This is mpc.info, produced by makeinfo version 7.0 from mpc.texi. This manual is for GNU MPC, a library for multiple precision complex arithmetic, version 1.3.1 of December 2022. Copyright © 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011, 2012, 2013, 2016, 2018, 2020, 2022 INRIA Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.3 or any later version published by the Free Software Foundation; with no Invariant Sections. A copy of the license is included in the section entitled “GNU Free Documentation License.” INFO-DIR-SECTION GNU Packages START-INFO-DIR-ENTRY * mpc: (mpc)Multiple Precision Complex Library. END-INFO-DIR-ENTRY  File: mpc.info, Node: Top, Next: Copying, Up: (dir) GNU MPC ******* This manual documents how to install and use the GNU Multiple Precision Complex Library, version 1.3.1 * Menu: * Copying:: GNU MPC Copying Conditions (LGPL). * Introduction to GNU MPC:: Brief introduction to GNU MPC. * Installing GNU MPC:: How to configure and compile the GNU MPC library. * Reporting Bugs:: How to usefully report bugs. * GNU MPC Basics:: What every GNU MPC user should know. * Complex Functions:: Functions for arithmetic on complex numbers. * Ball Arithmetic:: Types and functions for complex balls. * References:: * Concept Index:: * Function Index:: * Type Index:: * GNU Free Documentation License::  File: mpc.info, Node: Copying, Next: Introduction to GNU MPC, Prev: Top, Up: Top GNU MPC Copying Conditions ************************** GNU MPC is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. GNU MPC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program. If not, see .  File: mpc.info, Node: Introduction to GNU MPC, Next: Installing GNU MPC, Prev: Copying, Up: Top 1 Introduction to GNU MPC ************************* GNU MPC is a portable library written in C for arbitrary precision arithmetic on complex numbers providing correct rounding. It implements a multiprecision equivalent of the C99 standard. It builds upon the GNU MP and the GNU MPFR libraries. 1.1 How to use this Manual ========================== Everyone should read *note GNU MPC Basics::. If you need to install the library yourself, you need to read *note Installing GNU MPC::, too. The remainder of the manual can be used for later reference, although it is probably a good idea to skim through it.  File: mpc.info, Node: Installing GNU MPC, Next: Reporting Bugs, Prev: Introduction to GNU MPC, Up: Top 2 Installing GNU MPC ******************** To build GNU MPC, you first have to install GNU MP (version 5.0.0 or higher) and GNU MPFR (version 4.1.0 or higher) on your computer. You need a C compiler; GCC version 4.4 or higher is recommended, since GNU MPC may trigger a bug in previous versions, see the thread at . And you need a standard Unix ‘make’ program, plus some other standard Unix utility programs. Here are the steps needed to install the library on Unix systems: 1. ‘tar xzf mpc-1.3.1.tar.gz’ 2. ‘cd mpc-1.3.1’ 3. ‘./configure’ if GMP and GNU MPFR are installed into standard directories, that is, directories that are searched by default by the compiler and the linking tools. ‘./configure --with-gmp=’ is used to indicate a different location where GMP is installed. Alternatively, you can specify directly GMP include and GMP lib directories with ‘./configure --with-gmp-lib= --with-gmp-include=’. ‘./configure --with-mpfr=’ is used to indicate a different location where GNU MPFR is installed. Alternatively, you can specify directly GNU MPFR include and GNU MPFR lib directories with ‘./configure --with-mpf-lib= --with-mpfr-include=’. Another useful parameter is ‘--prefix’, which can be used to specify an alternative installation location instead of ‘/usr/local’; see ‘make install’ below. To enable checking for memory leaks using ‘valgrind’ during ‘make check’, add the parameter ‘--enable-valgrind-tests’. If for debugging purposes you wish to log calls to GNU MPC functions from within your code, add the parameter ‘--enable-logging’. In your code, replace the inclusion of ‘mpc.h’ by ‘mpc-log.h’ and link the executable dynamically. Then all calls to functions with only complex arguments are printed to ‘stderr’ in the following form: First, the function name is given, followed by its type such as ‘c_cc’, meaning that the function has one complex result (one ‘c’ in front of the ‘_’), computed from two complex arguments (two ‘c’ after the ‘_’). Then, the precisions of the real and the imaginary part of the first result is given, followed by the second one and so on. Finally, for each argument, the precisions of its real and imaginary part are specified and the argument itself is printed in hexadecimal via the function ‘mpc_out_str’ (*note String and Stream Input and Output::). The option requires a dynamic library, so it may not be combined with ‘--disable-shared’. Use ‘./configure --help’ for an exhaustive list of parameters. 4. ‘make’ This compiles GNU MPC in the working directory. 5. ‘make check’ This will make sure GNU MPC was built correctly. If you get error messages, please report them to ‘mpc-discuss@inria.fr’ (*Note Reporting Bugs::, for information on what to include in useful bug reports). 6. ‘make install’ This will copy the file ‘mpc.h’ to the directory ‘/usr/local/include’, the file ‘libmpc.a’ to the directory ‘/usr/local/lib’, and the file ‘mpc.info’ to the directory ‘/usr/local/share/info’ (or if you passed the ‘--prefix’ option to ‘configure’, using the prefix directory given as argument to ‘--prefix’ instead of ‘/usr/local’). Note: you need write permissions on these directories. 2.1 Other ‘make’ Targets ======================== There are some other useful make targets: • ‘info’ Create an info version of the manual, in ‘mpc.info’. • ‘pdf’ Create a PDF version of the manual, in ‘doc/mpc.pdf’. • ‘dvi’ Create a DVI version of the manual, in ‘doc/mpc.dvi’. • ‘ps’ Create a Postscript version of the manual, in ‘doc/mpc.ps’. • ‘html’ Create an HTML version of the manual, in several pages in the directory ‘doc/mpc.html’; if you want only one output HTML file, then type ‘makeinfo --html --no-split mpc.texi’ instead. • ‘clean’ Delete all object files and archive files, but not the configuration files. • ‘distclean’ Delete all files not included in the distribution. • ‘uninstall’ Delete all files copied by ‘make install’. 2.2 Known Build Problems ======================== On AIX, if GMP was built with the 64-bit ABI, before building and testing GNU MPC, it might be necessary to set the ‘OBJECT_MODE’ environment variable to 64 by, e.g., ‘export OBJECT_MODE=64’ This has been tested with the C compiler IBM XL C/C++ Enterprise Edition V8.0 for AIX, version: 08.00.0000.0021, GMP 4.2.4 and GNU MPFR 2.4.1. Please report any other problems you encounter to ‘mpc-discuss@inria.fr’. *Note Reporting Bugs::.  