% \iffalse meta-comment % %% File: l3fp-trig.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} \begin{document} \DocInput{\jobname.dtx} \end{document} % % \fi % % \title{^^A % The \pkg{l3fp-trig} module\\ % Floating point trigonometric functions^^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} % % \end{documentation} % % \begin{implementation} % % \section{\pkg{l3fp-trig} implementation} % % \begin{macrocode} %<*package> % \end{macrocode} % % \begin{macrocode} %<@@=fp> % \end{macrocode} % % \begin{macro}[EXP] % { % \@@_parse_word_acos:N , % \@@_parse_word_acosd:N , % \@@_parse_word_acsc:N , % \@@_parse_word_acscd:N , % \@@_parse_word_asec:N , % \@@_parse_word_asecd:N , % \@@_parse_word_asin:N , % \@@_parse_word_asind:N , % \@@_parse_word_cos:N , % \@@_parse_word_cosd:N , % \@@_parse_word_cot:N , % \@@_parse_word_cotd:N , % \@@_parse_word_csc:N , % \@@_parse_word_cscd:N , % \@@_parse_word_sec:N , % \@@_parse_word_secd:N , % \@@_parse_word_sin:N , % \@@_parse_word_sind:N , % \@@_parse_word_tan:N , % \@@_parse_word_tand:N , % } % Unary functions. % \begin{macrocode} \tl_map_inline:nn { {acos} {acsc} {asec} {asin} {cos} {cot} {csc} {sec} {sin} {tan} } { \cs_new:cpe { @@_parse_word_#1:N } { \exp_not:N \@@_parse_unary_function:NNN \exp_not:c { @@_#1_o:w } \exp_not:N \use_i:nn } \cs_new:cpe { @@_parse_word_#1d:N } { \exp_not:N \@@_parse_unary_function:NNN \exp_not:c { @@_#1_o:w } \exp_not:N \use_ii:nn } } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP] % { % \@@_parse_word_acot:N , \@@_parse_word_acotd:N, % \@@_parse_word_atan:N , \@@_parse_word_atand:N, % } % Those functions may receive a variable number of arguments. % \begin{macrocode} \cs_new:Npn \@@_parse_word_acot:N { \@@_parse_function:NNN \@@_acot_o:Nw \use_i:nn } \cs_new:Npn \@@_parse_word_acotd:N { \@@_parse_function:NNN \@@_acot_o:Nw \use_ii:nn } \cs_new:Npn \@@_parse_word_atan:N { \@@_parse_function:NNN \@@_atan_o:Nw \use_i:nn } \cs_new:Npn \@@_parse_word_atand:N { \@@_parse_function:NNN \@@_atan_o:Nw \use_ii:nn } % \end{macrocode} % \end{macro} % % \subsection{Direct trigonometric functions} % % The approach for all trigonometric functions (sine, cosine, tangent, % cotangent, cosecant, and secant), with arguments given in radians or % in degrees, is the same. % \begin{itemize} % \item Filter out special cases ($\pm 0$, $\pm\inf$ and \nan{}). % \item Keep the sign for later, and work with the absolute value % $\lvert x\rvert$ of the argument. % \item Small numbers ($\lvert x\rvert<1$ in radians, $\lvert % x\rvert<10$ in degrees) are converted to fixed point numbers (and % to radians if $\lvert x\rvert$ is in degrees). % \item For larger numbers, we need argument reduction. Subtract a % multiple of $\pi/2$ (in degrees,~$90$) to bring the number to the % range to $[0, \pi/2)$ (in degrees, $[0,90)$). % \item Reduce further to $[0, \pi/4]$ (in degrees, $[0,45]$) using % $\sin x = \cos (\pi/2-x)$, and when working in degrees, convert to % radians. % \item Use the appropriate power series depending on the octant % $\lfloor\frac{|x|}{\pi/4}\rfloor \mod 8$ (in degrees, the same % formula with $\pi/4\to 45$), the sign, and the function to % compute. % \end{itemize} % % \subsubsection{Filtering special cases} % % \begin{macro}[EXP]{\@@_sin_o:w} % This function, and its analogs for \texttt{cos}, \texttt{csc}, % \texttt{sec}, \texttt{tan}, and \texttt{cot} instead of % \texttt{sin}, are followed either by \cs{use_i:nn} and a float in % radians or by \cs{use_ii:nn} and a float in degrees. The sine of % $\pm 0$ or \nan{} is the same float. The sine of $\pm\infty$ raises % an invalid operation exception with the appropriate function name. % Otherwise, call the \texttt{trig} function to perform argument % reduction and if necessary convert the reduced argument to radians. % Then, \cs{@@_sin_series_o:NNwwww} is called to compute the % Taylor series: this function receives a sign~|#3|, an initial octant % of~$0$, and the function \cs{@@_ep_to_float_o:wwN} which converts the % result of the series to a floating point directly rather than taking % its inverse, since $\sin(x) = \#3 \sin\lvert x\rvert$. % \begin{macrocode} \cs_new:Npn \@@_sin_o:w #1 \s_@@ \@@_chk:w #2#3#4; @ { \if_case:w #2 \exp_stop_f: \@@_case_return_same_o:w \or: \@@_case_use:nw { \@@_trig:NNNNNwn #1 \@@_sin_series_o:NNwwww \@@_ep_to_float_o:wwN #3 0 } \or: \@@_case_use:nw { \@@_invalid_operation_o:fw { #1 { sin } { sind } } } \else: \@@_case_return_same_o:w \fi: \s_@@ \@@_chk:w #2 #3 #4; } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_cos_o:w} % The cosine of $\pm 0$ is $1$. The cosine of $\pm\infty$ raises an % invalid operation exception. The cosine of \nan{} is itself. % Otherwise, the \texttt{trig} function reduces the argument to at % most half a right-angle and converts if necessary to radians. We % then call the same series as for sine, but using a positive % sign~|0| regardless of the sign of~$x$, and with an initial octant % of~$2$, because $\cos(x) = + \sin(\pi/2 + \lvert x\rvert)$. % \begin{macrocode} \cs_new:Npn \@@_cos_o:w #1 \s_@@ \@@_chk:w #2#3; @ { \if_case:w #2 \exp_stop_f: \@@_case_return_o:Nw \c_one_fp \or: \@@_case_use:nw { \@@_trig:NNNNNwn #1 \@@_sin_series_o:NNwwww \@@_ep_to_float_o:wwN 0 2 } \or: \@@_case_use:nw { \@@_invalid_operation_o:fw { #1 { cos } { cosd } } } \else: \@@_case_return_same_o:w \fi: \s_@@ \@@_chk:w #2 #3; } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_csc_o:w} % The cosecant of $\pm 0$ is $\pm \infty$ with the same sign, with a % division by zero exception (see \cs{@@_cot_zero_o:Nfw} defined % below), which requires the function name. The cosecant of % $\pm\infty$ raises an invalid operation exception. The cosecant of % \nan{} is itself. Otherwise, the \texttt{trig} function performs % the argument reduction, and converts if necessary to radians before % calling the same series as for sine, using the sign~|#3|, a starting % octant of~$0$, and inverting during the conversion from the fixed % point sine to the floating point result, because $\csc(x) = \#3 % \big( \sin\lvert x\rvert\big)^{-1}$. % \begin{macrocode} \cs_new:Npn \@@_csc_o:w #1 \s_@@ \@@_chk:w #2#3#4; @ { \if_case:w #2 \exp_stop_f: \@@_cot_zero_o:Nfw #3 { #1 { csc } { cscd } } \or: \@@_case_use:nw { \@@_trig:NNNNNwn #1 \@@_sin_series_o:NNwwww \@@_ep_inv_to_float_o:wwN #3 0 } \or: \@@_case_use:nw { \@@_invalid_operation_o:fw { #1 { csc } { cscd } } } \else: \@@_case_return_same_o:w \fi: \s_@@ \@@_chk:w #2 #3 #4; } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_sec_o:w} % The secant of $\pm 0$ is $1$. The secant of $\pm \infty$ raises an % invalid operation exception. The secant of \nan{} is itself. % Otherwise, the \texttt{trig} function reduces the argument and turns % it to radians before calling the same series as for sine, using a % positive sign~$0$, a starting octant of~$2$, and inverting upon % conversion, because $\sec(x) = + 1 / \sin(\pi/2 + \lvert x\rvert)$. % \begin{macrocode} \cs_new:Npn \@@_sec_o:w #1 \s_@@ \@@_chk:w #2#3; @ { \if_case:w #2 \exp_stop_f: \@@_case_return_o:Nw \c_one_fp \or: \@@_case_use:nw { \@@_trig:NNNNNwn #1 \@@_sin_series_o:NNwwww \@@_ep_inv_to_float_o:wwN 0 2 } \or: \@@_case_use:nw { \@@_invalid_operation_o:fw { #1 { sec } { secd } } } \else: \@@_case_return_same_o:w \fi: \s_@@ \@@_chk:w #2 #3; } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_tan_o:w} % The tangent of $\pm 0$ or \nan{} is the same floating point number. % The tangent of $\pm\infty$ raises an invalid operation exception. % Once more, the \texttt{trig} function does the argument reduction % step and conversion to radians before calling % \cs{@@_tan_series_o:NNwwww}, with a sign~|#3| and an initial octant % of~$1$ (this shift is somewhat arbitrary). See \cs{@@_cot_o:w} for % an explanation of the $0$~argument. % \begin{macrocode} \cs_new:Npn \@@_tan_o:w #1 \s_@@ \@@_chk:w #2#3#4; @ { \if_case:w #2 \exp_stop_f: \@@_case_return_same_o:w \or: \@@_case_use:nw { \@@_trig:NNNNNwn #1 \@@_tan_series_o:NNwwww 0 #3 1 } \or: \@@_case_use:nw { \@@_invalid_operation_o:fw { #1 { tan } { tand } } } \else: \@@_case_return_same_o:w \fi: \s_@@ \@@_chk:w #2 #3 #4; } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_cot_o:w} % \begin{macro}[EXP]{\@@_cot_zero_o:Nfw} % The cotangent of $\pm 0$ is $\pm \infty$ with the same sign, with a % division by zero exception (see \cs{@@_cot_zero_o:Nfw}. The % cotangent of $\pm\infty$ raises an invalid operation exception. The % cotangent of \nan{} is itself. We use $\cot x = - \tan (\pi/2 + % x)$, and the initial octant for the tangent was chosen to be $1$, so % the octant here starts at $3$. The change in sign is obtained by % feeding \cs{@@_tan_series_o:NNwwww} two signs rather than just the % sign of the argument: the first of those indicates whether we % compute tangent or cotangent. Those signs are eventually combined. % \begin{macrocode} \cs_new:Npn \@@_cot_o:w #1 \s_@@ \@@_chk:w #2#3#4; @ { \if_case:w #2 \exp_stop_f: \@@_cot_zero_o:Nfw #3 { #1 { cot } { cotd } } \or: \@@_case_use:nw { \@@_trig:NNNNNwn #1 \@@_tan_series_o:NNwwww 2 #3 3 } \or: \@@_case_use:nw { \@@_invalid_operation_o:fw { #1 { cot } { cotd } } } \else: \@@_case_return_same_o:w \fi: \s_@@ \@@_chk:w #2 #3 #4; } \cs_new:Npn \@@_cot_zero_o:Nfw #1#2#3 \fi: { \fi: \token_if_eq_meaning:NNTF 0 #1 { \exp_args:NNf \@@_division_by_zero_o:Nnw \c_inf_fp } { \exp_args:NNf \@@_division_by_zero_o:Nnw \c_minus_inf_fp } {#2} } % \end{macrocode} % \end{macro} % \end{macro} % % \subsubsection{Distinguishing small and large arguments} % % \begin{macro}[EXP]{\@@_trig:NNNNNwn} % The first argument is \cs{use_i:nn} if the operand is in radians and % \cs{use_ii:nn} if it is in degrees. Arguments |#2| to~|#5| control % what trigonometric function we compute, and |#6| to~|#8| are pieces % of a normal floating point number. Call the \texttt{_series} % function~|#2|, with arguments |#3|, either a conversion function % (\cs{@@_ep_to_float_o:wN} or \cs{@@_ep_inv_to_float_o:wN}) or a sign $0$ % or~$2$ when computing tangent or cotangent; |#4|, a sign $0$ or~$2$; % the octant, computed in an integer expression starting with~|#5| and % stopped by a period; and a fixed point number obtained from the % floating point number by argument reduction (if necessary) and % conversion to radians (if necessary). Any argument reduction % adjusts the octant accordingly by leaving a (positive) shift into % its integer expression. Let us