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How can I work with complex numbers in C? I see there is a complex.h header file, but it doesn't give me much information about how to use it. How to access real and imaginary parts in an efficient way? Is there native functions to get module and phase?

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@Johann is there reason why you are asking why he wants C instead of C++? – MK. Jun 20 '11 at 23:48
@Johann Because C is easier to bind to my Python code. – Charles Brunet Jun 20 '11 at 23:58
@MK: Of course, because more often than not when this question comes up, they're also allowed to use C++ and I find complex math easier there than in C. – Johann Gerell Jun 21 '11 at 7:52
up vote 114 down vote accepted

This code will help you, and it's fairly self-explanatory:

#include <stdio.h>      /* Standard Library of Input and Output */
#include <complex.h>    /* Standard Library of Complex Numbers */

int main() {

    double complex z1 = 1.0 + 3.0 * I;
    double complex z2 = 1.0 - 4.0 * I;

    printf("Working with complex numbers:\n\v");

    printf("Starting values: Z1 = %.2f + %.2fi\tZ2 = %.2f %+.2fi\n", creal(z1), cimag(z1), creal(z2), cimag(z2));

    double complex sum = z1 + z2;
    printf("The sum: Z1 + Z2 = %.2f %+.2fi\n", creal(sum), cimag(sum));

    double complex difference = z1 - z2;
    printf("The difference: Z1 - Z2 = %.2f %+.2fi\n", creal(difference), cimag(difference));

    double complex product = z1 * z2;
    printf("The product: Z1 x Z2 = %.2f %+.2fi\n", creal(product), cimag(product));

    double complex quotient = z1 / z2;
    printf("The quotient: Z1 / Z2 = %.2f %+.2fi\n", creal(quotient), cimag(quotient));

    double complex conjugate = conj(z1);
    printf("The conjugate of Z1 = %.2f %+.2fi\n", creal(conjugate), cimag(conjugate));

    return 0;


creal(z1): get the real part (for flot crealf(z1), for long double creall(z1))

cimag(z1): get the imaginary part (for float cimagf(z1), for long double cimagl(z1))

Another important point to remember when working with complex numbers is that functions like cos(), exp() and sqrt() must be replaced with their complex forms, e.g. ccos(), cexp(), csqrt().

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This answer should get more upvotes. (and even be accepted, imo) – brimborium Dec 14 '12 at 11:07
What is this double complex? Is this a language extension or some macro magic? – Calmarius Dec 16 '14 at 18:55
@Calmarius complex is a standard c99 type (under the hood on GCC, it is actually an alias to the _Complex type). – Snaipe Apr 12 '15 at 8:50
@Snaipe: complex is not a type. It's a macro that expands to _Complex, which is a type specifier, but not a type by itself. The complex types are float _Complex, double _Complex, and long double _Complex. – Keith Thompson May 25 '15 at 8:22

Complex types are in the C language since C99 standard (-std=c99 option of GCC). Some compilers may implement complex types even in more earlier modes, but this is non-standard and non-portable extension (e.g. IBM XL, GCC, may be intel,... ).

You can start from - it gives a description of functions from complex.h

This manual also gives some info about macros.

To declare a complex variable, use

  double _Complex  a;        // use c* functions without suffix


  float _Complex   b;        // use c*f functions - with f suffix
  long double _Complex c;    // use c*l functions - with l suffix

To give a value into complex, use _Complex_I macro from complex.h:

  float _Complex d = 2.0f + 2.0f*_Complex_I;

(actually there can be some problems here with (0,-0i) numbers and NaNs in single half of complex)

Module is cabs(a)/cabsl(c)/cabsf(b); Real part is creal(a), Imaginary is cimag(a). carg(a) is for complex argument.