File: mpc.info, Node: Reporting Bugs, Next: GNU MPC Basics, Prev: Installing GNU MPC, Up: Top 3 Reporting Bugs **************** If you think you have found a bug in the GNU MPC library, please investigate and report it. We have made this library available to you, and it is not to ask too much from you, to ask you to report the bugs that you find. There are a few things you should think about when you put your bug report together. You have to send us a test case that makes it possible for us to reproduce the bug. Include instructions on how to run the test case. You also have to explain what is wrong; if you get a crash, or if the results printed are incorrect and in that case, in what way. Please include compiler version information in your bug report. This can be extracted using ‘gcc -v’, or ‘cc -V’ on some machines. Also, include the output from ‘uname -a’. If your bug report is good, we will do our best to help you to get a corrected version of the library; if the bug report is poor, we will not do anything about it (aside of chiding you to send better bug reports). Send your bug report to: ‘mpc-discuss@inria.fr’. If you think something in this manual is unclear, or downright incorrect, or if the language needs to be improved, please send a note to the same address.  File: mpc.info, Node: GNU MPC Basics, Next: Complex Functions, Prev: Reporting Bugs, Up: Top 4 GNU MPC Basics **************** All declarations needed to use GNU MPC are collected in the include file ‘mpc.h’. It is designed to work with both C and C++ compilers. You should include that file in any program using the GNU MPC library by adding the line #include "mpc.h" 4.1 Nomenclature and Types ========================== “Complex number” or “Complex” for short, is a pair of two arbitrary precision floating-point numbers (for the real and imaginary parts). The C data type for such objects is ‘mpc_t’. The “Precision” is the number of bits used to represent the mantissa of the real and imaginary parts; the corresponding C data type is ‘mpfr_prec_t’. For more details on the allowed precision range, *note (mpfr.info)Nomenclature and Types::. The “rounding mode” specifies the way to round the result of a complex operation, in case the exact result can not be represented exactly in the destination mantissa; the corresponding C data type is ‘mpc_rnd_t’. A complex rounding mode is a pair of two rounding modes: one for the real part, one for the imaginary part. 4.2 Function Classes ==================== There is only one class of functions in the GNU MPC library, namely functions for complex arithmetic. The function names begin with ‘mpc_’. The associated type is ‘mpc_t’. 4.3 GNU MPC Variable Conventions ================================ As a general rule, all GNU MPC functions expect output arguments before input arguments. This notation is based on an analogy with the assignment operator. GNU MPC allows you to use the same variable for both input and output in the same expression. For example, the main function for floating-point multiplication, ‘mpc_mul’, can be used like this: ‘mpc_mul (x, x, x, rnd_mode)’. This computes the square of X with rounding mode ‘rnd_mode’ and puts the result back in X. Before you can assign to an GNU MPC variable, you need to initialise it by calling one of the special initialization functions. When you are done with a variable, you need to clear it out, using one of the functions for that purpose. A variable should only be initialised once, or at least cleared out between each initialization. After a variable has been initialised, it may be assigned to any number of times. For efficiency reasons, avoid to initialise and clear out a variable in loops. Instead, initialise it before entering the loop, and clear it out after the loop has exited. You do not need to be concerned about allocating additional space for GNU MPC variables, since each of its real and imaginary part has a mantissa of fixed size. Hence unless you change its precision, or clear and reinitialise it, a complex variable will have the same allocated space during all its life. 4.4 Rounding Modes ================== A complex rounding mode is of the form ‘MPC_RNDxy’ where ‘x’ and ‘y’ are one of ‘N’ (to nearest), ‘Z’ (towards zero), ‘U’ (towards plus infinity), ‘D’ (towards minus infinity), ‘A’ (away from zero, that is, towards plus or minus infinity depending on the sign of the number to be rounded). The first letter refers to the rounding mode for the real part, and the second one for the imaginary part. For example ‘MPC_RNDZU’ indicates to round the real part towards zero, and the imaginary part towards plus infinity. The ‘round to nearest’ mode works as in the IEEE P754 standard: in case the number to be rounded lies exactly in the middle of two representable numbers, it is rounded to the one with the least significant bit set to zero. For example, the number 5, which is represented by (101) in binary, is rounded to (100)=4 with a precision of two bits, and not to (110)=6. 4.5 Return Value ================ Most GNU MPC functions have a return value of type ‘int’, which is used to indicate the position of the rounded real and imaginary parts with respect to the exact (infinite precision) values. If this integer is ‘i’, the macros ‘MPC_INEX_RE(i)’ and ‘MPC_INEX_IM(i)’ give 0 if the corresponding rounded value is exact, a negative value if the rounded value is less than the exact one, and a positive value if it is greater than the exact one. Similarly, functions computing a result of type ‘mpfr_t’ return an integer that is 0, positive or negative depending on whether the rounded value is the same, larger or smaller then the exact result. Some functions, such as ‘mpc_sin_cos’, compute two complex results; the macros ‘MPC_INEX1(i)’ and ‘MPC_INEX2(i)’, applied to the return value ‘i’ of such a function, yield the exactness value corresponding to the first or the second computed value, respectively. 4.6 Branch Cuts And Special Values ================================== Some complex functions have branch cuts, across which the function is discontinous. In GNU MPC, the branch cuts chosen are the same as those specified for the corresponding functions in the ISO C99 standard. Likewise, when evaluated at a point whose real or imaginary part is either infinite or a NaN or a signed zero, a function returns the same value as those specified for the corresponding function in the ISO C99 standard.  