If the macro constant | (since C11) |
The C programming language, as of C99, supports complex number math with the three built-in types double _Complex
, float _Complex
, and long double _Complex
(see _Complex). When the header <complex.h>
is included, the three complex number types are also accessible as double complex
, float complex
, long double complex
.
In addition to the complex types, the three imaginary types may be supported: double _Imaginary
, float _Imaginary
, and long double _Imaginary
(see _Imaginary). When the header <complex.h>
is included, the three imaginary types are also accessible as double imaginary
, float imaginary
, and long double imaginary
.
Standard arithmetic operators +, -, *, /
can be used with real, complex, and imaginary types in any combination.
A compiler that defines |
(since C99) (until C11) |
Imaginary numbers are supported if | (since C11) |
Defined in header <complex.h> |
|
---|---|
Types |
|
(C99) | imaginary type macro (keyword macro) |
(C99) | complex type macro (keyword macro) |
The imaginary constant |
|
(C99) | the imaginary unit constant i (macro constant) |
(C99) | the complex unit constant i (macro constant) |
(C99) | the complex or imaginary unit constant i (macro constant) |
Manipulation |
|
(C11)(C11)(C11) | constructs a complex number from real and imaginary parts (function macro) |
(C99)(C99)(C99) | computes the real part of a complex number (function) |
(C99)(C99)(C99) | computes the imaginary part a complex number (function) |
(C99)(C99)(C99) | computes the magnitude of a complex number (function) |
(C99)(C99)(C99) | computes the phase angle of a complex number (function) |
(C99)(C99)(C99) | computes the complex conjugate (function) |
(C99)(C99)(C99) | computes the projection on Riemann sphere (function) |
Exponential functions |
|
(C99)(C99)(C99) | computes the complex base-e exponential (function) |
(C99)(C99)(C99) | computes the complex natural logarithm (function) |
Power functions |
|
(C99)(C99)(C99) | computes the complex power function (function) |
(C99)(C99)(C99) | computes the complex square root (function) |
Trigonometric functions |
|
(C99)(C99)(C99) | computes the complex sine (function) |
(C99)(C99)(C99) | computes the complex cosine (function) |
(C99)(C99)(C99) | computes the complex tangent (function) |
(C99)(C99)(C99) | computes the complex arc sine (function) |
(C99)(C99)(C99) | computes the complex arc cosine (function) |
(C99)(C99)(C99) | computes the complex arc tangent (function) |
Hyperbolic functions |
|
(C99)(C99)(C99) | computes the complex hyperbolic sine (function) |
(C99)(C99)(C99) | computes the complex hyperbolic cosine (function) |
(C99)(C99)(C99) | computes the complex hyperbolic tangent (function) |
(C99)(C99)(C99) | computes the complex arc hyperbolic sine (function) |
(C99)(C99)(C99) | computes the complex arc hyperbolic cosine (function) |
(C99)(C99)(C99) | computes the complex arc hyperbolic tangent (function) |
The following function names are reserved for future addition to complex.h
and are not available for use in the programs that include that header: cerf
, cerfc
, cexp2
, cexpm1
, clog10
, clog1p
, clog2
, clgamma
, and ctgamma
, along with their -f and -l suffixed variants.
Although the C standard names the inverse hyperbolics with "complex arc hyperbolic sine" etc., the inverse functions of the hyperbolic functions are the area functions. Their argument is the area of a hyperbolic sector, not an arc. The correct names are "complex inverse hyperbolic sine" etc. Some authors use "complex area hyperbolic sine" etc.
A complex or imaginary number is infinite if one of its components is infinite, even if the other component is NaN.
A complex or imaginary number is finite if both components are neither infinities nor NaNs.
A complex or imaginary number is a zero if both components are positive or negative zeroes.
#include <stdio.h> #include <complex.h> #include <tgmath.h> int main(void) { double complex z1 = I * I; // imaginary unit squared printf("I * I = %.1f%+.1fi\n", creal(z1), cimag(z1)); double complex z2 = pow(I, 2); // imaginary unit squared printf("pow(I, 2) = %.1f%+.1fi\n", creal(z2), cimag(z2)); double PI = acos(-1); double complex z3 = exp(I * PI); // Euler's formula printf("exp(I*PI) = %.1f%+.1fi\n", creal(z3), cimag(z3)); double complex z4 = 1+2*I, z5 = 1-2*I; // conjugates printf("(1+2i)*(1-2i) = %.1f%+.1fi\n", creal(z4*z5), cimag(z4*z5)); }
Output:
I * I = -1.0+0.0i pow(I, 2) = -1.0+0.0i exp(I*PI) = -1.0+0.0i (1+2i)*(1-2i) = 5.0+0.0i
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