nnn} to the function % with this \meta{identifier}. % \end{function} % % \section{Some useful constants, and scratch variables} % % \begin{variable}[added = 2012-05-08, module = fp]{\c_zero_fp, \c_minus_zero_fp} % Zero, with either sign. % \end{variable} % % \begin{variable}[added = 2012-05-08, module = fp]{\c_one_fp} % One as an \texttt{fp}: useful for comparisons in some places. % \end{variable} % % \begin{variable}[added = 2012-05-08, module = fp]{\c_inf_fp, \c_minus_inf_fp} % Infinity, with either sign. These can be input directly in a % floating point expression as \texttt{inf} and \texttt{-inf}. % \end{variable} % % \begin{variable}[added = 2012-05-08, module = fp]{\c_nan_fp} % Not a number. This can be input directly in a floating point expression % as \texttt{nan}. % \end{variable} % % \begin{variable}[updated = 2012-05-08, module = fp]{\c_e_fp} % The value of the base of the natural logarithm, $\mathrm{e} = \exp(1)$. % \end{variable} % % \begin{variable}[updated = 2013-11-17, module = fp]{\c_pi_fp} % The value of~$\pi$. This can be input directly in a floating point % expression as~\texttt{pi}. % \end{variable} % % \begin{variable}[added = 2012-05-08, updated = 2013-11-17, module = fp] % {\c_one_degree_fp} % The value of $1^{\circ}$ in radians. Multiply an angle given in % degrees by this value to obtain a result in radians. Note that % trigonometric functions expecting an argument in radians or in % degrees are both available. Within floating point expressions, this % can be accessed as \texttt{deg}. % \end{variable} % % \section{Scratch variables} % % \begin{variable}[module = fp]{\l_tmpa_fp, \l_tmpb_fp} % Scratch floating points for local assignment. These are never used by % the kernel code, and so are safe for use with any \LaTeX3-defined % function. However, they may be overwritten by other non-kernel % code and so should only be used for short-term storage. % \end{variable} % % \begin{variable}[module = fp]{\g_tmpa_fp, \g_tmpb_fp} % Scratch floating points for global assignment. These are never used by % the kernel code, and so are safe for use with any \LaTeX3-defined % function. However, they may be overwritten by other non-kernel % code and so should only be used for short-term storage. % \end{variable} % % \section{Floating point exceptions} % \label{sec:l3fp:fp-exceptions} % % \emph{The functions defined in this section are experimental, and % their functionality may be altered or removed altogether.} % % \enquote{Exceptions} may occur when performing some floating point % operations, such as \texttt{0 / 0}, or \texttt{10 ** 1e9999}. The % relevant \textsc{IEEE} standard defines $5$ types of exceptions, % of which we implement~$4$. % \begin{itemize} % \item \emph{Overflow} occurs whenever the result of an operation is % too large to be represented as a normal floating point number. This % results in $\pm \infty$. % \item \emph{Underflow} occurs whenever the result of an operation is % too close to $0$ to be represented as a normal floating point % number. This results in $\pm 0$. % \item \emph{Invalid operation} occurs for operations with no defined % outcome, for instance $0/0$ or $\sin(\infty)$, and results in a \nan{}. % It also occurs for conversion functions whose target type does not % have the appropriate infinite or \nan{} value (\emph{e.g.}, % \cs{fp_to_dim:n}). % \item \emph{Division by zero} occurs when dividing a non-zero number % by $0$, or when evaluating functions at poles, \emph{e.g.}, % $\ln(0)$ or $\cot(0)$. This results in $\pm\infty$. % \item [\emph{(not yet)}] \emph{Inexact} occurs whenever the result of % a computation is not exact, in other words, almost always. At the % moment, this exception is entirely ignored in \LaTeX3. % \end{itemize} % To each exception we associate a \enquote{flag}: \cs{l_fp_overflow_flag}, % \cs{l_fp_underflow_flag}, \cs{l_fp_invalid_operation_flag} and % \cs{l_fp_division_by_zero_flag}. The state of these flags can be tested % and modified with commands from \pkg{l3flag} % % By default, the \enquote{invalid operation} exception triggers an % (expandable) error, and raises the corresponding flag. Other % exceptions raise the corresponding flag but do not trigger an error. % The behaviour when an exception occurs can be modified (using % \cs{fp_trap:nn}) to either produce an error and raise the flag, or % only raise the flag, or do nothing at all. % % \begin{function}[added = 2012-07-19, updated = 2017-02-13, % tested = m3fp-traps001]{\fp_trap:nn} % \begin{syntax} % \cs{fp_trap:nn} \Arg{exception} \Arg{trap type} % \end{syntax} % All occurrences of the \meta{exception} (\texttt{overflow}, % \texttt{underflow}, \texttt{invalid_operation} or % \texttt{division_by_zero}) within the current % group are treated as \meta{trap type}, which can be % \begin{itemize} % \item \texttt{none}: the \meta{exception} will be entirely % ignored, and leave no trace; % \item \texttt{flag}: the \meta{exception} will turn the % corresponding flag on when it occurs; % \item \texttt{error}: additionally, the \meta{exception} will halt % the \TeX{} run and display some information about the current % operation in the terminal. % \end{itemize} % \end{function} % % \begin{variable} % { % \l_fp_overflow_flag, % \l_fp_underflow_flag, % \l_fp_invalid_operation_flag, % \l_fp_division_by_zero_flag % } % Flags denoting the occurrence of various floating-point exceptions. % \end{variable} % % \section{Viewing floating points} % % \begin{function}[added = 2012-05-08, updated = 2021-04-29, % tested = m3fp002]{\fp_show:N, \fp_show:c, \fp_show:n} % \begin{syntax} % \cs{fp_show:N} \meta{fp~var} % \cs{fp_show:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and displays the % result in the terminal. % \end{function} % % \begin{function}[added = 2014-08-22, updated = 2021-04-29] % {\fp_log:N, \fp_log:c, \fp_log:n} % \begin{syntax} % \cs{fp_log:N} \meta{fp~var} % \cs{fp_log:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} and writes the % result in the log file. % \end{function} % % \section{Floating point expressions} % % \subsection{Input of floating point numbers} \label{sec:l3fp:fp-floats} % % We support four types of floating point numbers: % \begin{itemize} % \item $\pm m \cdot 10^{n}$, a floating % point number, with integer $1\leq m\leq 10^{16}$, and % $-{\ExplSyntaxOn\int_use:N\c__fp_minus_min_exponent_int}\leq % n\leq {\ExplSyntaxOn\int_use:N\c__fp_max_exponent_int}$; % \item $\pm 0$, zero, with a given sign; % \item $\pm \infty$, infinity, with a given sign; % \item \nan{}, is \enquote{not a number}, and can be either quiet % or signalling (\emph{not yet}: this distinction is currently % unsupported); % \end{itemize} % Normal floating point numbers are stored in base $10$, with up to $16$ % significant figures. % % On input, a normal floating point number consists of: % \begin{itemize} % \item \meta{sign}: a possibly empty string of |+| and |-| characters; % \item \meta{significand}: a non-empty string of digits together with zero % or one dot; % \item \meta{exponent} optionally: the character |e| or |E|, followed by a % possibly empty string of |+|~and~|-| tokens, and a non-empty string % of digits. % \end{itemize} % The sign of the resulting number is |+| if \meta{sign} contains an % even number of |-|, and |-| otherwise, hence, an empty \meta{sign} % denotes a non-negative input. The stored significand is obtained from % \meta{significand} by omitting the decimal separator and leading zeros, % and rounding to $16$ significant digits, filling with trailing zeros % if necessary. In particular, the value stored is exact if the input % \meta{significand} has at most $16$ digits. The stored \meta{exponent} % is obtained by combining the input \meta{exponent} ($0$ if absent) % with a shift depending on the position of the significand and the number % of leading zeros. % % A special case arises if the resulting \meta{exponent} is either too % large or too small for the floating point number to be % represented. This results either in an overflow (the number is then % replaced by $\pm\infty$), or an underflow (resulting in $\pm 0$). % % The result is thus $\pm 0$ if and only if \meta{significand} contains no % non-zero digit (\emph{i.e.}, consists only in characters~|0|, and an % optional period), or if there is an underflow. Note that a % single dot is currently a valid floating point number, equal to~$+0$, % but that is not guaranteed to remain true. % % The \meta{significand} must be non-empty, so |e1| and |e-1| are not % valid floating point numbers. Note that the latter could be mistaken % with the difference of \enquote{\texttt{e}} and $1$. To avoid % confusions, the base of natural logarithms cannot be input as |e| and % should be input as \texttt{exp(1)} or \cs[module = fp]{c_e_fp} (which is faster). % % Special numbers are input as follows: % \begin{itemize} % \item \texttt{inf} represents $+\infty$, and can be preceded by any % \meta{sign}, yielding $\pm\infty$ as appropriate. % \item \texttt{nan} represents a (quiet) non-number. It can be % preceded by any sign, but that sign is ignored. % \item Any unrecognizable string triggers an error, and produces a % \nan{}. % \item Note that commands such as \tn{infty}, \tn{pi}, or \tn{sin} % \emph{do not} work in floating point expressions. They may % silently be interpreted as completely unexpected numbers, because % integer constants (allowed in expressions) are commonly stored as % mathematical characters. % \end{itemize} % % \subsection{Precedence of operators} % \label{sec:l3fp:fp-precedence} % % We list here all the operations supported in floating point % expressions, in order of decreasing precedence: operations listed % earlier bind more tightly than operations listed below them. % \begin{itemize} % \item Function calls (\texttt{sin}, \texttt{ln}, \emph{etc}). % \item Binary |**| and |^| (right associative). % \item Unary |+|, |-|, |!