To directly access (read/write) real an imag part you may use this unportable GCC-extension:

 __real__ a = 1.4;
 __imag__ a = 2.0;
 float b = __real__ a;
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almost every complex function will be implemented by compiler as builtin function in efficient way. Just use modern compiler and give it some non-zero level of optimization. – osgx Jun 21 '11 at 0:07
FYI, since the OP mentions Python bindings, when working with Python I try to stick to C89 (since the rest of Python's code is C89, and if you want your extension to run on Windows, it's usually compiled with MVSC, which is limited to C89). I don't know that it's strictly necessary though. – detly Jul 9 '13 at 7:59
The expression (complex float) { r, i } can also be used to set the separate parts of the number and independently (allowing the real part to be INF while the imaginary part is NAN, for instance). That avoids the GCC-specific keyword, though I'm not sure if it actually is portable. – cleong Apr 25 '14 at 19:36
Note that Complex support is optional in C99: compilers may simply not have it if they define __STDC_NO_COMPLEX__. In practice however, it is implemented on major compilers. – Ciro Santilli 巴拿馬文件 六四事件 法轮功 Sep 17 '14 at 12:04
Jasen, check page 182 of N1256 draft "7.3 Complex arithmetic <complex.h>". Such keyword was probably selected in C99 to not break existing c (C90) programs which implements complex by hand. If <complex.h> is included, complex will be defined as macro, expanded to _Complex. You may be also interested in Derek M. Jones's "The New C Standard: An Economic and Cultural Commentary" (2008) page 500 "complex types"… – osgx Jan 25 '15 at 8:44


#include <stdio.h>      /* Standard Library of Input and Output */
#include <complex.h>    /* Standart Library of Complex Numbers */

int main() 
    double complex z1 = 1.0 + 3.0 * I;
    double complex z2 = 1.0 - 4.0 * I;

    printf("Working with complex numbers:\n\v");

    printf("Starting values: Z1 = %.2f + %.2fi\tZ2 = %.2f %+.2fi\n", 

    double complex sum = z1 + z2;
    printf("The sum: Z1 + Z2 = %.2f %+.2fi\n", creal(sum), cimag(sum));
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The notion of complex numbers was introduced in mathematics, from the need of calculating negative quadratic roots. Complex number concept was taken by a variety of engineering fields.

Today that complex numbers are widely used in advanced engineering domains such as physics, electronics, mechanics, astronomy, etc...

Real and imaginary part, of a negative square root example:

#include <stdio.h>   
#include <complex.h>

int main() 
    int negNum;

    printf("Calculate negative square roots:\n"
           "Enter negative number:");

    scanf("%d", &negNum);

    double complex negSqrt = csqrt(negNum);

    double pReal = creal(negSqrt);
    double pImag = cimag(negSqrt);

    printf("\nReal part %f, imaginary part %f"
           ", for negative square root.(%d)",
           pReal, pImag, negNum);

    return 0;
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For convenience, one may include tgmath.h library for the type generate macros. It creates the same function name as the double version for all type of variable. For example, For example, it defines a sqrt() macro that expands to the sqrtf() , sqrt() , or sqrtl() function, depending on the type of argument provided.

So one don't need to remember the corresponding function name for different type of variables!

#include <stdio.h>
#include <tgmath.h>//for the type generate marcros. 
#include <complex.h>//for easier declare complex variables and complex unit I

int main(void)
    double complex z1=1./4.*M_PI+1./4.*M_PI*I;//M_PI is just pi=3.1415...
    double complex z2, z3, z4, z5; 


    printf("exp(z1)=%lf + %lf I\n", creal(z2),cimag(z2));
    printf("sin(z1)=%lf + %lf I\n", creal(z3),cimag(z3));
    printf("sqrt(z1)=%lf + %lf I\n", creal(z4),cimag(z4));
    printf("log(z1)=%lf + %lf I\n", creal(z5),cimag(z5));

    return 0;
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To extract the real part of a complex-valued expression z, use the notation as __real__ z. Similarly, use __imag__ attribute on the z to extract the imaginary part.

For example;

__complex__ float z;
float r;
float i;
r = __real__ z;
i = __imag__ z;

r is the real part of the complex number "z" i is the imaginary part of the complex number "z"

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These are gcc-specific extensions. Another answer already mentioned them, and the accepted answer already how to do this in standard C. – Keith Thompson May 25 '15 at 8:25

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