File: mpc.info, Node: Complex Functions, Next: Ball Arithmetic, Prev: GNU MPC Basics, Up: Top 5 Complex Functions ******************* The complex functions expect arguments of type ‘mpc_t’. The GNU MPC floating-point functions have an interface that is similar to the GNU MP integer functions. The function prefix for operations on complex numbers is ‘mpc_’. The precision of a computation is defined as follows: Compute the requested operation exactly (with “infinite precision”), and round the result to the destination variable precision with the given rounding mode. The GNU MPC complex functions are intended to be a smooth extension of the IEEE P754 arithmetic. The results obtained on one computer should not differ from the results obtained on a computer with a different word size. * Menu: * Initializing Complex Numbers:: * Assigning Complex Numbers:: * Converting Complex Numbers:: * String and Stream Input and Output:: * Complex Comparison:: * Projection & Decomposing:: * Basic Arithmetic:: * Power Functions and Logarithm:: * Trigonometric Functions:: * Modular Functions:: * Miscellaneous Complex Functions:: * Advanced Functions:: * Internals::  File: mpc.info, Node: Initializing Complex Numbers, Next: Assigning Complex Numbers, Up: Complex Functions 5.1 Initialization Functions ============================ An ‘mpc_t’ object must be initialised before storing the first value in it. The functions ‘mpc_init2’ and ‘mpc_init3’ are used for that purpose. -- Function: void mpc_init2 (mpc_t Z, mpfr_prec_t PREC) Initialise Z to precision PREC bits and set its real and imaginary parts to NaN. Normally, a variable should be initialised once only or at least be cleared, using ‘mpc_clear’, between initializations. -- Function: void mpc_init3 (mpc_t Z, mpfr_prec_t PREC_R, mpfr_prec_t PREC_I) Initialise Z with the precision of its real part being PREC_R bits and the precision of its imaginary part being PREC_I bits, and set the real and imaginary parts to NaN. -- Function: void mpc_clear (mpc_t Z) Free the space occupied by Z. Make sure to call this function for all ‘mpc_t’ variables when you are done with them. Here is an example on how to initialise complex variables: { mpc_t x, y; mpc_init2 (x, 256); /* precision _exactly_ 256 bits */ mpc_init3 (y, 100, 50); /* 100/50 bits for the real/imaginary part */ ... mpc_clear (x); mpc_clear (y); } The following function is useful for changing the precision during a calculation. A typical use would be for adjusting the precision gradually in iterative algorithms like Newton-Raphson, making the computation precision closely match the actual accurate part of the numbers. -- Function: void mpc_set_prec (mpc_t X, mpfr_prec_t PREC) Reset the precision of X to be *exactly* PREC bits, and set its real/imaginary parts to NaN. The previous value stored in X is lost. It is equivalent to a call to ‘mpc_clear(x)’ followed by a call to ‘mpc_init2(x, prec)’, but more efficient as no allocation is done in case the current allocated space for the mantissa of X is sufficient. -- Function: mpfr_prec_t mpc_get_prec (const mpc_t X) If the real and imaginary part of X have the same precision, it is returned, otherwise, 0 is returned. -- Function: void mpc_get_prec2 (mpfr_prec_t* PR, mpfr_prec_t* PI, const mpc_t X) Returns the precision of the real part of X via PR and of its imaginary part via PI.  File: mpc.info, Node: Assigning Complex Numbers, Next: Converting Complex Numbers, Prev: Initializing Complex Numbers, Up: Complex Functions 5.2 Assignment Functions ======================== These functions assign new values to already initialised complex numbers (*note Initializing Complex Numbers::). When using any functions with ‘intmax_t’ or ‘uintmax_t’ parameters, you must include ‘’ or ‘’ _before_ ‘mpc.h’, to allow ‘mpc.h’ to define prototypes for these functions. Similarly, functions with parameters of type ‘complex’ or ‘long complex’ are defined only if ‘’ is included _before_ ‘mpc.h’. If you need assignment functions that are not in the current API, you can define them using the ‘MPC_SET_X_Y’ macro (*note Advanced Functions::). -- Function: int mpc_set (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set the value of ROP from OP, rounded to the precision of ROP with the given rounding mode RND. -- Function: int mpc_set_ui (mpc_t ROP, unsigned long int OP, mpc_rnd_t RND) -- Function: int mpc_set_si (mpc_t ROP, long int OP, mpc_rnd_t RND) -- Function: int mpc_set_uj (mpc_t ROP, uintmax_t OP, mpc_rnd_t RND) -- Function: int mpc_set_sj (mpc_t ROP, intmax_t OP, mpc_rnd_t RND) -- Function: int mpc_set_d (mpc_t ROP, double OP, mpc_rnd_t RND) -- Function: int mpc_set_ld (mpc_t ROP, long double OP, mpc_rnd_t RND) -- Function: int mpc_set_dc (mpc_t ROP, double _Complex OP, mpc_rnd_t RND) -- Function: int mpc_set_ldc (mpc_t ROP, long double _Complex OP, mpc_rnd_t RND) -- Function: int mpc_set_z (mpc_t ROP, const mpz_t OP mpc_rnd_t RND) -- Function: int mpc_set_q (mpc_t ROP, const mpq_t OP mpc_rnd_t RND) -- Function: int mpc_set_f (mpc_t ROP, const mpf_t OP mpc_rnd_t RND) -- Function: int mpc_set_fr (mpc_t ROP, const mpfr_t OP, mpc_rnd_t RND) Set the value of ROP from OP, rounded to the precision of ROP with the given rounding mode RND. The argument OP is interpreted as real, so the imaginary part of ROP is set to zero with a positive sign. Please note that even a ‘long int’ may have to be rounded, if the destination precision is less than the machine word width. For ‘mpc_set_d’, be careful that the input number OP may not be exactly representable as a double-precision number (this happens for 0.1 for instance), in which case it is first rounded by the C compiler to a double-precision number, and then only to a complex number. -- Function: int mpc_set_ui_ui (mpc_t ROP, unsigned long int OP1, unsigned long int OP2, mpc_rnd_t RND) -- Function: int mpc_set_si_si (mpc_t ROP, long int OP1, long int OP2, mpc_rnd_t RND) -- Function: int mpc_set_uj_uj (mpc_t ROP, uintmax_t OP1, uintmax_t OP2, mpc_rnd_t RND) -- Function: int mpc_set_sj_sj (mpc_t ROP, intmax_t OP1, intmax_t OP2, mpc_rnd_t RND) -- Function: int mpc_set_d_d (mpc_t ROP, double OP1, double OP2, mpc_rnd_t RND) -- Function: int mpc_set_ld_ld (mpc_t ROP, long double OP1, long double OP2, mpc_rnd_t RND) -- Function: int mpc_set_z_z (mpc_t ROP, const mpz_t OP1, const mpz_t OP2, mpc_rnd_t RND) -- Function: int mpc_set_q_q (mpc_t ROP, const mpq_t OP1, const mpq_t OP2, mpc_rnd_t RND) -- Function: int mpc_set_f_f (mpc_t ROP, const mpf_t OP1, const mpf_t OP2, mpc_rnd_t RND) -- Function: int mpc_set_fr_fr (mpc_t ROP, const mpfr_t OP1, const mpfr_t OP2, mpc_rnd_t RND) Set the real part of ROP from OP1, and its imaginary part from OP2, according to the rounding mode RND. Beware that the behaviour of ‘mpc_set_fr_fr’ is undefined if OP1 or OP2 is a pointer to the real or imaginary part of ROP. To exchange the real and the imaginary part of a complex number, either use ‘mpfr_swap (mpc_realref (rop), mpc_imagref (rop))’, which also exchanges the precisions of the two parts; or use a temporary variable. For functions assigning complex variables from strings or input streams, *note String and Stream Input and Output::. -- Function: void mpc_set_nan (mpc_t ROP) Set ROP to Nan+i*NaN. -- Function: void mpc_swap (mpc_t OP1, mpc_t OP2) Swap the values of OP1 and OP2 efficiently. Warning: The precisions are exchanged, too; in case these are different, ‘mpc_swap’ is thus not equivalent to three ‘mpc_set’ calls using a third auxiliary variable.  File: mpc.info, Node: Converting Complex Numbers, Next: String and Stream Input and Output, Prev: Assigning Complex Numbers, Up: Complex Functions 5.3 Conversion Functions ======================== The following functions are available only if ‘’ is included _before_ ‘mpc.h’. -- Function: double _Complex mpc_get_dc (const mpc_t OP, mpc_rnd_t RND) -- Function: long double _Complex mpc_get_ldc (mpc_t OP, mpc_rnd_t RND) Convert OP to a C complex number, using the rounding mode RND. For functions converting complex variables to strings or stream output, *note String and Stream Input and Output::.  