|. % \item Implicit multiplication by juxtaposition (\texttt{2pi}) % when neither factor is in parentheses. % \item Binary |*| and |/|, implicit multiplication by juxtaposition with parentheses (for instance \texttt{3(4+5)}). % \item Binary |+| and |-|. % \item Comparisons |>=|, |!=|, |?|), and by |+|, |-|, |*|, |/|. Unless otherwise % specified, providing a tuple as an argument of any other operation % yields the \enquote{invalid operation} exception and a \nan{} result. % % \begin{function}[tested = m3fp-logic002, module = {}]{?:} % \begin{syntax} % \cs{fp_eval:n} \{ \meta{operand_1} |?| \meta{operand_2} |:| \meta{operand_3} \} % \end{syntax} % The ternary operator |?:| results in \meta{operand_2} if % \meta{operand_1} is true (not $\pm 0$), and \meta{operand_3} if \meta{operand_1} % is false ($\pm 0$). All three \meta{operands} are evaluated in all % cases; they may be tuples. The operator is right associative, hence % \begin{verbatim} % \fp_eval:n % { % 1 + 3 > 4 ? 1 : % 2 + 4 > 5 ? 2 : % 3 + 5 > 6 ? 3 : 4 % } % \end{verbatim} % first tests whether $1 + 3 > 4$; since this isn't true, the branch % following |:| is taken, and $2 + 4 > 5$ is compared; since this is % true, the branch before |:| is taken, and everything else is % (evaluated then) ignored. That allows testing for various cases in % a concise manner, with the drawback that all computations are made % in all cases. % \end{function} % % \begin{function}[tested = m3fp-logic002]{||} % \begin{syntax} % \cs{fp_eval:n} \{ \meta{operand_1} \verb"||" \meta{operand_2} \} % \end{syntax} % If \meta{operand_1} is true (not $\pm 0$), use that value, otherwise the % value of \meta{operand_2}. Both \meta{operands} are evaluated in all % cases; they may be tuples. In \meta{operand_1} \verb"||" % \meta{operand_2} \verb"||" \ldots{} \verb"||" \meta{operands_n}, the % first true (nonzero) \meta{operand} is used and if all are zero the % last one ($\pm 0$) is used. % \end{function} % % \begin{function}[tested = m3fp-logic002]{&&} % \begin{syntax} % \cs{fp_eval:n} \{ \meta{operand_1} |&&| \meta{operand_2} \} % \end{syntax} % If \meta{operand_1} is false (equal to~$\pm 0$), use that value, % otherwise the value of \meta{operand_2}. Both \meta{operands} are % evaluated in all cases; they may be tuples. In \meta{operand_1} % |&&| \meta{operand_2} |&&| \ldots{} |&&| \meta{operands_n}, the % first false ($\pm 0$) \meta{operand} is used and if none is zero the % last one is used. % \end{function} % % \begin{function}[tested = m3fp-logic001, updated = 2013-12-14] % {<, =, >, ?} % \begin{syntax} % \cs{fp_eval:n} \\ % ~~\{ \\ % ~~~~\meta{operand_1} \meta{relation_1} \\ % ~~~~\ldots{} \\ % ~~~~\meta{operand_N} \meta{relation_N} \\ % ~~~~\meta{operand_{N+1}} \\ % ~~\} % \end{syntax} % Each \meta{relation} consists of a non-empty string of |<|, |=|, % |>|, and~|?|, optionally preceded by~|!|, and may not start % with~|?|. This evaluates to $+1$ if all comparisons % \meta{operand_i} \meta{relation_i} \meta{operand_{i+1}} are true, and % $+0$ otherwise. All \meta{operands} are evaluated (once) in all cases. % See \cs{fp_compare:nTF} for details. % \end{function} % % \begin{function}[tested = m3fp-basics001]{+, -} % \begin{syntax} % \cs{fp_eval:n} \{ \meta{operand_1} |+| \meta{operand_2} \} % \cs{fp_eval:n} \{ \meta{operand_1} |-| \meta{operand_2} \} % \end{syntax} % Computes the sum or the difference of its two \meta{operands}. The % \enquote{invalid operation} exception occurs for $\infty-\infty$. % \enquote{Underflow} and \enquote{overflow} occur when appropriate. % These operations supports the itemwise addition or subtraction of % two tuples, but if they have a different number of items the % \enquote{invalid operation} exception occurs and the result is \nan{}. % \end{function} % % \begin{function}[tested = {m3fp-basics002, m3fp-basics003}]{*, /} % \begin{syntax} % \cs{fp_eval:n} \{ \meta{operand_1} |*| \meta{operand_2} \} % \cs{fp_eval:n} \{ \meta{operand_1} |/| \meta{operand_2} \} % \end{syntax} % Computes the product or the ratio of its two \meta{operands}. The % \enquote{invalid operation} exception occurs for $\infty/\infty$, % $0/0$, or $0*\infty$. \enquote{Division by zero} occurs when % dividing a finite non-zero number by $\pm 0$. \enquote{Underflow} % and \enquote{overflow} occur when appropriate. % When \meta{operand_1} is a tuple and \meta{operand_2} is a floating % point number, each item of \meta{operand_1} is multiplied or divided % by \meta{operand_2}. Multiplication also supports the case where % \meta{operand_1} is a floating point number and \meta{operand_2} a % tuple. Other combinations yield an \enquote{invalid operation} % exception and a \nan{} result. % \end{function} % % \begin{function}[tested = m3fp-basics004, label = !]