std::imag(std::complex)
From cppreference.com
Defined in header <complex>
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| (1) | ||
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template
<
class T >
T imag( const std::complex <T> & z ) ; |
(until C++14) | |
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template
<
class T >
constexpr T imag( const std::complex <T> & z ) ; |
(since C++14) | |
Additional overloads (since C++11) |
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Defined in header <complex>
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| (A) | ||
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float imag(
float f )
;
double imag( double f ); |
(until C++14) | |
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constexpr
float imag(
float f )
;
constexpr double imag( double f ); |
(since C++14) (until C++23) |
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template
<
class FloatingPoint >
FloatingPoint imag( FloatingPoint f ) ; |
(since C++23) | |
| (B) | ||
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template
<
class Integer >
double imag( Integer i ) ; |
(until C++14) | |
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template
<
class Integer >
constexpr double imag( Integer i ) ; |
(since C++14) | |
1) Returns the imaginary part of the complex number z, i.e. z.imag()
A,B) Additional overloads are provided for all integer and floating-point types, which are treated as complex numbers with zero imaginary part.
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(since C++11) |
Parameters
| z | - | complex value |
| f | - | floating-point value |
| i | - | integer value |
Return value
1) The imaginary part of z.
A) decltype(f){} (zero).
B) 0.0.
Notes
The additional overloads are not required to be provided exactly as (A,B). They only need to be sufficient to ensure that for their argument num:
- If num has a standard(until C++23) floating-point type
T, then std::imag(num) has the same effect as std:: imag ( std::complex <T> (num) ) - Otherwise, if num has an integer type, then std::imag(num) has the same effect as std:: imag ( std::complex < double > (num) )
See also
| accesses the imaginary part of the complex number (public member function) |
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| returns the real part (function template) |
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C documentation for cimag
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