File: mpc.info, Node: String and Stream Input and Output, Next: Complex Comparison, Prev: Converting Complex Numbers, Up: Complex Functions 5.4 String and Stream Input and Output ====================================== -- Function: int mpc_strtoc (mpc_t ROP, const char *NPTR, char **ENDPTR, int BASE, mpc_rnd_t RND) Read a complex number from a string NPTR in base BASE, rounded to the precision of ROP with the given rounding mode RND. The BASE must be either 0 or a number from 2 to 36 (otherwise the behaviour is undefined). If NPTR starts with valid data, the result is stored in ROP, the usual inexact value is returned (*note Return Value: return-value.) and, if ENDPTR is not the null pointer, *ENDPTR points to the character just after the valid data. Otherwise, ROP is set to ‘NaN + i * NaN’, -1 is returned and, if ENDPTR is not the null pointer, the value of NPTR is stored in the location referenced by ENDPTR. The expected form of a complex number string is either a real number (an optional leading whitespace, an optional sign followed by a floating-point number), or a pair of real numbers in parentheses separated by whitespace. If a real number is read, the missing imaginary part is set to +0. The form of a floating-point number depends on the base and is described in the documentation of ‘mpfr_strtofr’ (*note (mpfr.info)Assignment Functions::). For instance, ‘"3.1415926"’, ‘"(1.25e+7 +.17)"’, ‘"(@nan@ 2)"’ and ‘"(-0 -7)"’ are valid strings for BASE = 10. If BASE = 0, then a prefix may be used to indicate the base in which the floating-point number is written. Use prefix ’0b’ for binary numbers, prefix ’0x’ for hexadecimal numbers, and no prefix for decimal numbers. The real and imaginary part may then be written in different bases. For instance, ‘"(1.024e+3 +2.05e+3)"’ and ‘"(0b1p+10 +0x802)"’ are valid strings for ‘base’=0 and represent the same value. -- Function: int mpc_set_str (mpc_t ROP, const char *S, int BASE, mpc_rnd_t rnd) Set ROP to the value of the string S in base BASE, rounded to the precision of ROP with the given rounding mode RND. See the documentation of ‘mpc_strtoc’ for a detailed description of the valid string formats. Contrarily to ‘mpc_strtoc’, ‘mpc_set_str’ requires the _whole_ string to represent a valid complex number (potentially followed by additional white space). This function returns the usual inexact value (*note Return Value: return-value.) if the entire string up to the final null character is a valid number in base BASE; otherwise it returns −1, and ROP is set to NaN+i*NaN. -- Function: char * mpc_get_str (int B, size_t N, const mpc_t OP, mpc_rnd_t RND) Convert OP to a string containing its real and imaginary parts, separated by a space and enclosed in a pair of parentheses. The numbers are written in base B (which may vary from 2 to 36) and rounded according to RND. The number of significant digits, at least 2, is given by N. It is also possible to let N be zero, in which case the number of digits is chosen large enough so that re-reading the printed value with the same precision, assuming both output and input use rounding to nearest, will recover the original value of OP. Note that ‘mpc_get_str’ uses the decimal point of the current locale if available, and ‘.’ otherwise. The string is generated using the current memory allocation function (‘malloc’ by default, unless it has been modified using the custom memory allocation interface of ‘gmp’); once it is not needed any more, it should be freed by calling ‘mpc_free_str’. -- Function: void mpc_free_str (char *STR) Free the string STR, which needs to have been allocated by a call to ‘mpc_get_str’. The following two functions read numbers from input streams and write them to output streams. When using any of these functions, you need to include ‘stdio.h’ _before_ ‘mpc.h’. -- Function: int mpc_inp_str (mpc_t ROP, FILE *STREAM, size_t *READ, int BASE, mpc_rnd_t RND) Input a string in base BASE in the same format as for ‘mpc_strtoc’ from stdio stream STREAM, rounded according to RND, and put the read complex number into ROP. If STREAM is the null pointer, ROP is read from ‘stdin’. Return the usual inexact value; if an error occurs, set ROP to ‘NaN + i * NaN’ and return -1. If READ is not the null pointer, it is set to the number of read characters. Unlike ‘mpc_strtoc’, the function ‘mpc_inp_str’ does not possess perfect knowledge of the string to transform and has to read it character by character, so it behaves slightly differently: It tries to read a string describing a complex number and processes this string through a call to ‘mpc_set_str’. Precisely, after skipping optional whitespace, a minimal string is read according to the regular expression ‘mpfr | '(' \s* mpfr \s+ mpfr \s* ')'’, where ‘\s’ denotes a whitespace, and ‘mpfr’ is either a string containing neither whitespaces nor parentheses, or ‘nan(n-char-sequence)’ or ‘@nan@(n-char-sequence)’ (regardless of capitalisation) with ‘n-char-sequence’ a string of ascii letters, digits or ‘'_'’. For instance, upon input of ‘"nan(13 1)"’, the function ‘mpc_inp_str’ starts to recognise a value of NaN followed by an n-char-sequence indicated by the opening parenthesis; as soon as the space is reached, it becomes clear that the expression in parentheses is not an n-char-sequence, and the error flag -1 is returned after 6 characters have been consumed from the stream (the whitespace itself remaining in the stream). The function ‘mpc_strtoc’, on the other hand, may track back when reaching the whitespace; it treats the string as the two successive complex numbers ‘NaN + i * 0’ and ‘13 + i’. It is thus recommended to have a whitespace follow each floating point number to avoid this problem. -- Function: size_t mpc_out_str (FILE *STREAM, int BASE, size_t N_DIGITS, const mpc_t OP, mpc_rnd_t RND) Output OP on stdio stream STREAM in base BASE, rounded according to RND, in the same format as for ‘mpc_strtoc’ If STREAM is the null pointer, ROP is written to ‘stdout’. Return the number of characters written.  