cprojf, cproj, cprojl
From cppreference.com
Defined in header
<complex.h>
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float cprojf( float complex z );
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(1) | (since C99) |
double cproj( double complex z );
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(2) | (since C99) |
long double cprojl( long double complex z );
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(3) | (since C99) |
Defined in header
<tgmath.h>
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#define cproj( z )
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(4) | (since C99) |
1-3) Computes the projection of
z
on the Riemann sphere.
4) Type-generic macro: if
z
has type long double complex, long double imaginary, or long double, cprojl
is called. If z
has type float complex, float imaginary, or float, cprojf
is called. If z
has type double complex, double imaginary, double, or any integer type, cproj
is called.For most z
, std::proj(z)==z, but all complex infinities, even the numbers where one component is infinite and the other is NaN, become positive real infinity, INFINITY+0.0*I or INFINITY-0.0*I. The sign of the imaginary (zero) component is the sign of cimag(z).
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[edit] Parameters
z | - | complex argument |
[edit] Return value
The projection of z
on the Riemann sphere.
This function is fully specified for all possible inputs and is not subject to any errors described in math_errhandling
[edit] Notes
The cproj
function helps model the Riemann sphere by mapping all infinities to one (give or take the sign of the imaginary zero), and should be used just before any operation, especially comparisons, that might give spurious results for any of the other infinities.
[edit] Example
Run this code
#include <stdio.h> #include <complex.h> #include <math.h> int main(void) { double complex z1 = cproj(1 + 2*I); printf("cproj(1+2i) = %.1f%+.1fi\n", creal(z1),cimag(z1)); double complex z2 = cproj(INFINITY+2.0*I); printf("cproj(Inf+2i) = %.1f%+.1fi\n", creal(z2),cimag(z2)); double complex z3 = cproj(INFINITY-2.0*I); printf("cproj(Inf-2i) = %.1f%+.1fi\n", creal(z3),cimag(z3)); }
Output:
cproj(1+2i) = 1.0+2.0i cproj(Inf+2i) = inf+0.0i cproj(Inf-2i) = inf-0.0i
[edit] See also
C++ documentation for proj
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