{+, -, !} % \begin{syntax} % \cs{fp_eval:n} \{ |+| \meta{operand} \} % \cs{fp_eval:n} \{ |-| \meta{operand} \} % \cs{fp_eval:n} \{ |!| \meta{operand} \} % \end{syntax} % The unary |+| does nothing, the unary |-| changes the sign of the % \meta{operand} (for a tuple, of all its components), and % |!| \meta{operand} evaluates to $1$ if \meta{operand} is false % (is $\pm 0$) and $0$ otherwise (this is the \texttt{not} % boolean function). Those operations never raise exceptions. % \end{function} % % \begin{function}[tested = m3fp-expo001]{**, ^} % \begin{syntax} % \cs{fp_eval:n} \{ \meta{operand_1} |**| \meta{operand_2} \} % \cs{fp_eval:n} \{ \meta{operand_1} |^| \meta{operand_2} \} % \end{syntax} % Raises \meta{operand_1} to the power \meta{operand_2}. This % operation is right associative, hence \texttt{2 ** 2 ** 3} equals % $2^{2^{3}} = 256$. If \meta{operand_1} is negative or $-0$ then: % the result's sign is $+$ if the \meta{operand_2} is infinite and % $(-1)^p$ if the \meta{operand_2} is $p/5^q$ with $p$, $q$ integers; % the result is $+0$ if % |abs(|\meta{operand_1}|)^|\meta{operand_2} evaluates to zero; in % other cases the \enquote{invalid operation} exception occurs because % the sign cannot be determined. \enquote{Division by zero} occurs % when raising $\pm 0$ to a finite strictly negative power. % \enquote{Underflow} and \enquote{overflow} occur when appropriate. % If either operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[tested = m3fp-basics004]{abs} % \begin{syntax} % \cs{fp_eval:n} \{ |abs(| \meta{fp expr} |)| \} % \end{syntax} % Computes the absolute value of the \meta{fp expr}. If the operand is % a tuple, \enquote{invalid operation} occurs. This operation does % not raise exceptions in other cases. See also \cs{fp_abs:n}. % \end{function} % % \begin{function}[tested = m3fp-expo001]{exp} % \begin{syntax} % \cs{fp_eval:n} \{ |exp(| \meta{fp expr} |)| \} % \end{syntax} % Computes the exponential of the \meta{fp expr}. \enquote{Underflow} % and \enquote{overflow} occur when appropriate. % If the operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[tested = m3fp-expo001]{fact} % \begin{syntax} % \cs{fp_eval:n} \{ |fact(| \meta{fp expr} |)| \} % \end{syntax} % Computes the factorial of the \meta{fp expr}. If the \meta{fp expr} % is an integer between $-0$ and $3248$ included, the result is finite % and correctly rounded. Larger positive integers give $+\infty$ with % \enquote{overflow}, while $|fact(|{+\infty}|)|=+\infty$ and % $|fact(nan)|=|nan|$ with no exception. All other inputs give \nan{} % with the \enquote{invalid operation} exception. % \end{function} % % \begin{function}[tested = m3fp-expo001]{ln} % \begin{syntax} % \cs{fp_eval:n} \{ |ln(| \meta{fp expr} |)| \} % \end{syntax} % Computes the natural logarithm of the \meta{fp expr}. Negative % numbers have no (real) logarithm, hence the \enquote{invalid % operation} is raised in that case, including for $\ln(-0)$. % \enquote{Division by zero} occurs when evaluating % $\ln(+0) = -\infty$. \enquote{Underflow} and \enquote{overflow} % occur when appropriate. If the operand is a tuple, \enquote{invalid % operation} occurs. % \end{function} % % \begin{function}[EXP, added = 2018-11-03]{logb} % \begin{syntax} % \cs{fp_eval:n} \{ |logb(| \meta{fp expr} |)| \} % \end{syntax} % Determines the exponent of the \meta{fp expr}, namely the floor of % the base-$10$ logarithm of its absolute value. \enquote{Division by % zero} occurs when evaluating $\operatorname{logb}(\pm 0) = -\infty$. % Other special values are $\operatorname{logb}(\pm\infty)=+\infty$ % and $\operatorname{logb}(\nan{})=\nan{}$. If the operand is a tuple % or is \nan{}, then \enquote{invalid operation} occurs and the result % is \nan{}. % \end{function} % % \begin{function}[tested = m3fp-logic002]{max, min} % \begin{syntax} % \cs{fp_eval:n} \{ |max(| \meta{fp expr_1} |,| \meta{fp expr_2} |,| \ldots{} |)| \} % \cs{fp_eval:n} \{ |min(| \meta{fp expr_1} |,| \meta{fp expr_2} |,| \ldots{} |)| \} % \end{syntax} % Evaluates each \meta{fp expr} and computes the largest (smallest) of % those. If any of the \meta{fp expr} is a \nan{} or tuple, the result % is \nan{}. If any operand is a tuple, \enquote{invalid operation} % occurs; these operations do not raise exceptions in other cases. % \end{function} % % \begin{function} % [tested = {m3fp-round001, m3fp-round002}, added = 2013-12-14, updated = 2015-08-08] % {round, trunc, ceil, floor} % \begin{syntax} % \cs{fp_eval:n} \{ |round| |(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |round| |(| \meta{fp expr_1} , \meta{fp expr_2} |)| \} % \cs{fp_eval:n} \{ |round| |(| \meta{fp expr_1} , \meta{fp expr_2} , \meta{fp expr_3} |)| \} % \end{syntax} % Only |round| accepts a third argument. % Evaluates $\meta{fp expr_1}=x$ and $\meta{fp expr_2}=n$ and $\meta{fp expr_3}=t$ then rounds % $x$~to $n$~places. If $n$~is an integer, this rounds~$x$ to a % multiple of~$10^{-n}$; if $n=+\infty$, this always yields~$x$; if % $n=-\infty$, this yields one of $\pm 0$, $\pm\infty$, or~\nan{}; if % $n=\nan{}$, this yields \nan{}; if % $n$~is neither $\pm\infty$ nor an integer, then an \enquote{invalid % operation} exception is raised. When \meta{fp expr_2} is omitted, % $n=0$, \emph{i.e.