File: mpc.info, Node: Complex Comparison, Next: Projection & Decomposing, Prev: String and Stream Input and Output, Up: Complex Functions 5.5 Comparison Functions ======================== -- Function: int mpc_cmp (const mpc_t OP1, const mpc_t OP2) -- Function: int mpc_cmp_si_si (const mpc_t OP1, long int OP2R, long int OP2I) -- Macro: int mpc_cmp_si (mpc_t OP1, long int OP2) Compare OP1 and OP2, where in the case of ‘mpc_cmp_si_si’, OP2 is taken to be OP2R + i OP2I. The return value C can be decomposed into ‘x = MPC_INEX_RE(c)’ and ‘y = MPC_INEX_IM(c)’, such that X is positive if the real part of OP1 is greater than that of OP2, zero if both real parts are equal, and negative if the real part of OP1 is less than that of OP2, and likewise for Y. Both OP1 and OP2 are considered to their full own precision, which may differ. It is not allowed that one of the operands has a NaN (Not-a-Number) part. The storage of the return value is such that equality can be simply checked with ‘mpc_cmp (op1, op2) == 0’. -- Function: int mpc_cmp_abs (const mpc_t OP1, const mpc_t OP2) Compare the absolute values of OP1 and OP2. The return value is 0 if both are the same (including infinity), positive if the absolute value of OP1 is greater than that of OP2, and negative if it is smaller. If OP1 or OP2 has a real or imaginary part which is NaN, the function behaves like ‘mpfr_cmp’ on two real numbers of which at least one is NaN.  File: mpc.info, Node: Projection & Decomposing, Next: Basic Arithmetic, Prev: Complex Comparison, Up: Complex Functions 5.6 Projection and Decomposing Functions ======================================== -- Function: int mpc_real (mpfr_t ROP, const mpc_t OP, mpfr_rnd_t RND) Set ROP to the value of the real part of OP rounded in the direction RND. -- Function: int mpc_imag (mpfr_t ROP, const mpc_t OP, mpfr_rnd_t RND) Set ROP to the value of the imaginary part of OP rounded in the direction RND. -- Macro: mpfr_t mpc_realref (mpc_t OP) -- Macro: mpfr_t mpc_imagref (mpc_t OP) Return a reference to the real part and imaginary part of OP, respectively. The ‘mpfr’ functions can be used on the result of these macros (note that the ‘mpfr_t’ type is itself a pointer). -- Function: int mpc_arg (mpfr_t ROP, const mpc_t OP, mpfr_rnd_t RND) Set ROP to the argument of OP, with a branch cut along the negative real axis. -- Function: int mpc_proj (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Compute a projection of OP onto the Riemann sphere. Set ROP to OP rounded in the direction RND, except when at least one part of OP is infinite (even if the other part is a NaN) in which case the real part of ROP is set to plus infinity and its imaginary part to a signed zero with the same sign as the imaginary part of OP.  File: mpc.info, Node: Basic Arithmetic, Next: Power Functions and Logarithm, Prev: Projection & Decomposing, Up: Complex Functions 5.7 Basic Arithmetic Functions ============================== All the following functions are designed in such a way that, when working with real numbers instead of complex numbers, their complexity should essentially be the same as with the GNU MPFR library, with only a marginal overhead due to the GNU MPC layer. For functions taking as input an integer argument (for example ‘mpc_add_ui’), when this argument is zero, it is considered as an unsigned (that is, exact in this context) zero, and we follow the MPFR conventions: (0) + (+0) = +0, (0) - (+0) = -0, (0) - (+0) = -0, (0) - (-0) = +0. The same applies for functions taking an argument of type ‘mpfr_t’, such as ‘mpc_add_fr’, of which the imaginary part is considered to be an exact, unsigned zero. -- Function: int mpc_add (mpc_t ROP, const mpc_t OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_add_ui (mpc_t ROP, const mpc_t OP1, unsigned long int OP2, mpc_rnd_t RND) -- Function: int mpc_add_fr (mpc_t ROP, const mpc_t OP1, const mpfr_t OP2, mpc_rnd_t RND) Set ROP to OP1 + OP2 rounded according to RND. -- Function: int mpc_sub (mpc_t ROP, const mpc_t OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_sub_fr (mpc_t ROP, const mpc_t OP1, const mpfr_t OP2, mpc_rnd_t RND) -- Function: int mpc_fr_sub (mpc_t ROP, const mpfr_t OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_sub_ui (mpc_t ROP, const mpc_t OP1, unsigned long int OP2, mpc_rnd_t RND) -- Macro: int mpc_ui_sub (mpc_t ROP, unsigned long int OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_ui_ui_sub (mpc_t ROP, unsigned long int RE1, unsigned long int IM1, mpc_t OP2, mpc_rnd_t RND) Set ROP to OP1 − OP2 rounded according to RND. For ‘mpc_ui_ui_sub’, OP1 is RE1 + IM1. -- Function: int mpc_neg (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to −OP rounded according to RND. Just changes the sign if ROP and OP are the same variable. -- Function: int mpc_sum (mpc_t ROP, const mpc_ptr* OP, unsigned long N, mpc_rnd_t RND) Set ROP to the sum of the elements in the array OP of length N, rounded according to RND. -- Function: int mpc_mul (mpc_t ROP, const mpc_t OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_mul_ui (mpc_t ROP, const mpc_t OP1, unsigned long int OP2, mpc_rnd_t RND) -- Function: int mpc_mul_si (mpc_t ROP, const mpc_t OP1, long int OP2, mpc_rnd_t RND) -- Function: int mpc_mul_fr (mpc_t ROP, const mpc_t OP1, const mpfr_t OP2, mpc_rnd_t RND) Set ROP to OP1 times OP2 rounded according to RND. Note: for ‘mpc_mul’, in case OP1 and OP2 have the same value, use ‘mpc_sqr’ for better efficiency. -- Function: int mpc_mul_i (mpc_t ROP, const mpc_t OP, int SGN, mpc_rnd_t RND) Set ROP to OP times the imaginary unit i if SGN is non-negative, set ROP to OP times -i otherwise, in both cases rounded according to RND. -- Function: int mpc_sqr (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the square of OP rounded according to RND. -- Function: int mpc_fma (mpc_t ROP, const mpc_t OP1, const mpc_t OP2, const mpc_t OP3, mpc_rnd_t RND) Set ROP to OP1*OP2+OP3, rounded according to RND, with only one final rounding. -- Function: int mpc_dot (mpc_t ROP, const mpc_ptr* OP1, mpc_ptr* OP2, unsigned long N, mpc_rnd_t RND) Set ROP to the dot product of the elements in the arrays OP1 and OP2, both of length N, rounded according to RND. -- Function: int mpc_div (mpc_t ROP, const mpc_t OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_div_ui (mpc_t ROP, const mpc_t OP1, unsigned long int OP2, mpc_rnd_t RND) -- Function: int mpc_div_fr (mpc_t ROP, const mpc_t OP1, const mpfr_t OP2, mpc_rnd_t RND) -- Function: int mpc_ui_div (mpc_t ROP, unsigned long int OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_fr_div (mpc_t ROP, const mpfr_t OP1, const mpc_t OP2, mpc_rnd_t RND) Set ROP to OP1/OP2 rounded according to RND. -- Function: int mpc_conj (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the conjugate of OP rounded according to RND. Just changes the sign of the imaginary part if ROP and OP are the same variable. -- Function: int mpc_abs (mpfr_t ROP, const mpc_t OP, mpfr_rnd_t RND) Set the floating-point number ROP to the absolute value of OP, rounded in the direction RND. -- Function: int mpc_norm (mpfr_t ROP, const mpc_t OP, mpfr_rnd_t RND) Set the floating-point number ROP to the norm of OP (i.e., the square of its absolute value), rounded in the direction RND. -- Function: int mpc_mul_2ui (mpc_t ROP, const mpc_t OP1, unsigned long int OP2, mpc_rnd_t RND) -- Function: int mpc_mul_2si (mpc_t ROP, const mpc_t OP1, long int OP2, mpc_rnd_t RND) Set ROP to OP1 times 2 raised to OP2 rounded according to RND. Just modifies the exponents of the real and imaginary parts by OP2 when ROP and OP1 are identical. -- Function: int mpc_div_2ui (mpc_t ROP, const mpc_t OP1, unsigned long int OP2, mpc_rnd_t RND) -- Function: int mpc_div_2si (mpc_t ROP, const mpc_t OP1, long int OP2, mpc_rnd_t RND) Set ROP to OP1 divided by 2 raised to OP2 rounded according to RND. Just modifies the exponents of the real and imaginary parts by OP2 when ROP and OP1 are identical.  