explain the integer comparison. Two % of the four \cs{exp_after:wN} are expanded, the expansion hits the % test, which is true if the float is at least~$1$ when working in % radians, and at least $10$ when working in degrees. Then one of the % remaining \cs{exp_after:wN} hits |#1|, which picks the \texttt{trig} % or \texttt{trigd} function in whichever branch of the conditional % was taken. The final \cs{exp_after:wN} closes the conditional. At % the end of the day, a number is \texttt{large} if it is $\geq 1$ in % radians or $\geq 10$ in degrees, and \texttt{small} otherwise. All % four \texttt{trig}/\texttt{trigd} auxiliaries receive the operand as % an extended-precision number. % \begin{macrocode} \cs_new:Npn \@@_trig:NNNNNwn #1#2#3#4#5 \s_@@ \@@_chk:w 1#6#7#8; { \exp_after:wN #2 \exp_after:wN #3 \exp_after:wN #4 \int_value:w \@@_int_eval:w #5 \exp_after:wN \exp_after:wN \exp_after:wN \exp_after:wN \if_int_compare:w #7 > #1 0 1 \exp_stop_f: #1 \@@_trig_large:ww \@@_trigd_large:ww \else: #1 \@@_trig_small:ww \@@_trigd_small:ww \fi: #7,#8{0000}{0000}; } % \end{macrocode} % \end{macro} % % \subsubsection{Small arguments} % % \begin{macro}[EXP]{\@@_trig_small:ww} % This receives a small extended-precision number in radians and % converts it to a fixed point number. Some trailing digits may be % lost in the conversion, so we keep the original floating point % number around: when computing sine or tangent (or their inverses), % the last step is to multiply by the floating point number (as % an extended-precision number) rather than the fixed point number. % The period serves to end the integer expression for the octant. % \begin{macrocode} \cs_new:Npn \@@_trig_small:ww #1,#2; { \@@_ep_to_fixed:wwn #1,#2; . #1,#2; } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_trigd_small:ww} % Convert the extended-precision number to radians, then call % \cs{@@_trig_small:ww} to massage it in the form appropriate for the % \texttt{_series} auxiliary. % \begin{macrocode} \cs_new:Npn \@@_trigd_small:ww #1,#2; { \@@_ep_mul_raw:wwwwN -1,{1745}{3292}{5199}{4329}{5769}{2369}; #1,#2; \@@_trig_small:ww } % \end{macrocode} % \end{macro} % % \subsubsection{Argument reduction in degrees} % % \begin{macro}[rEXP] % { % \@@_trigd_large:ww, \@@_trigd_large_auxi:nnnnwNNNN, % \@@_trigd_large_auxii:wNw, \@@_trigd_large_auxiii:www % } % Note that $25\times 360 = 9000$, so $10^{k+1} \equiv 10^{k} % \pmod{360}$ for $k\geq 3$. When the exponent~|#1| is very large, we % can thus safely replace it by~$22$ (or even~$19$). We turn the % floating point number into a fixed point number with two blocks of % $8$~digits followed by five blocks of $4$~digits. The original % float is $100\times\meta{block_1}\cdots\meta{block_3}. % \meta{block_4}\cdots\meta{block_7}$, or is equal to it modulo~$360$ % if the exponent~|#1| is very large. The first auxiliary finds % $\meta{block_1} + \meta{block_2} \pmod{9}$, a single digit, and % prepends it to the $4$~digits of \meta{block_3}. It also unpacks % \meta{block_4} and grabs the $4$~digits of \meta{block_7}. The % second auxiliary grabs the \meta{block_3} plus any contribution from % the first two blocks as~|#1|, the first digit of \meta{block_4} % (just after the decimal point in hundreds of degrees) as~|#2|, and % the three other digits as~|#3|. It finds the quotient and remainder % of |#1#2| modulo~$9$, adds twice the quotient to the integer % expression for the octant, and places the remainder (between $0$ % and~$8$) before |#3| to form a new \meta{block_4}. The resulting % fixed point number is $x\in [0, 0.9]$. If $x\geq 0.45$, we add~$1$ % to the octant and feed $0.9-x$ with an exponent of~$2$ (to % compensate the fact that we are working in units of hundreds of % degrees rather than degrees) to \cs{@@_trigd_small:ww}. Otherwise, % we feed it~$x$ with an exponent of~$2$. The third auxiliary also % discards digits which were not packed into the various % \meta{blocks}. Since the original exponent~|#1| is at least~$2$, % those are all~$0$ and no precision is lost (|#6| and~|#7| are % four~$0$ each). % \begin{macrocode} \cs_new:Npn \@@_trigd_large:ww #1, #2#3#4#5#6#7; { \exp_after:wN \@@_pack_eight:wNNNNNNNN \exp_after:wN \@@_pack_eight:wNNNNNNNN \exp_after:wN \@@_pack_twice_four:wNNNNNNNN \exp_after:wN \@@_pack_twice_four:wNNNNNNNN \exp_after:wN \@@_trigd_large_auxi:nnnnwNNNN \exp_after:wN ; \exp:w \exp_end_continue_f:w \prg_replicate:nn { \int_max:nn { 22 - #1 } { 0 } } { 0 } #2#3#4#5#6#7 0000 0000 0000 ! } \cs_new:Npn \@@_trigd_large_auxi:nnnnwNNNN #1#2#3#4#5; #6#7#8#9 { \exp_after:wN \@@_trigd_large_auxii:wNw \int_value:w \@@_int_eval:w #1 + #2 - (#1 + #2 - 4) / 9 * 9 \@@_int_eval_end: #3; #4; #5{#6#7#8#9}; } \cs_new:Npn \@@_trigd_large_auxii:wNw #1; #2#3; { + (#1#2 - 4) / 9 * 2 \exp_after:wN \@@_trigd_large_auxiii:www \int_value:w \@@_int_eval:w #1#2 - (#1#2 - 4) / 9 * 9 \@@_int_eval_end: #3 ; } \cs_new:Npn \@@_trigd_large_auxiii:www #1; #2; #3! { \if_int_compare:w #1 < 4500 \exp_stop_f: \exp_after:wN \@@_use_i_until_s:nw \exp_after:wN \@@_fixed_continue:wn \else: + 1 \fi: \@@_fixed_sub:wwn {9000}{0000}{0000}{0000}{0000}{0000}; {#1}#2{0000}{0000}; { \@@_trigd_small:ww 2, } } % \end{macrocode} % \end{macro} % % \subsubsection{Argument