}, \meta{fp expr_1} is rounded to an integer. The % rounding direction depends on the function. % \begin{itemize} % \item |round| yields the multiple of~$10^{-n}$ closest to~$x$, % with ties ($x$ half-way between two such multiples) rounded % as follows. If $t$ is \texttt{nan} (or not given) the even % multiple is chosen (\enquote{ties to even}), if $t=\pm 0$ the % multiple closest to $0$ is chosen (\enquote{ties to zero}), % if $t$ is positive/negative the multiple closest to $\infty$/$-\infty$ is chosen % (\enquote{ties towards positive/negative infinity}). % \item |floor| yields the largest % multiple of~$10^{-n}$ smaller or equal to~$x$ (\enquote{round % towards negative infinity}); % \item |ceil| yields the smallest % multiple of~$10^{-n}$ greater or equal to~$x$ (\enquote{round % towards positive infinity}); % \item |trunc| yields a multiple % of~$10^{-n}$ with the same sign as~$x$ and with the largest % absolute value less than that of~$x$ (\enquote{round towards % zero}). % \end{itemize} % \enquote{Overflow} occurs if $x$~is finite and the result is % infinite (this can only happen if $\meta{fp expr_2}\string<-9984$). % If any operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[tested = m3fp-logic002]{sign} % \begin{syntax} % \cs{fp_eval:n} \{ |sign(| \meta{fp expr} |)| \} % \end{syntax} % Evaluates the \meta{fp expr} and determines its sign: $+1$ for % positive numbers and for $+\infty$, $-1$ for negative numbers and % for $-\infty$, $\pm 0$ for $\pm 0$, and \nan{} for \nan{}. % If the operand is a tuple, \enquote{invalid operation} occurs. % This operation does not raise exceptions in other cases. % \end{function} % % \begin{function}[updated = 2013-11-17, tested = m3fp-trig001] % {sin, cos, tan, cot, csc, sec} % \begin{syntax} % \cs{fp_eval:n} \{ |sin(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |cos(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |tan(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |cot(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |csc(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |sec(| \meta{fp expr} |)| \} % \end{syntax} % Computes the sine, cosine, tangent, cotangent, cosecant, or secant % of the \meta{fp expr} given in radians. For arguments given in % degrees, see \texttt{sind}, \texttt{cosd}, \emph{etc.} Note that % since $\pi$~is irrational, $\operatorname{sin}(8\mathrm{pi})$ is not quite % zero, while its analogue $\operatorname{sind}(8\times 180)$ is exactly % zero. The trigonometric functions are undefined for % an argument of $\pm\infty$, leading to the \enquote{invalid % operation} exception. Additionally, evaluating tangent, % cotangent, cosecant, or secant at one of their poles leads to a % \enquote{division by zero} exception. \enquote{Underflow} and % \enquote{overflow} occur when appropriate. % If the operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[added = 2013-11-02, tested = m3fp-trig003] % {sind, cosd, tand, cotd, cscd, secd} % \begin{syntax} % \cs{fp_eval:n} \{ |sind(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |cosd(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |tand(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |cotd(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |cscd(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |secd(| \meta{fp expr} |)| \} % \end{syntax} % Computes the sine, cosine, tangent, cotangent, cosecant, or secant % of the \meta{fp expr} given in degrees. For arguments given in % radians, see \texttt{sin}, \texttt{cos}, \emph{etc.