File: mpc.info, Node: Power Functions and Logarithm, Next: Trigonometric Functions, Prev: Basic Arithmetic, Up: Complex Functions 5.8 Power Functions and Logarithm ================================= -- Function: int mpc_sqrt (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the square root of OP rounded according to RND. The returned value ROP has a non-negative real part, and if its real part is zero, a non-negative imaginary part. -- Function: int mpc_pow (mpc_t ROP, const mpc_t OP1, const mpc_t OP2, mpc_rnd_t RND) -- Function: int mpc_pow_d (mpc_t ROP, const mpc_t OP1, double OP2, mpc_rnd_t RND) -- Function: int mpc_pow_ld (mpc_t ROP, const mpc_t OP1, long double OP2, mpc_rnd_t RND) -- Function: int mpc_pow_si (mpc_t ROP, const mpc_t OP1, long OP2, mpc_rnd_t RND) -- Function: int mpc_pow_ui (mpc_t ROP, const mpc_t OP1, unsigned long OP2, mpc_rnd_t RND) -- Function: int mpc_pow_z (mpc_t ROP, const mpc_t OP1, const mpz_t OP2, mpc_rnd_t RND) -- Function: int mpc_pow_fr (mpc_t ROP, const mpc_t OP1, const mpfr_t OP2, mpc_rnd_t RND) Set ROP to OP1 raised to the power OP2, rounded according to RND. For ‘mpc_pow_d’, ‘mpc_pow_ld’, ‘mpc_pow_si’, ‘mpc_pow_ui’, ‘mpc_pow_z’ and ‘mpc_pow_fr’, the imaginary part of OP2 is considered as +0. When both OP1 and OP2 are zero, the result has real part 1, and imaginary part 0, with sign being the opposite of that of OP2. -- Function: int mpc_exp (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the exponential of OP, rounded according to RND with the precision of ROP. -- Function: int mpc_log (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_log10 (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the natural and base-10 logarithm of OP respectively, rounded according to RND with the precision of ROP. The principal branch is chosen, with the branch cut on the negative real axis, so that the imaginary part of the result lies in ]-Pi , Pi] and ]-Pi/log(10) , Pi/log(10)] respectively. -- Function: int mpc_rootofunity (mpc_t ROP, unsigned long int N, unsigned long int K, mpc_rnd_t RND) Set ROP to the standard primitive N-th root of unity raised to the power K, that is, exp (2 Pi i k / n), rounded according to RND with the precision of ROP. -- Function: int mpc_agm (mpc_t ROP, const mpc_t A, const mpc_t B, mpc_rnd_t RND) Set ROP to the arithmetic-geometric mean (AGM) of A and B, rounded according to RND with the precision of ROP. Concerning the branch cut, the function is computed by homogeneity either as A AGM(1,b0) with b0=B/A if |A|>=|B|, or as B AGM(1,b0) with b0=A/B otherwise; then when b0 is real and negative, AGM(1,b0) is chosen to have positive imaginary part.  File: mpc.info, Node: Trigonometric Functions, Next: Modular Functions, Prev: Power Functions and Logarithm, Up: Complex Functions 5.9 Trigonometric Functions =========================== -- Function: int mpc_sin (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_cos (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_tan (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the sine, cosine, tangent of OP, rounded according to RND with the precision of ROP. -- Function: int mpc_sin_cos (mpc_t ROP_SIN, mpc_t ROP_COS, const mpc_t OP, mpc_rnd_t RND_SIN, mpc_rnd_t RND_COS) Set ROP_SIN to the sine of OP, rounded according to RND_SIN with the precision of ROP_SIN, and ROP_COS to the cosine of OP, rounded according to RND_COS with the precision of ROP_COS. -- Function: int mpc_sinh (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_cosh (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_tanh (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the hyperbolic sine, hyperbolic cosine, hyperbolic tangent of OP, rounded according to RND with the precision of ROP. -- Function: int mpc_asin (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_acos (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_atan (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the inverse sine, inverse cosine, inverse tangent of OP, rounded according to RND with the precision of ROP. -- Function: int mpc_asinh (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_acosh (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) -- Function: int mpc_atanh (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Set ROP to the inverse hyperbolic sine, inverse hyperbolic cosine, inverse hyperbolic tangent of OP, rounded according to RND with the precision of ROP. The branch cut of ‘mpc_acosh’ is (-Inf, 1)  File: mpc.info, Node: Modular Functions, Next: Miscellaneous Complex Functions, Prev: Trigonometric Functions, Up: Complex Functions 5.10 Modular Functions ====================== The following function is experimental, not least because it depends on the equally experimental ball arithmetic, see *note Ball Arithmetic::. So its prototype may change in future releases, and it may be removed altogether. -- Function: int mpc_eta_fund (mpc_t ROP, const mpc_t OP, mpc_rnd_t RND) Assuming that the argument OP lies in the fundamental domain for Sl_2(Z), that is, it has real part not below -1/2 and not above +1/2 and absolute value at least 1, return the value of the Dedekind eta-function in ROP. For arguments outside the fundamental domain the function is expected to loop indefinitely.  File: mpc.info, Node: Miscellaneous Complex Functions, Next: Advanced Functions, Prev: Modular Functions, Up: Complex Functions 5.11 Miscellaneous Functions ============================ -- Function: int mpc_urandom (mpc_t ROP, gmp_randstate_t STATE) Generate a uniformly distributed random complex in the unit square [0, 1] x [0, 1]. Return 0, unless an exponent in the real or imaginary part is not in the current exponent range, in which case that part is set to NaN and a zero value is returned. The second argument is a ‘gmp_randstate_t’ structure which should be created using the GMP ‘rand_init’ function, see the GMP manual. -- Function: const char * mpc_get_version (void) Return the GNU MPC version, as a null-terminated string. -- Macro: MPC_VERSION -- Macro: MPC_VERSION_MAJOR -- Macro: MPC_VERSION_MINOR -- Macro: MPC_VERSION_PATCHLEVEL -- Macro: MPC_VERSION_STRING ‘MPC_VERSION’ is the version of GNU MPC as a preprocessing constant. ‘MPC_VERSION_MAJOR’, ‘MPC_VERSION_MINOR’ and ‘MPC_VERSION_PATCHLEVEL’ are respectively the major, minor and patch level of GNU MPC version, as preprocessing constants. ‘MPC_VERSION_STRING’ is the version as a string constant, which can be compared to the result of ‘mpc_get_version’ to check at run time the header file and library used match: if (strcmp (mpc_get_version (), MPC_VERSION_STRING)) fprintf (stderr, "Warning: header and library do not match\n"); Note: Obtaining different strings is not necessarily an error, as in general, a program compiled with some old GNU MPC version can be dynamically linked with a newer GNU MPC library version (if allowed by the library versioning system). -- Macro: long MPC_VERSION_NUM (MAJOR, MINOR, PATCHLEVEL) Create an integer in the same format as used by ‘MPC_VERSION’ from the given MAJOR, MINOR and PATCHLEVEL. Here is an example of how to check the GNU MPC version at compile time: #if (!defined(MPC_VERSION) || (MPC_VERSION. • Guillaume Hanrot, Vincent Lefèvre, Patrick Pélissier, Paul Zimmermann et al. ‘MPFR’ – A library for multiple-precision floating-point computations with exact rounding. Version 4.1.0, . • IEEE Standard for Floating-Point Arithmetic, IEEE Computer Society, IEEE Std 754-2019, Approved 13 June 2019, 84 pages. • Donald E. Knuth, "The Art of Computer Programming", vol 2, "Seminumerical Algorithms", 2nd edition, Addison-Wesley, 1981. • ISO/IEC 9899:1999, Programming languages — C.  