reduction in radians} % % Arguments greater or equal to~$1$ need to be reduced to a range where % we only need a few terms of the Taylor series. We reduce to the range % $[0,2\pi]$ by subtracting multiples of~$2\pi$, then to the smaller % range $[0,\pi/2]$ by subtracting multiples of~$\pi/2$ (keeping track % of how many times~$\pi/2$ is subtracted), then to $[0,\pi/4]$ by % mapping $x\to \pi/2 - x$ if appropriate. When the argument is very % large, say, $10^{100}$, an equally large multiple of~$2\pi$ must be % subtracted, hence we must work with a very good approximation % of~$2\pi$ in order to get a sensible remainder modulo~$2\pi$. % % Specifically, we multiply the argument by an approximation % of~$1/(2\pi)$ with $\ExplSyntaxOn\int_eval:n { \c__fp_max_exponent_int % + 48 }\ExplSyntaxOff$~digits, then discard the integer part of the % result, keeping $52$~digits of the fractional part. From the % fractional part of $x/(2\pi)$ we deduce the octant (quotient of the % first three digits by~$125$). We then multiply by $8$ or~$-8$ (the % latter when the octant is odd), ignore any integer part (related to % the octant), and convert the fractional part to an extended precision % number, before multiplying by~$\pi/4$ to convert back to a value in % radians in $[0,\pi/4]$. % % It is possible to prove that given the precision of floating points % and their range of exponents, the $52$~digits may start at most with % $24$~zeros. The $5$~last digits are affected by carries from % computations which are not done, hence we are left with at least $52 - % 24 - 5 = 23$ significant digits, enough to round correctly up to % $0.6\cdot\text{ulp}$ in all cases. % % \begin{variable}[EXP]{\c_@@_trig_intarray} % This integer array stores blocks of $8$~decimals of % $10^{-16}/(2\pi)$. Each entry is $10^8$ plus an $8$~digit number % storing $8$ decimals. In total we store $10112$~decimals of % $10^{-16}/(2\pi)$. The number of decimals we really need is the % maximum exponent plus the number of digits we later need,~$52$, % plus~$12$ ($4-1$~groups of $4$~digits). The memory footprint ($1/2$ % byte per digit) is the same as an earlier method of storing the data % as a control sequence name, but the major advantage is that we can % unpack specific subsets of the digits without unpacking the $10112$ % decimals. % \begin{macrocode} \intarray_const_from_clist:Nn \c_@@_trig_intarray { 100000000, 100000000, 115915494, 130918953, 135768883, 176337251, 143620344, 159645740, 145644874, 176673440, 158896797, 163422653, 150901138, 102766253, 108595607, 128427267, 157958036, 189291184, 161145786, 152877967, 141073169, 198392292, 139966937, 140907757, 130777463, 196925307, 168871739, 128962173, 197661693, 136239024, 117236290, 111832380, 111422269, 197557159, 140461890, 108690267, 139561204, 189410936, 193784408, 155287230, 199946443, 140024867, 123477394, 159610898, 132309678, 130749061, 166986462, 180469944, 186521878, 181574786, 156696424, 110389958, 174139348, 160998386, 180991999, 162442875, 158517117, 188584311, 117518767, 116054654, 175369880, 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193584259, 126727638, 168143633, 109856853, 127860243, 132141052, 133076065, 188414958, 158718197, 107124299, 159592267, 181172796, 144388537, 196763139, 127431422, 179531145, 100064922, 112650013, 132686230, 121550837, } % \end{macrocode} % \end{variable} % % \begin{macro}[rEXP] % { % \@@_trig_large:ww, % \@@_trig_large_auxi:w, % \@@_trig_large_auxii:w, % \@@_trig_large_auxiii:w, % } % The exponent~|#1| is between $1$ and~$\ExplSyntaxOn \int_use:N % \c__fp_max_exponent_int$. We wish to look up decimals % $10^{\text{\texttt{\#1}}-16}/(2\pi)$ starting from the digit % $|#1|+1$. Since they are stored in batches of~$8$, compute % $\lfloor|#1|/8\rfloor$ and fetch blocks of $8$ digits starting % there. The numbering of items in \cs{c_@@_trig_intarray} starts % at~$1$, so the block $\lfloor|#1|/8\rfloor+1$ contains the digit we % want, at one of the eight positions. Each call to \cs{int_value:w} % \cs{__kernel_intarray_item:Nn} expands the next, until being stopped % by \cs{@@_trig_large_auxiii:w} using \cs{exp_stop_f:}. Once all % these blocks are unpacked, the \cs{exp_stop_f:} and $0$ to $7$ % digits are removed by \cs[no-index]{use_none:n\ldots{}n}. % Finally, \cs{@@_trig_large_auxii:w} packs $64$ digits (there are % between $65$ and $72$ at this point) into groups of~$4$ and the % \texttt{auxv} auxiliary is called. % \begin{macrocode} \cs_new:Npn \@@_trig_large:ww #1, #2#3#4#5#6; { \exp_after:wN \@@_trig_large_auxi:w \int_value:w \@@_int_eval:w (#1 - 4) / 8 \exp_after:wN , \int_value:w #1 , ; {#2}{#3}{#4}{#5} ; } \cs_new:Npn \@@_trig_large_auxi:w #1, #2, { \exp_after:wN \exp_after:wN \exp_after:wN \@@_trig_large_auxii:w \cs:w use_none:n \prg_replicate:nn { #2 - #1 * 8 } { n } \exp_after:wN \cs_end: \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 1 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 2 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 3 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 4 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 5 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 6 