} Note that % since $\pi$~is irrational, $\operatorname{sin}(8\mathrm{pi})$ is not quite % zero, while its analogue $\operatorname{sind}(8\times 180)$ is exactly % zero. The trigonometric functions are undefined for % an argument of $\pm\infty$, leading to the \enquote{invalid % operation} exception. Additionally, evaluating tangent, % cotangent, cosecant, or secant at one of their poles leads to a % \enquote{division by zero} exception. \enquote{Underflow} and % \enquote{overflow} occur when appropriate. % If the operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[added = 2013-11-02, tested = m3fp-trig002] % {asin, acos, acsc, asec} % \begin{syntax} % \cs{fp_eval:n} \{ |asin(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |acos(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |acsc(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |asec(| \meta{fp expr} |)| \} % \end{syntax} % Computes the arcsine, arccosine, arccosecant, or arcsecant of the % \meta{fp expr} and returns the result in radians, in the range % $[-\pi/2,\pi/2]$ for \texttt{asin} and \texttt{acsc} and $[0,\pi]$ % for \texttt{acos} and \texttt{asec}. For a result in degrees, use % \texttt{asind}, \emph{etc.} If the argument of |asin| or |acos| % lies outside the range $[-1,1]$, or the argument of |acsc| or |asec| % inside the range $(-1,1)$, an \enquote{invalid operation} exception % is raised. \enquote{Underflow} and \enquote{overflow} occur when % appropriate. % If the operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[added = 2013-11-02, tested = m3fp-trig004] % {asind, acosd, acscd, asecd} % \begin{syntax} % \cs{fp_eval:n} \{ |asind(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |acosd(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |acscd(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |asecd(| \meta{fp expr} |)| \} % \end{syntax} % Computes the arcsine, arccosine, arccosecant, or arcsecant of the % \meta{fp expr} and returns the result in degrees, in the range % $[-90,90]$ for \texttt{asind} and \texttt{acscd} and $[0,180]$ for % \texttt{acosd} and \texttt{asecd}. For a result in radians, use % \texttt{asin}, \emph{etc.} If the argument of |asind| or |acosd| lies % outside the range $[-1,1]$, or the argument of |acscd| or |asecd| % inside the range $(-1,1)$, an \enquote{invalid operation} exception % is raised. \enquote{Underflow} and \enquote{overflow} occur when % appropriate. % If the operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[added = 2013-11-02, tested = m3fp-trig002] % {atan, acot} % \begin{syntax} % \cs{fp_eval:n} \{ |atan(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |atan(| \meta{fp expr_1} , \meta{fp expr_2} |)| \} % \cs{fp_eval:n} \{ |acot(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |acot(| \meta{fp expr_1} , \meta{fp expr_2} |)| \} % \end{syntax} % Those functions yield an angle in radians: \texttt{atand} and % \texttt{acotd} are their analogs in degrees. The one-argument % versions compute the arctangent or arccotangent of the % \meta{fp expr}: arctangent takes values in the range % $[-\pi/2,\pi/2]$, and arccotangent in the range $[0,\pi]$. The % two-argument arctangent computes the angle in polar coordinates of % the point with Cartesian coordinates $(\meta{fp expr_2}, % \meta{fp expr_1})$: this is the arctangent of % $\meta{fp expr_1}/\meta{fp expr_2}$, possibly shifted by~$\pi$ % depending on the signs of \meta{fp expr_1} and \meta{fp expr_2}. The % two-argument arccotangent computes the angle in polar coordinates of % the point $(\meta{fp expr_1}, \meta{fp expr_2})$, equal to the % arccotangent of $\meta{fp expr_1}/\meta{fp expr_2}$, possibly shifted % by~$\pi$. Both two-argument functions take values in the wider % range $[-\pi,\pi]$. The ratio $\meta{fp expr_1}/\meta{fp expr_2}$ % need not be defined for the two-argument arctangent: when both % expressions yield~$\pm 0$, or when both yield~$\pm\infty$, the % resulting angle is one of $\{\pm\pi/4,\pm 3\pi/4\}$ depending on % signs. The \enquote{underflow} exception can occur. % If any operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[added = 2013-11-02, tested = m3fp-trig004] % {atand, acotd} % \begin{syntax} % \cs{fp_eval:n} \{ |atand(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |atand(| \meta{fp expr_1} , \meta{fp expr_2} |)| \} % \cs{fp_eval:n} \{ |acotd(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |acotd(| \meta{fp expr_1} , \meta{fp expr_2} |)| \} % \end{syntax} % Those functions yield an angle in degrees: \texttt{atan} and % \texttt{acot} are their analogs in radians. The one-argument % versions compute the arctangent or arccotangent of the % \meta{fp expr}: arctangent takes values in the range $[-90,90]$, and % arccotangent in the range $[0,180]$. The two-argument arctangent % computes the angle in polar coordinates of the point with Cartesian % coordinates $(\meta{fp expr_2}, \meta{fp expr_1})$: this is the % arctangent of $\meta{fp expr_1}/\meta{fp expr_2}$, possibly shifted % by~$180$ depending on the signs of \meta{fp expr_1} and % \meta{fp expr_2}. The two-argument arccotangent computes the angle % in polar coordinates of the point $(\meta{fp expr_1}, % \meta{fp expr_2})$, equal to the arccotangent of % $\meta{fp expr_1}/\meta{fp expr_2}$, possibly shifted by~$180$. Both % two-argument functions take values in the wider range $[-180,180]$. % The ratio $\meta{fp expr_1}/\meta{fp expr_2}$ need not be defined for % the two-argument arctangent: when both expressions yield~$\pm 0$, or % when both yield~$\pm\infty$, the resulting angle is one of $\{\pm % 45,\pm 135\}$ depending on signs. The \enquote{underflow} % exception can occur. % If any operand is a tuple, \enquote{invalid operation} occurs. % \end{function} % % \begin{function}[added = 2013-12-14, tested = m3fp-basics005]{sqrt} % \begin{syntax} % \cs{fp_eval:n} \{ |sqrt(| \meta{fp expr} |)| \} % \end{syntax} % Computes the square root of the \meta{fp expr}. The \enquote{invalid % operation} is raised when the \meta{fp expr} is negative or is a tuple; no other % exception can occur. Special values yield $\sqrt{-0} = -0$, % $\sqrt{+0} = +0$, $\sqrt{+\infty} = +\infty$ and % $\sqrt{\text{\nan{}}}=\text{\nan{}}$. % \end{function} % % \begin{function}[added = 2016-12-05]{rand} % \begin{syntax} % \cs{fp_eval:n} \{ |rand()| \} % \end{syntax} % Produces a pseudo-random floating-point number (multiple of % $10^{-16}$) between $0$~included and $1$~excluded. This is not available % in older versions of \XeTeX{}. The random seed can be queried using % \cs{sys_rand_seed:} and set using \cs{sys_gset_rand_seed:n}. % \begin{texnote} % This is based on pseudo-random numbers provided by the engine's % primitive \tn{pdfuniformdeviate} in \pdfTeX{}, \pTeX{}, \upTeX{} % and \tn{uniformdeviate} in \LuaTeX{} and \XeTeX{}. The underlying code is % based on Metapost, which follows an additive scheme recommended in % Section 3.6 of \enquote{The Art of Computer Programming, % Volume~2}. % % While we are more careful than \tn{uniformdeviate} to preserve % uniformity of the underlying stream of $28$-bit pseudo-random % integers, these pseudo-random numbers should of course not be % relied upon for serious numerical computations nor cryptography. % \end{texnote} % \end{function} % % \begin{function}[added = 2016-12-05]{randint} % \begin{syntax} % \cs{fp_eval:n} \{ |randint(| \meta{fp expr} |)| \} % \cs{fp_eval:n} \{ |randint(| \meta{fp expr_1} , \meta{fp expr_2} |)| \} % \end{syntax} % Produces a pseudo-random integer between $1$~and \meta{fp expr} or % between \meta{fp expr_1} and \meta{fp expr_2} inclusive. The bounds % must be integers in the range $(-10^{16},10^{16})$ and the first % must be smaller or equal to the second. See \texttt{rand} for % important comments on how these pseudo-random numbers are generated. % \end{function} % % \begin{variable}[tested = m3fp-parse001]{inf, nan} % The special values $+\infty$, $-\infty$, and \nan{} are represented % as \texttt{inf}, \texttt{-inf} and \texttt{nan} (see \cs[module = fp]{c_inf_fp}, % \cs[module = fp]{c_minus_inf_fp} and \cs[module = fp]{c_nan_fp}). % \end{variable} % % \begin{variable}[tested = m3fp-parse001]{pi} % The value of $\pi$ (see \cs[module = fp]{c_pi_fp}). % \end{variable} % % \begin{variable}[tested = m3fp-parse001]{deg} % The value of $1^{\circ}$ in radians (see \cs[module = fp]{c_one_degree_fp}). % \end{variable} % % \begin{variable}[tested = m3fp-parse001] % {em, ex, in, pt, pc, cm, mm, dd, cc, nd, nc, bp, sp} % \newcommand{\unit}[1]{\ifmmode\,\fi\text{\texttt{#1}}} % Those units of measurement are equal to their values in \unit{pt}, % namely % \begin{align*} % 1 \unit{in} & = 72.27 \unit{pt} \\ % 1 \unit{pt} & = 1 \unit{pt} \\ % 1 \unit{pc} & = 12 \unit{pt} \\ % 1 \unit{cm} & = \frac{1}{2.54} \unit{in} = 28.45275590551181 \unit{pt} \\ % 1 \unit{mm} & = \frac{1}{25.4} \unit{in} = 2.845275590551181 \unit{pt} \\ % 1 \unit{dd} & = 0.376065 \unit{mm} = 1.07000856496063 \unit{pt} \\ % 1 \unit{cc} & = 12 \unit{dd} = 12.84010277952756 \unit{pt} \\ % 1 \unit{nd} & = 0.375 \unit{mm} = 1.066978346456693 \unit{pt} \\ % 1 \unit{nc} & = 12 \unit{nd} = 12.80374015748031 \unit{pt} \\ % 1 \unit{bp} & = \frac{1}{72} \unit{in} = 1.00375 \unit{pt} \\ % 1 \unit{sp} & = 2^{-16} \unit{pt} = 1.52587890625 \times 10^{-5} \unit{pt}. % \end{align*} % The values of the (font-dependent) units \unit{em} and \unit{ex} are % gathered from \TeX{} when the surrounding floating point expression % is evaluated. % \end{variable} % % \begin{variable}[tested = m3fp-parse001]{true, false} % Other names for $1$ and $+0$. % \end{variable} % % \begin{function}[EXP, added = 2012-05-14, updated = 2012-07-08, % tested = m3fp-convert003]{\fp_abs:n} % \begin{syntax} % \cs{fp_abs:n} \Arg{fp expr} % \end{syntax} % Evaluates the \meta{fp expr} as described for % \cs{fp_eval:n} and leaves the absolute value of the result in the % input stream. If the argument is $\pm\infty$, \nan{} or a tuple, % \enquote{invalid operation} occurs. Within floating point % expressions, |abs()| can be used; it accepts $\pm\infty$ and \nan{} % as arguments. % \end{function} % % \begin{function}[EXP, added = 2012-09-26, tested = m3fp-convert003] % {\fp_max:nn, \fp_min:nn} % \begin{syntax} % \cs{fp_max:nn} \Arg{fp expr_1} \Arg{fp expr_2} % \end{syntax} % Evaluates the \meta{fp exprs} as described for % \cs{fp_eval:n} and leaves the resulting larger (\texttt{max}) or % smaller (\texttt{min}) value in the input stream. If the argument % is a tuple, \enquote{invalid operation} occurs, but no other case % raises exceptions. Within floating point expressions, |max()| and % |min()| can be used. % \end{function} % % \section{Disclaimer and roadmap} % % This module may break if the escape character is among % |0123456789_+|, or if it receives a \TeX{} primitive conditional affected % by \cs{exp_not:N}. % % The following need to be done. I'll try to time-order the items. % \begin{itemize} % \item Function to count items in a tuple (and to determine if something is a tuple). % \item Decide what exponent range to consider. % \item Support signalling \texttt{nan}. % \item Modulo and remainder, and rounding function |quantize| (and its friends analogous to |trunc|, |ceil|, |floor|). % \item \cs{fp_format:nn} \Arg{fp expr} \Arg{format}, but what should % \meta{format} be? More general pretty printing? % \item Add |and|, |or|, |xor|? Perhaps under the names \texttt{all}, % \texttt{any}, and \texttt{xor}? % \item Add $\log(x,b)$ for logarithm of $x$ in base $b$. % \item \texttt{hypot} (Euclidean length). % Cartesian-to-polar transform. % \item Hyperbolic functions \texttt{cosh}, \texttt{sinh}, \texttt{tanh}. % \item Inverse hyperbolics. % \item Base conversion, input such as \texttt{0xAB.CDEF}. % \item Factorial (not with |!|), gamma function. % \item Improve coefficients of the \texttt{sin} and \texttt{tan} % series. % \item Treat upper and lower case letters identically in % identifiers, and ignore underscores. % \item Add an |array(1,2,3)| and |i=complex(0,1)|. % \item Provide an experimental |map| function? Perhaps easier to % implement if it is a single character, |@sin(1,2)|? % \item Provide an |isnan| function analogue of \cs{fp_if_nan:nTF}? % \item Support keyword arguments? % \end{itemize} % \pkg{Pgfmath} also provides box-measurements (depth, height, width), but % boxes are not possible expandably. % % Bugs, and tests to add. % \begin{itemize} % \item Check that functions are monotonic when they should. % \item Add exceptions to |?:|, |!<=>?|, |&&|, \verb"||", and |!|. % \item Logarithms of numbers very close to $1$ are inaccurate. % \item When rounding towards $-\infty$, |\dim_to_fp:n {0pt}| should % return $-0$, not $+0$. % \item The result of $(\pm0)+(\pm0)$, of $x+(-x)$, and of $(-x)+x$ % should depend on the rounding mode. % \item \texttt{0e9999999999} gives a \TeX{} \enquote{number too % large} error. % \item Subnormals are not implemented. % \end{itemize} % % Possible optimizations/improvements. % \begin{itemize} % \item Document that \pkg{l3trial/l3fp-types} introduces tools for % adding new types. % \item In subsection~\ref{sec:l3fp:fp-floats}, write a grammar. % \item It would be nice if the \texttt{parse} auxiliaries for each % operation were set up in the corresponding module, rather than % centralizing in \pkg{l3fp-parse}. % \item Some functions should get an |_o| ending to indicate that they % expand after their result. % \item More care should be given to distinguish expandable/restricted % expandable (auxiliary and internal) functions. % \item The code for the \texttt{ternary} set of functions is ugly. % \item There are many |~| missing in the doc to avoid bad line-breaks. % \item The algorithm for computing the logarithm of the significand % could be made to use a $5$ terms Taylor series instead of $10$ % terms by taking $c = 2000/(\lfloor 200x\rfloor +1) \in [10,95]$ % instead of $c\in [1,10]$. Also, it would then be possible to % simplify the computation of $t$. However, we would then have to % hard-code the logarithms of $44$ small integers instead of $9$. % \item Improve notations in the explanations of the division % algorithm (\pkg{l3fp-basics}). % \item Understand and document \cs[no-index]{__fp_basics_pack_weird_low:NNNNw} % and \cs[no-index]{__fp_basics_pack_weird_high:NNNNNNNNw} better. Move the % other \texttt{basics_pack} auxiliaries to \pkg{l3fp-aux} under a % better name. % \item Find out if underflow can really occur for trigonometric % functions, and redoc as appropriate. % \item Add bibliography. Some of Kahan's articles, some previous % \TeX{} fp packages, the international standards,\ldots{} % \item Also take into account the \enquote{inexact} exception? % \item Support multi-character prefix operators (\emph{e.g.}, |@/| or % whatever)? % \end{itemize} % % \end{documentation} % % \begin{implementation} % % \section{\pkg{l3fp} implementation} % % Nothing to see here: everything is in the subfiles! % % \end{implementation} % % \PrintIndex