File: mpc.info, Node: Concept Index, Next: Function Index, Prev: References, Up: Top Concept Index ************* [index] * Menu: * Arithmetic functions: Basic Arithmetic. (line 6) * Ball arithmetic: Ball Arithmetic. (line 6) * Comparison functions: Complex Comparison. (line 6) * Complex arithmetic functions: Basic Arithmetic. (line 6) * Complex assignment functions: Assigning Complex Numbers. (line 6) * Complex comparisons functions: Complex Comparison. (line 6) * Complex functions: Complex Functions. (line 6) * Complex number: GNU MPC Basics. (line 15) * Conditions for copying GNU MPC: Copying. (line 6) * Conversion functions: Converting Complex Numbers. (line 6) * Copying conditions: Copying. (line 6) * Installation: Installing GNU MPC. (line 6) * Logarithm: Power Functions and Logarithm. (line 6) * Miscellaneous complex functions: Miscellaneous Complex Functions. (line 6) * Modular functions: Modular Functions. (line 6) * mpc.h: GNU MPC Basics. (line 6) * Power functions: Power Functions and Logarithm. (line 6) * Precision: GNU MPC Basics. (line 19) * Projection and Decomposing Functions: Projection & Decomposing. (line 6) * Reporting bugs: Reporting Bugs. (line 6) * Rounding Mode: GNU MPC Basics. (line 24) * String and stream input and output: String and Stream Input and Output. (line 6) * Trigonometric functions: Trigonometric Functions. (line 6) * User-defined precision: Complex Functions. (line 12)  File: mpc.info, Node: Function Index, Next: Type Index, Prev: Concept Index, Up: Top Function Index ************** [index] * Menu: * _Complex: Converting Complex Numbers. (line 9) * mpcb_add: Ball Arithmetic. (line 260) * mpcb_can_round: Ball Arithmetic. (line 273) * mpcb_clear: Ball Arithmetic. (line 194) * mpcb_div: Ball Arithmetic. (line 266) * mpcb_div_2ui: Ball Arithmetic. (line 267) * mpcb_get_prec: Ball Arithmetic. (line 201) * mpcb_init: Ball Arithmetic. (line 193) * mpcb_mul: Ball Arithmetic. (line 261) * mpcb_neg: Ball Arithmetic. (line 259) * mpcb_pow_ui: Ball Arithmetic. (line 263) * mpcb_round: Ball Arithmetic. (line 309) * mpcb_set: Ball Arithmetic. (line 205) * mpcb_set_c: Ball Arithmetic. (line 214) * mpcb_set_inf: Ball Arithmetic. (line 208) * mpcb_set_ui_ui: Ball Arithmetic. (line 254) * mpcb_sqr: Ball Arithmetic. (line 262) * mpcb_sqrt: Ball Arithmetic. (line 265) * mpcr_add: Ball Arithmetic. (line 93) * mpcr_add_rounding_error: Ball Arithmetic. (line 125) * mpcr_cmp: Ball Arithmetic. (line 64) * mpcr_c_abs_rnd: Ball Arithmetic. (line 120) * mpcr_div: Ball Arithmetic. (line 96) * mpcr_div_2ui: Ball Arithmetic. (line 99) * mpcr_get_exp: Ball Arithmetic. (line 81) * mpcr_inf_p: Ball Arithmetic. (line 55) * mpcr_lt_half_p: Ball Arithmetic. (line 60) * mpcr_max: Ball Arithmetic. (line 78) * mpcr_mul: Ball Arithmetic. (line 95) * mpcr_mul_2ui: Ball Arithmetic. (line 97) * mpcr_out_str: Ball Arithmetic. (line 88) * mpcr_set: Ball Arithmetic. (line 73) * mpcr_set_inf: Ball Arithmetic. (line 70) * mpcr_set_one: Ball Arithmetic. (line 72) * mpcr_set_ui64_2si64: Ball Arithmetic. (line 74) * mpcr_set_zero: Ball Arithmetic. (line 71) * mpcr_sqr: Ball Arithmetic. (line 101) * mpcr_sqrt: Ball Arithmetic. (line 102) * mpcr_sub: Ball Arithmetic. (line 94) * mpcr_sub_rnd: Ball Arithmetic. (line 108) * mpcr_zero_p: Ball Arithmetic. (line 56) * mpc_abs: Basic Arithmetic. (line 99) * mpc_acos: Trigonometric Functions. (line 25) * mpc_acosh: Trigonometric Functions. (line 31) * mpc_add: Basic Arithmetic. (line 19) * mpc_add_fr: Basic Arithmetic. (line 23) * mpc_add_ui: Basic Arithmetic. (line 21) * mpc_agm: Power Functions and Logarithm. (line 50) * mpc_arg: Projection & Decomposing. (line 20) * mpc_asin: Trigonometric Functions. (line 24) * mpc_asinh: Trigonometric Functions. (line 30) * mpc_atan: Trigonometric Functions. (line 26) * mpc_atanh: Trigonometric Functions. (line 32) * mpc_clear: Initializing Complex Numbers. (line 21) * mpc_cmp: Complex Comparison. (line 6) * mpc_cmp_abs: Complex Comparison. (line 23) * mpc_cmp_si: Complex Comparison. (line 9) * mpc_cmp_si_si: Complex Comparison. (line 7) * mpc_conj: Basic Arithmetic. (line 94) * mpc_cos: Trigonometric Functions. (line 7) * mpc_cosh: Trigonometric Functions. (line 19) * mpc_div: Basic Arithmetic. (line 82) * mpc_div_2si: Basic Arithmetic. (line 117) * mpc_div_2ui: Basic Arithmetic. (line 115) * mpc_div_fr: Basic Arithmetic. (line 86) * mpc_div_ui: Basic Arithmetic. (line 84) * mpc_dot: Basic Arithmetic. (line 77) * mpc_eta_fund: Modular Functions. (line 11) * mpc_exp: Power Functions and Logarithm. (line 32) * mpc_fma: Basic Arithmetic. (line 72) * mpc_free_str: String and Stream Input and Output. (line 66) * mpc_fr_div: Basic Arithmetic. (line 90) * mpc_fr_sub: Basic Arithmetic. (line 31) * mpc_get_ldc: Converting Complex Numbers. (line 10) * mpc_get_prec: Initializing Complex Numbers. (line 49) * mpc_get_prec2: Initializing Complex Numbers. (line 53) * mpc_get_str: String and Stream Input and Output. (line 48) * mpc_get_version: Miscellaneous Complex Functions. (line 14) * mpc_imag: Projection & Decomposing. (line 10) * mpc_imagref: Projection & Decomposing. (line 15) * mpc_init2: Initializing Complex Numbers. (line 10) * mpc_init3: Initializing Complex Numbers. (line 15) * mpc_inp_str: String and Stream Input and Output. (line 74) * mpc_log: Power Functions and Logarithm. (line 36) * mpc_log10: Power Functions and Logarithm. (line 37) * mpc_mul: Basic Arithmetic. (line 51) * mpc_mul_2si: Basic Arithmetic. (line 109) * mpc_mul_2ui: Basic Arithmetic. (line 107) * mpc_mul_fr: Basic Arithmetic. (line 57) * mpc_mul_i: Basic Arithmetic. (line 63) * mpc_mul_si: Basic Arithmetic. (line 55) * mpc_mul_ui: Basic Arithmetic. (line 53) * mpc_neg: Basic Arithmetic. (line 42) * mpc_norm: Basic Arithmetic. (line 103) * mpc_out_str: String and Stream Input and Output. (line 109) * mpc_pow: Power Functions and Logarithm. (line 11) * mpc_pow_d: Power Functions and Logarithm. (line 13) * mpc_pow_fr: Power Functions and Logarithm. (line 23) * mpc_pow_ld: Power Functions and Logarithm. (line 15) * mpc_pow_si: Power Functions and Logarithm. (line 17) * mpc_pow_ui: Power Functions and Logarithm. (line 19) * mpc_pow_z: Power Functions