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 7 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 8 \scan_stop: } \exp_after:wN \@@_trig_large_auxiii:w \int_value:w \__kernel_intarray_item:Nn \c_@@_trig_intarray { \@@_int_eval:w #1 + 9 \scan_stop: } \exp_stop_f: } \cs_new:Npn \@@_trig_large_auxii:w { \@@_pack_twice_four:wNNNNNNNN \@@_pack_twice_four:wNNNNNNNN \@@_pack_twice_four:wNNNNNNNN \@@_pack_twice_four:wNNNNNNNN \@@_pack_twice_four:wNNNNNNNN \@@_pack_twice_four:wNNNNNNNN \@@_pack_twice_four:wNNNNNNNN \@@_pack_twice_four:wNNNNNNNN \@@_trig_large_auxv:www ; } \cs_new:Npn \@@_trig_large_auxiii:w 1 { \exp_stop_f: } % \end{macrocode} % \end{macro} % % \begin{macro}[rEXP] % { % \@@_trig_large_auxv:www, % \@@_trig_large_auxvi:wnnnnnnnn, % \@@_trig_large_pack:NNNNNw % } % First come the first $64$~digits of the fractional part of % $10^{\text{\texttt{\#1}}-16}/(2\pi)$, arranged in $16$~blocks % of~$4$, and ending with a semicolon. Then a few more digits of the % same fractional part, ending with a semicolon, then $4$~blocks of % $4$~digits holding the significand of the original argument. % Multiply the $16$-digit significand with the $64$-digit fractional % part: the \texttt{auxvi} auxiliary receives the significand % as~|#2#3#4#5| and $16$~digits of the fractional part as~|#6#7#8#9|, % and computes one step of the usual ladder of \texttt{pack} functions % we use for multiplication (see \emph{e.g.,} \cs{@@_fixed_mul:wwn}), % then discards one block of the fractional part to set things up for % the next step of the ladder. We perform $13$~such steps, replacing % the last \texttt{middle} shift by the appropriate \texttt{trailing} % shift, then discard the significand and remaining $3$~blocks from % the fractional part, as there are not enough digits to compute any % more step in the ladder. The last semicolon closes the ladder, and % we return control to the \texttt{auxvii} auxiliary. % \begin{macrocode} \cs_new:Npn \@@_trig_large_auxv:www #1; #2; #3; { \exp_after:wN \@@_use_i_until_s:nw \exp_after:wN \@@_trig_large_auxvii:w \int_value:w \@@_int_eval:w \c_@@_leading_shift_int \prg_replicate:nn { 13 } { \@@_trig_large_auxvi:wnnnnnnnn } + \c_@@_trailing_shift_int - \c_@@_middle_shift_int \@@_use_i_until_s:nw ; #3 #1 ; ; } \cs_new:Npn \@@_trig_large_auxvi:wnnnnnnnn #1; #2#3#4#5#6#7#8#9 { \exp_after:wN \@@_trig_large_pack:NNNNNw \int_value:w \@@_int_eval:w \c_@@_middle_shift_int + #2*#9 + #3*#8 + #4*#7 + #5*#6 #1; {#2}{#3}{#4}{#5} {#7}{#8}{#9} } \cs_new:Npn \@@_trig_large_pack:NNNNNw #1#2#3#4#5#6; { + #1#2#3#4#5 ; #6 } % \end{macrocode} % \end{macro} % % \begin{macro}[rEXP] % { % \@@_trig_large_auxvii:w, % \@@_trig_large_auxviii:w, % } % \begin{macro}[EXP] % { % \@@_trig_large_auxix:Nw, % \@@_trig_large_auxx:wNNNNN, % \@@_trig_large_auxxi:w % } % The \texttt{auxvii} auxiliary is followed by $52$~digits and a % semicolon. We find the octant as the integer part of $8$~times what % follows, or equivalently as the integer part of $|#1#2#3|/125$, and % add it to the surrounding integer expression for the octant. We % then compute $8$~times the $52$-digit number, with a minus sign if % the octant is odd. Again, the last \texttt{middle} shift is % converted to a \texttt{trailing} shift. Any integer part (including % negative values which come up when the octant is odd) is discarded % by \cs{@@_use_i_until_s:nw}. The resulting fractional part should % then be converted to radians by multiplying by~$2\pi/8$, but first, % build an extended precision number by abusing % \cs{@@_ep_to_ep_loop:N} with the appropriate trailing markers. % Finally, \cs{@@_trig_small:ww} sets up the argument for the % functions which compute the Taylor series. % \begin{macrocode} \cs_new:Npn \@@_trig_large_auxvii:w #1#2#3 { \exp_after:wN \@@_trig_large_auxviii:ww \int_value:w \@@_int_eval:w (#1#2#3 - 62) / 125 ; #1#2#3 } \cs_new:Npn \@@_trig_large_auxviii:ww #1; { + #1 \if_int_odd:w #1 \exp_stop_f: \exp_after:wN \@@_trig_large_auxix:Nw \exp_after:wN - \else: \exp_after:wN \@@_trig_large_auxix:Nw \exp_after:wN + \fi: } \cs_new:Npn \@@_trig_large_auxix:Nw { \exp_after:wN \@@_use_i_until_s:nw \exp_after:wN \@@_trig_large_auxxi:w \int_value:w \@@_int_eval:w \c_@@_leading_shift_int \prg_replicate:nn { 13 } { \@@_trig_large_auxx:wNNNNN } + \c_@@_trailing_shift_int - \c_@@_middle_shift_int ; } \cs_new:Npn \@@_trig_large_auxx:wNNNNN #1; #2 #3#4#5#6 { \exp_after:wN \@@_trig_large_pack:NNNNNw \int_value:w \@@_int_eval:w \c_@@_middle_shift_int #2 8 * #3#4#5#6 #1; #2 } \cs_new:Npn \@@_trig_large_auxxi:w #1; { \exp_after:wN \@@_ep_mul_raw:wwwwN \int_value:w \@@_int_eval:w 0 \@@_ep_to_ep_loop:N #1 ; ; ! 0,{7853}{9816}{3397}{4483}{0961}{5661}; \@@_trig_small:ww } % \end{macrocode} % \end{macro} % \end{macro} % % \subsubsection{Computing the power series} % % \begin{macro}[EXP] % {\@@_sin_series_o:NNwwww, \@@_sin_series_aux_o:NNnwww} % Here we receive a conversion function \cs{@@_ep_to_float_o:wwN} or % \cs{@@_ep_inv_to_float_o:wwN}, a \meta{sign} ($0$ or~$2$), a % (non-negative) \meta{octant} delimited by a dot, a \meta{fixed % point} number delimited by a semicolon, and an extended-precision % number. The auxiliary receives: % \begin{itemize} % \item the conversion function~|#1|; % \item the final sign, which depends on the octant~|#3| and the % sign~|#2|; % \item the octant~|#3|, which controls the series we use; % \item the square |#4 * #4| of the argument as a fixed point number, % computed with \cs{@@_fixed_mul:wwn}; % \item the number itself as an extended-precision number. % \end{itemize} % If the octant is in $\{1,2,5,6,\ldots{}\}$, we are near an extremum % of the function and we use the series % \[ % \cos(x) = 1 - x^2 \bigg( \frac{1}{2!} - x^2 \bigg( \frac{1}{4!} % - x^2 \bigg( \cdots \bigg) \bigg) \bigg) . % \] % Otherwise, the series % \[ % \sin(x) = x \bigg( 1 - x^2 \bigg( \frac{1}{3!} - x^2 \bigg( % \frac{1}{5!} - x^2 \bigg( \cdots \bigg) \bigg) \bigg) \bigg) % \] % is used. Finally, the extended-precision number is converted to a % floating point number with the given sign, and \cs{@@_sanitize:Nw} % checks for overflow and underflow. % \begin{macrocode} \cs_new:Npn \@@_sin_series_o:NNwwww #1#2#3. #4; { \@@_fixed_mul:wwn #4; #4; { \exp_after:wN \@@_sin_series_aux_o:NNnwww \exp_after:wN #1 \int_value:w \if_int_odd:w \@@_int_eval:w (#3 + 2) / 4 \@@_int_eval_end: #2 \else: \if_meaning:w #2 0 2 \else: 0 \fi: \fi: {#3} } } \cs_new:Npn \@@_sin_series_aux_o:NNnwww #1#2#3 #4; #5,#6; { \if_int_odd:w \@@_int_eval:w #3 / 2 \@@_int_eval_end: \exp_after:wN \use_i:nn \else: \exp_after:wN \use_ii:nn \fi: { % 1/18! \@@_fixed_mul_sub_back:wwwn {0000}{0000}{0000}{0001}{5619}{2070}; #4;{0000}{0000}{0000}{0477}{9477}{3324}; \@@_fixed_mul_sub_back:wwwn #4;{0000}{0000}{0011}{4707}{4559}{7730}; \@@_fixed_mul_sub_back:wwwn #4;{0000}{0000}{2087}{6756}{9878}{6810}; \@@_fixed_mul_sub_back:wwwn #4;{0000}{0027}{5573}{1922}{3985}{8907}; \@@_fixed_mul_sub_back:wwwn #4;{0000}{2480}{1587}{3015}{8730}{1587}; \@@_fixed_mul_sub_back:wwwn #4;{0013}{8888}{8888}{8888}{8888}{8889}; \@@_fixed_mul_sub_back:wwwn #4;{0416}{6666}{6666}{6666}{6666}{6667}; \@@_fixed_mul_sub_back:wwwn #4;{5000}{0000}{0000}{0000}{0000}{0000}; \@@_fixed_mul_sub_back:wwwn#4;{10000}{0000}{0000}{0000}{0000}{0000}; { \@@_fixed_continue:wn 0, } } { % 1/17! \@@_fixed_mul_sub_back:wwwn {0000}{0000}{0000}{0028}{1145}{7254}; #4;{0000}{0000}{0000}{7647}{1637}{3182}; \@@_fixed_mul_sub_back:wwwn #4;{0000}{0000}{0160}{5904}{3836}{8216}; \@@_fixed_mul_sub_back:wwwn #4;{0000}{0002}{5052}{1083}{8544}{1719}; \@@_fixed_mul_sub_back:wwwn #4;{0000}{0275}{5731}{9223}{9858}{9065}; \@@_fixed_mul_sub_back:wwwn #4;{0001}{9841}{2698}{4126}{9841}{2698}; \@@_fixed_mul_sub_back:wwwn #4;{0083}{3333}{3333}{3333}{3333}{3333}; \@@_fixed_mul_sub_back:wwwn #4;{1666}{6666}{6666}{6666}{6666}{6667}; \@@_fixed_mul_sub_back:wwwn#4;{10000}{0000}{0000}{0000}{0000}{0000}; { \@@_ep_mul:wwwwn 0, } #5,#6; } { \exp_after:wN \@@_sanitize:Nw \exp_after:wN #2 \int_value:w \@@_int_eval:w #1 } #2 } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP] % {\@@_tan_series_o:NNwwww, \@@_tan_series_aux_o:Nnwww} % Contrarily to \cs{@@_sin_series_o:NNwwww} which received a % conversion auxiliary as~|#1|, here, |#1| is $0$ for tangent % and $2$ for % cotangent. Consider first the case of the tangent. The octant |#3| % starts at $1$, which means that it is $1$ or $2$ for $\lvert % x\rvert\in[0,\pi/2]$, it is $3$ or $4$ for $\lvert % x\rvert\in[\pi/2,\pi]$, and so on: the intervals on which % $\tan\lvert x\rvert\geq 0$ coincide with those for which $\lfloor % (|#3| + 1) / 2\rfloor$ is odd. We also have to take into account % the original sign of $x$ to get the sign of the final result; it is % straightforward to check that the first \cs{int_value:w} expansion % produces $0$ for a positive final result, and $2$ otherwise. A % similar story holds for $\cot(x)$. % % The auxiliary receives the sign, the octant, the square of the % (reduced) input, and the (reduced) input (an extended-precision % number) as arguments. It then % computes the numerator and denominator of % \[ % \tan(x) \simeq % \frac{x (1 - x^2 (a_1 - x^2 (a_2 - x^2 (a_3 - x^2 (a_4 - x^2 a_5)))))} % {1 - x^2 (b_1 - x^2 (b_2 - x^2 (b_3 - x^2 (b_4 - x^2 b_5))))} . % \] % The ratio is computed by \cs{@@_ep_div:wwwwn}, then converted to a % floating point number. For octants~|#3| (really, quadrants) next to % a pole of the % functions, the fixed point numerator and denominator are exchanged % before computing the ratio. Note that this \cs{if_int_odd:w} test % relies on the fact that the octant is at least~$1$. % \begin{macrocode} \cs_new:Npn \@@_tan_series_o:NNwwww #1#2#3. #4; { \@@_fixed_mul:wwn #4; #4; { \exp_after:wN \@@_tan_series_aux_o:Nnwww \int_value:w \if_int_odd:w \@@_int_eval:w #3 / 2 \@@_int_eval_end: \exp_after:wN \reverse_if:N \fi: \if_meaning:w #1#2 2 \else: 0 \fi: {#3} } } \cs_new:Npn \@@_tan_series_aux_o:Nnwww #1 #2 #3; #4,#5; { \@@_fixed_mul_sub_back:wwwn {0000}{0000}{1527}{3493}{0856}{7059}; #3; {0000}{0159}{6080}{0274}{5257}{6472}; \@@_fixed_mul_sub_back:wwwn #3; {0002}{4571}{2320}{0157}{2558}{8481}; \@@_fixed_mul_sub_back:wwwn #3; {0115}{5830}{7533}{5397}{3168}{2147}; \@@_fixed_mul_sub_back:wwwn #3; {1929}{8245}{6140}{3508}{7719}{2982}; \@@_fixed_mul_sub_back:wwwn #3;{10000}{0000}{0000}{0000}{0000}{0000}; { \@@_ep_mul:wwwwn 0, } #4,#5; { \@@_fixed_mul_sub_back:wwwn {0000}{0007}{0258}{0681}{9408}{4706}; #3;{0000}{2343}{7175}{1399}{6151}{7670}; \@@_fixed_mul_sub_back:wwwn #3;{0019}{2638}{4588}{9232}{8861}{3691}; \@@_fixed_mul_sub_back:wwwn #3;{0536}{6357}{0691}{4344}{6852}{4252}; \@@_fixed_mul_sub_back:wwwn #3;{5263}{1578}{9473}{6842}{1052}{6315}; \@@_fixed_mul_sub_back:wwwn#3;{10000}{0000}{0000}{0000}{0000}{0000}; { \reverse_if:N \if_int_odd:w \@@_int_eval:w (#2 - 1) / 2 \@@_int_eval_end: \exp_after:wN \@@_reverse_args:Nww \fi: \@@_ep_div:wwwwn 0, } } { \exp_after:wN \@@_sanitize:Nw \exp_after:wN #1 \int_value:w \@@_int_eval:w \@@_ep_to_float_o:wwN } #1 } % \end{macrocode} % \end{macro} % % \subsection{Inverse trigonometric functions} % % All inverse trigonometric functions (arcsine, arccosine, arctangent, % arccotangent, arccosecant, and arcsecant) are based on a function % often denoted \texttt{atan2}. This function is accessed directly by % feeding two arguments to arctangent, and is defined by \(\operatorname{atan}(y, x) = % \operatorname{atan}(y/x)\) for generic \(y\) and~\(x\). Its advantages over the % conventional arctangent is that it takes values in $[-\pi,\pi]$ rather % than $[-\pi/2,\pi/2]$, and that it is better behaved in boundary % cases. Other inverse trigonometric functions are expressed in terms % of \(\operatorname{atan}\) as % \begin{align} % \operatorname{acos} x & = \operatorname{atan}(\sqrt{1-x^2}, x) \\ % \operatorname{asin} x & = \operatorname{atan}(x, \sqrt{1-x^2}) \\ % \operatorname{asec} x & = \operatorname{atan}(\sqrt{x^2-1}, 1) \\ % \operatorname{acsc} x & = \operatorname{atan}(1, \sqrt{x^2-1}) \\ % \operatorname{atan} x & = \operatorname{atan}(x, 1) \\ % \operatorname{acot} x & = \operatorname{atan}(1, x) . % \end{align} % Rather than introducing a new function, \texttt{atan2}, the arctangent % function \texttt{atan} is overloaded: it can take one or two % arguments. In the comments below, following many texts, we call the % first argument~$y$ and the second~$x$, because $\operatorname{atan}(y, x) = \operatorname{atan}(y % / x)$ is the angular coordinate of the point $(x, y)$. % % As for direct trigonometric functions, the first step in computing % $\operatorname{atan}(y, x)$ is argument reduction. The sign of~$y$ gives that % of the result. We distinguish eight regions where the point $(x, % \lvert y\rvert)$ can lie, of angular size roughly $\pi/8$, % characterized by their \enquote{octant}, between $0$ and~$7$ included. In % each region, we compute an arctangent as a Taylor series, then shift % this arctangent by the appropriate multiple of $\pi/4$ and sign to get % the result. Here is a list of octants, and how we compute the % arctangent (we assume $y>0$: otherwise replace $y$ by~$-y$ below): % \begin{itemize} % \item[0] $0 < \lvert y\rvert < 0.41421 x$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x}$ % is given by a nicely convergent Taylor series; % \item[1] $0 < 0.41421 x < \lvert y\rvert < x$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x} % = \frac{\pi}{4}-\operatorname{atan}\frac{x-\lvert y\rvert}{x+\lvert y\rvert}$; % \item[2] $0 < 0.41421 \lvert y\rvert < x < \lvert y\rvert$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x} % = \frac{\pi}{4}+\operatorname{atan}\frac{-x+\lvert y\rvert}{x+\lvert y\rvert}$; % \item[3] $0 < x < 0.41421 \lvert y\rvert$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x} % = \frac{\pi}{2}-\operatorname{atan}\frac{x}{\lvert y\rvert}$; % \item[4] $0 < -x < 0.41421 \lvert y\rvert$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x} % = \frac{\pi}{2}+\operatorname{atan}\frac{-x}{\lvert y\rvert}$; % \item[5] $0 < 0.41421 \lvert y\rvert < -x < \lvert y\rvert$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x} % =\frac{3\pi}{4}-\operatorname{atan}\frac{x+\lvert y\rvert}{-x+\lvert y\rvert}$; % \item[6] $0 < -0.41421 x < \lvert y\rvert < -x$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x} % =\frac{3\pi}{4}+\operatorname{atan}\frac{-x-\lvert y\rvert}{-x+\lvert y\rvert}$; % \item[7] $0 < \lvert y\rvert < -0.41421 x$, then % $\operatorname{atan}\frac{\lvert y\rvert}{x} % = \pi-\operatorname{atan}\frac{\lvert y\rvert}{-x}$. % \end{itemize} % In the following, we denote by~$z$ the ratio among % $\lvert\frac{y}{x}\rvert$, $\lvert\frac{x}{y}\rvert$, % $\lvert\frac{x+y}{x-y}\rvert$, $\lvert\frac{x-y}{x+y}\rvert$ which % appears in the right-hand side above. % % \subsubsection{Arctangent and arccotangent} % % \begin{macro}[EXP]{\@@_atan_o:Nw, \@@_acot_o:Nw, \@@_atan_default:w} % The parsing step manipulates \texttt{atan} and \texttt{acot} like % \texttt{min} and \texttt{max}, reading in an array of operands, but % also leaves \cs{use_i:nn} or \cs{use_ii:nn} depending on whether the % result should be given in radians or in degrees. The helper % \cs{@@_parse_function_one_two:nnw} checks that the operand is one or % two floating point numbers (not tuples) and leaves its second % argument or its tail accordingly (its first argument is used for % error messages). More precisely if we are given a single floating % point number \cs{@@_atan_default:w} places \cs{c_one_fp} (expanded) % after it; otherwise \cs{@@_atan_default:w} is omitted by % \cs{@@_parse_function_one_two:nnw}. % \begin{macrocode} \cs_new:Npn \@@_atan_o:Nw #1 { \@@_parse_function_one_two:nnw { #1 { atan } { atand } } { \@@_atan_default:w \@@_atanii_o:Nww #1 } } \cs_new:Npn \@@_acot_o:Nw #1 { \@@_parse_function_one_two:nnw { #1 { acot } { acotd } } { \@@_atan_default:w \@@_acotii_o:Nww #1 } } \cs_new:Npe \@@_atan_default:w #1#2#3 @ { #1 #2 #3 \c_one_fp @ } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_atanii_o:Nww, \@@_acotii_o:Nww} % If either operand is \texttt{nan}, we return it. If both are % normal, we call \cs{@@_atan_normal_o:NNnwNnw}. If both are zero or % both infinity, we call \cs{@@_atan_inf_o:NNNw} with argument~$2$, % leading to a result among $\{\pm\pi/4, \pm 3\pi/4\}$ (in degrees, % $\{\pm 45, \pm 135\}$). Otherwise, one is much bigger than the % other, and we call \cs{@@_atan_inf_o:NNNw} with either an argument % of~$4$, leading to the values $\pm\pi/2$ (in degrees,~$\pm 90$), % or~$0$, leading to $\{\pm 0, \pm\pi\}$ (in degrees, $\{\pm 0,\pm % 180\}$). Since $\operatorname{acot}(x, y) = \operatorname{atan}(y, x)$, % \cs{@@_acotii_o:ww} simply reverses its two arguments. % \begin{macrocode} \cs_new:Npn \@@_atanii_o:Nww #1 \s_@@ \@@_chk:w #2#3#4; \s_@@ \@@_chk:w #5 #6 @ { \if_meaning:w 3 #2 \@@_case_return_i_o:ww \fi: \if_meaning:w 3 #5 \@@_case_return_ii_o:ww \fi: \if_case:w \if_meaning:w #2 #5 \if_meaning:w 1 #2 10 \else: 0 \fi: \else: \if_int_compare:w #2 > #5 \exp_stop_f: 1 \else: 2 \fi: \fi: \exp_stop_f: \@@_case_return:nw { \@@_atan_inf_o:NNNw #1 #3 2 } \or: \@@_case_return:nw { \@@_atan_inf_o:NNNw #1 #3 4 } \or: \@@_case_return:nw { \@@_atan_inf_o:NNNw #1 #3 0 } \fi: \@@_atan_normal_o:NNnwNnw #1 \s_@@ \@@_chk:w #2#3#4; \s_@@ \@@_chk:w #5 #6 } \cs_new:Npn \@@_acotii_o:Nww #1#2; #3; { \@@_atanii_o:Nww #1#3; #2; } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_atan_inf_o:NNNw} % This auxiliary is called whenever one number is $\pm 0$ or % $\pm\infty$ (and neither is \nan{}). Then the result only depends % on the signs, and its value is a multiple of $\pi/4$. We use the % same auxiliary as for normal numbers, % \cs{@@_atan_combine_o:NwwwwwN}, with arguments the final sign~|#2|; % the octant~|#3|; $\operatorname{atan} z/z=1$ as a fixed point number; $z=0$~as a % fixed point number; and $z=0$~as an extended-precision number. % Given the values we provide, $\operatorname{atan} z$ is computed to be~$0$, % and the result is $[|#3|/2]\cdot\pi/4$ if the sign~|#5| of~$x$ % is positive, and $[(7-|#3|)/2]\cdot\pi/4$ for negative~$x$, where % the divisions are rounded up. % \begin{macrocode} \cs_new:Npn \@@_atan_inf_o:NNNw #1#2#3 \s_@@ \@@_chk:w #4#5#6; { \exp_after:wN \@@_atan_combine_o:NwwwwwN \exp_after:wN #2 \int_value:w \@@_int_eval:w \if_meaning:w 2 #5 7 - \fi: #3 \exp_after:wN ; \c_@@_one_fixed_tl {0000}{0000}{0000}{0000}{0000}{0000}; 0,{0000}{0000}{0000}{0000}{0000}{0000}; #1 } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_atan_normal_o:NNnwNnw} % Here we simply reorder the floating point data into a pair of signed % extended-precision numbers, that is, a sign, an exponent ending with % a comma, and a six-block mantissa ending with a semi-colon. This % extended precision is required by other inverse trigonometric % functions, to compute things like $\operatorname{atan}(x,\sqrt{1-x^2})$ without % intermediate rounding errors. % \begin{macrocode} \cs_new_protected:Npn \@@_atan_normal_o:NNnwNnw #1 \s_@@ \@@_chk:w 1#2#3#4; \s_@@ \@@_chk:w 1#5#6#7; { \@@_atan_test_o:NwwNwwN #2 #3, #4{0000}{0000}; #5 #6, #7{0000}{0000}; #1 } % \end{macrocode} % \end{macro} % % \begin{macro}[EXP]{\@@_atan_test_o:NwwNwwN} % This receives: the sign~|#1| of~$y$, its exponent~|#2|, its $24$ % digits~|#3| in groups of~$4$, and similarly for~$x$. We prepare to % call \cs{@@_atan_combine_o:NwwwwwN} which expects the sign~|#1|, the % octant, the ratio $(\operatorname{atan} z)/z = 1 - \cdots$, and the value of~$z$, % both as a fixed point number and as an extended-precision floating % point number with a mantissa in $[0.01,1)$. For now, we place |#1| % as a first argument, and start an integer expression for the octant. % The sign of $x$ does not affect~$z$, so we simply leave % a contribution to the octant: $\meta{octant} \to 7 - \meta{octant}$ % for negative~$x$. Then we order $\lvert y\rvert$ and $\lvert % x\rvert$ in a non-decreasing order: if $\lvert y\rvert > \lvert % x\rvert$, insert $3-$ in the expression for the octant, and swap the % two numbers. The finer test with $0.41421$ is done by % \cs{@@_atan_div:wnwwnw} after the operands have been ordered. % \begin{macrocode} \cs_new:Npn \@@_atan_test_o:NwwNwwN #1#2,#3; #4#5,#6; { \exp_after:wN \@@_atan_combine_o:NwwwwwN \exp_after:wN #1 \int_value:w \@@_int_eval:w \if_meaning:w 2 #4 7 - \@@_int_eval:w \fi: \if_int_compare:w \@@_ep_compare:wwww #2,#3; #5,#6; > \c_zero_int 3 - \exp_after:wN \@@_reverse_args:Nww \fi: \@@_atan_div:wnwwnw #2,#3; #5,#6; } % \end{macrocode} % \end{macro} % % \begin{macro}[rEXP]{\@@_atan_div:wnwwnw, \@@_atan_near:wwwn} % \begin{macro}[EXP]{\@@_atan_near_aux:wwn} % This receives two positive numbers $a$ and~$b$ (equal to $\lvert % x\rvert$ and~$\lvert y\rvert$ in some order), each as an exponent % and $6$~blocks of $4$~digits, such that $0 % \end{macrocode} % % \end{implementation} % % \PrintChanges % % \PrintIndex