and Logarithm. (line 21) * mpc_proj: Projection & Decomposing. (line 24) * mpc_real: Projection & Decomposing. (line 6) * mpc_realref: Projection & Decomposing. (line 14) * mpc_rootofunity: Power Functions and Logarithm. (line 44) * mpc_set: Assigning Complex Numbers. (line 16) * mpc_set_d: Assigning Complex Numbers. (line 25) * mpc_set_dc: Assigning Complex Numbers. (line 27) * mpc_set_d_d: Assigning Complex Numbers. (line 54) * mpc_set_f: Assigning Complex Numbers. (line 33) * mpc_set_fr: Assigning Complex Numbers. (line 34) * mpc_set_fr_fr: Assigning Complex Numbers. (line 64) * mpc_set_f_f: Assigning Complex Numbers. (line 62) * mpc_set_ld: Assigning Complex Numbers. (line 26) * mpc_set_ldc: Assigning Complex Numbers. (line 29) * mpc_set_ld_ld: Assigning Complex Numbers. (line 56) * mpc_set_nan: Assigning Complex Numbers. (line 79) * mpc_set_prec: Initializing Complex Numbers. (line 41) * mpc_set_q: Assigning Complex Numbers. (line 32) * mpc_set_q_q: Assigning Complex Numbers. (line 60) * mpc_set_si: Assigning Complex Numbers. (line 22) * mpc_set_si_si: Assigning Complex Numbers. (line 48) * mpc_set_sj: Assigning Complex Numbers. (line 24) * mpc_set_sj_sj: Assigning Complex Numbers. (line 52) * mpc_set_str: String and Stream Input and Output. (line 35) * mpc_set_ui: Assigning Complex Numbers. (line 20) * mpc_set_ui_ui: Assigning Complex Numbers. (line 46) * mpc_set_uj: Assigning Complex Numbers. (line 23) * mpc_set_uj_uj: Assigning Complex Numbers. (line 50) * MPC_SET_X_Y: Advanced Functions. (line 6) * mpc_set_z: Assigning Complex Numbers. (line 31) * mpc_set_z_z: Assigning Complex Numbers. (line 58) * mpc_sin: Trigonometric Functions. (line 6) * mpc_sinh: Trigonometric Functions. (line 18) * mpc_sin_cos: Trigonometric Functions. (line 12) * mpc_sqr: Basic Arithmetic. (line 69) * mpc_sqrt: Power Functions and Logarithm. (line 6) * mpc_strtoc: String and Stream Input and Output. (line 6) * mpc_sub: Basic Arithmetic. (line 27) * mpc_sub_fr: Basic Arithmetic. (line 29) * mpc_sub_ui: Basic Arithmetic. (line 33) * mpc_sum: Basic Arithmetic. (line 46) * mpc_swap: Assigning Complex Numbers. (line 82) * mpc_tan: Trigonometric Functions. (line 8) * mpc_tanh: Trigonometric Functions. (line 20) * mpc_ui_div: Basic Arithmetic. (line 88) * mpc_ui_sub: Basic Arithmetic. (line 35) * mpc_ui_ui_sub: Basic Arithmetic. (line 37) * mpc_urandom: Miscellaneous Complex Functions. (line 6) * MPC_VERSION: Miscellaneous Complex Functions. (line 17) * MPC_VERSION_MAJOR: Miscellaneous Complex Functions. (line 18) * MPC_VERSION_MINOR: Miscellaneous Complex Functions. (line 19) * MPC_VERSION_NUM: Miscellaneous Complex Functions. (line 36) * MPC_VERSION_PATCHLEVEL: Miscellaneous Complex Functions. (line 20) * MPC_VERSION_STRING: Miscellaneous Complex Functions. (line 21)  File: mpc.info, Node: Type Index, Next: GNU Free Documentation License, Prev: Function Index, Up: Top Type Index ********** [index] * Menu: * mpcb_ptr: Ball Arithmetic. (line 140) * mpcb_srcptr: Ball Arithmetic. (line 140) * mpcb_t: Ball Arithmetic. (line 11) * mpcb_t <1>: Ball Arithmetic. (line 140) * mpcr_ptr: Ball Arithmetic. (line 28) * mpcr_srcptr: Ball Arithmetic. (line 28) * mpcr_t: Ball Arithmetic. (line 28) * mpc_ptr: GNU MPC Basics. (line 15) * mpc_rnd_t: GNU MPC Basics. (line 24) * mpc_srcptr: GNU MPC Basics. (line 15) * mpc_t: GNU MPC Basics. (line 15) * mpfr_prec_t: GNU MPC Basics. (line 19)  File: mpc.info, Node: GNU Free Documentation License, Prev: Type Index, Up: Top Appendix A GNU Free Documentation License ***************************************** Version 1.3, 3 November 2008 Copyright © 2000, 2001, 2002, 2007, 2008 Free Software Foundation, Inc. Everyone is permitted to copy and distribute verbatim copies of this license document, but changing it is not allowed. 0. PREAMBLE The purpose of this License is to make a manual, textbook, or other functional and useful document “free” in the sense of freedom: to assure everyone the effective freedom to copy and redistribute it, with or without modifying it, either commercially or noncommercially. Secondarily, this License preserves for the author and publisher a way to get credit for their work, while not being considered responsible for modifications made by others. This License is a kind of “copyleft”, which means that derivative works of the document must themselves be free in the same sense. It complements the GNU General Public License, which is a copyleft license designed for free software. We have designed this License in order to use it for manuals for free software, because free software needs free documentation: a free program should come with manuals providing the same freedoms that the software does. 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The operator of an MMC Site may republish an MMC contained in the site under CC-BY-SA on the same site at any time before August 1, 2009, provided the MMC is eligible for relicensing. ADDENDUM: How to use this License for your documents ==================================================== To use this License in a document you have written, include a copy of the License in the document and put the following copyright and license notices just after the title page: Copyright (C) YEAR YOUR NAME. Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.3 or any later version published by the Free Software Foundation; with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A copy of the license is included in the section entitled ``GNU Free Documentation License''. If you have Invariant Sections, Front-Cover Texts and Back-Cover Texts, replace the “with...Texts.” line with this: with the Invariant Sections being LIST THEIR TITLES, with the Front-Cover Texts being LIST, and with the Back-Cover Texts being LIST. If you have Invariant Sections without Cover Texts, or some other combination of the three, merge those two alternatives to suit the situation. If your document contains nontrivial examples of program code, we recommend releasing these examples in parallel under your choice of free software license, such as the GNU General Public License, to permit their use in free software.  Tag Table: Node: Top769 Node: Copying1550 Node: Introduction to GNU MPC2322 Node: Installing GNU MPC3041 Node: Reporting Bugs8342 Node: GNU MPC Basics9689 Ref: return-value13571 Node: Complex Functions15058 Node: Initializing Complex Numbers16257 Node: Assigning Complex Numbers18684 Node: Converting Complex Numbers23230 Node: String and Stream Input and Output23869 Node: Complex Comparison30607 Node: Projection & Decomposing32170 Node: Basic Arithmetic33579 Node: Power Functions and Logarithm39308 Node: Trigonometric Functions42244 Node: Modular Functions44199 Node: Miscellaneous Complex Functions45034 Node: Advanced Functions47240 Node: Internals48338 Node: Ball Arithmetic48797 Node: References66134 Node: Concept Index66931 Node: Function Index69391 Node: Type Index86438 Node: GNU Free Documentation License87468  End Tag Table  Local Variables: coding: utf-8 End: