namespace Eigen { /** \eigenManualPage CoeffwiseMathFunctions Catalog of coefficient-wise math functions This table presents a catalog of the coefficient-wise math functions supported by %Eigen. In this table, \c a, \c b, refer to Array objects or expressions, and \c m refers to a linear algebra Matrix/Vector object. Standard scalar types are abbreviated as follows: - \c int: \c i32 - \c float: \c f - \c double: \c d - \c std::complex: \c cf - \c std::complex: \c cd For each row, the first column list the equivalent calls for arrays, and matrices when supported. Of course, all functions are available for matrices by first casting it as an array: \c m.array(). The third column gives some hints in the underlying scalar implementation. In most cases, %Eigen does not implement itself the math function but relies on the STL for standard scalar types, or user-provided functions for custom scalar types. For instance, some simply calls the respective function of the STL while preserving argument-dependent lookup for custom types. The following: \code using std::foo; foo(a[i]); \endcode means that the STL's function \c std::foo will be potentially called if it is compatible with the underlying scalar type. If not, then the user must ensure that an overload of the function foo is available for the given scalar type (usually defined in the same namespace as the given scalar type). This also means that, unless specified, if the function \c std::foo is available only in some recent c++ versions (e.g., c++11), then the respective %Eigen's function/method will be usable on standard types only if the compiler support the required c++ version.

API	Description	Default scalar implementation	SIMD

Basic operations
\anchor cwisetable_abs a.\link ArrayBase::abs abs\endlink(); \n \link Eigen::abs abs\endlink(a); \n m.\link MatrixBase::cwiseAbs cwiseAbs\endlink();	absolute value (\f$ \|a_i\| \f$)	using std::abs; \n abs(a[i]);	SSE2, AVX (i32,f,d)
\anchor cwisetable_inverse a.\link ArrayBase::inverse inverse\endlink(); \n \link Eigen::inverse inverse\endlink(a); \n m.\link MatrixBase::cwiseInverse cwiseInverse\endlink();	inverse value (\f$ 1/a_i \f$)	1/a[i];	All engines (f,d,fc,fd)
\anchor cwisetable_conj a.\link ArrayBase::conjugate conjugate\endlink(); \n \link Eigen::conj conj\endlink(a); \n m.\link MatrixBase::conjugate conjugate\endlink();	complex conjugate (\f$ \bar{a_i} \f$),\n no-op for real	using std::conj; \n conj(a[i]);	All engines (fc,fd)
\anchor cwisetable_arg a.\link ArrayBase::arg arg\endlink(); \n \link Eigen::arg arg\endlink(a); \n m.\link MatrixBase::cwiseArg cwiseArg\endlink();	phase angle of complex number	using std::arg; \n arg(a[i]);	All engines (fc,fd)
Exponential functions
\anchor cwisetable_exp a.\link ArrayBase::exp exp\endlink(); \n \link Eigen::exp exp\endlink(a);	\f$ e \f$ raised to the given power (\f$ e^{a_i} \f$)	using std::exp; \n exp(a[i]);	SSE2, AVX (f,d)
\anchor cwisetable_log a.\link ArrayBase::log log\endlink(); \n \link Eigen::log log\endlink(a);	natural (base \f$ e \f$) logarithm (\f$ \ln({a_i}) \f$)	using std::log; \n log(a[i]);	SSE2, AVX (f)
\anchor cwisetable_log1p a.\link ArrayBase::log1p log1p\endlink(); \n \link Eigen::log1p log1p\endlink(a);	natural (base \f$ e \f$) logarithm of 1 plus \n the given number (\f$ \ln({1+a_i}) \f$)	built-in generic implementation based on \c log,\n plus \c using \c std::log1p ; \cpp11
\anchor cwisetable_log10 a.\link ArrayBase::log10 log10\endlink(); \n \link Eigen::log10 log10\endlink(a);	base 10 logarithm (\f$ \log_{10}({a_i}) \f$)	using std::log10; \n log10(a[i]);
Power functions
\anchor cwisetable_pow a.\link ArrayBase::pow pow\endlink(b); \n \link ArrayBase::pow(const Eigen::ArrayBase< Derived > &x, const Eigen::ArrayBase< ExponentDerived > &exponents) pow\endlink(a,b);	raises a number to the given power (\f$ a_i ^ {b_i} \f$) \n \c a and \c b can be either an array or scalar.	using std::pow; \n pow(a[i],b[i]);\n (plus builtin for integer types)
\anchor cwisetable_sqrt a.\link ArrayBase::sqrt sqrt\endlink(); \n \link Eigen::sqrt sqrt\endlink(a);\n m.\link MatrixBase::cwiseSqrt cwiseSqrt\endlink();	computes square root (\f$ \sqrt a_i \f$)	using std::sqrt; \n sqrt(a[i]);	SSE2, AVX (f,d)
\anchor cwisetable_rsqrt a.\link ArrayBase::rsqrt rsqrt\endlink(); \n \link Eigen::rsqrt rsqrt\endlink(a);	reciprocal square root (\f$ 1/{\sqrt a_i} \f$)	using std::sqrt; \n 1/sqrt(a[i]); \n	SSE2, AVX, AltiVec, ZVector (f,d)\n (approx + 1 Newton iteration)
\anchor cwisetable_square a.\link ArrayBase::square square\endlink(); \n \link Eigen::square square\endlink(a);	computes square power (\f$ a_i^2 \f$)	a[i]*a[i]	All (i32,f,d,cf,cd)
\anchor cwisetable_cube a.\link ArrayBase::cube cube\endlink(); \n \link Eigen::cube cube\endlink(a);	computes cubic power (\f$ a_i^3 \f$)	a[i]a[i]a[i]	All (i32,f,d,cf,cd)
\anchor cwisetable_abs2 a.\link ArrayBase::abs2 abs2\endlink(); \n \link Eigen::abs2 abs2\endlink(a);\n m.\link MatrixBase::cwiseAbs2 cwiseAbs2\endlink();	computes the squared absolute value (\f$ \|a_i\|^2 \f$)	real: a[i]a[i] \n complex: real(a[i])real(a[i]) \n + imag(a[i])*imag(a[i])	All (i32,f,d)
Trigonometric functions
\anchor cwisetable_sin a.\link ArrayBase::sin sin\endlink(); \n \link Eigen::sin sin\endlink(a);	computes sine	using std::sin; \n sin(a[i]);	SSE2, AVX (f)
\anchor cwisetable_cos a.\link ArrayBase::cos cos\endlink(); \n \link Eigen::cos cos\endlink(a);	computes cosine	using std::cos; \n cos(a[i]);	SSE2, AVX (f)
\anchor cwisetable_tan a.\link ArrayBase::tan tan\endlink(); \n \link Eigen::tan tan\endlink(a);	computes tangent	using std::tan; \n tan(a[i]);
\anchor cwisetable_asin a.\link ArrayBase::asin asin\endlink(); \n \link Eigen::asin asin\endlink(a);	computes arc sine (\f$ \sin^{-1} a_i \f$)	using std::asin; \n asin(a[i]);
\anchor cwisetable_acos a.\link ArrayBase::acos acos\endlink(); \n \link Eigen::acos acos\endlink(a);	computes arc cosine (\f$ \cos^{-1} a_i \f$)	using std::acos; \n acos(a[i]);
\anchor cwisetable_atan a.\link ArrayBase::atan atan\endlink(); \n \link Eigen::atan atan\endlink(a);	computes arc tangent (\f$ \tan^{-1} a_i \f$)	using std::atan; \n atan(a[i]);
Hyperbolic functions
\anchor cwisetable_sinh a.\link ArrayBase::sinh sinh\endlink(); \n \link Eigen::sinh sinh\endlink(a);	computes hyperbolic sine	using std::sinh; \n sinh(a[i]);
\anchor cwisetable_cosh a.\link ArrayBase::cosh cohs\endlink(); \n \link Eigen::cosh cosh\endlink(a);	computes hyperbolic cosine	using std::cosh; \n cosh(a[i]);
\anchor cwisetable_tanh a.\link ArrayBase::tanh tanh\endlink(); \n \link Eigen::tanh tanh\endlink(a);	computes hyperbolic tangent	using std::tanh; \n tanh(a[i]);
\anchor cwisetable_asinh a.\link ArrayBase::asinh asinh\endlink(); \n \link Eigen::asinh asinh\endlink(a);	computes inverse hyperbolic sine	using std::asinh; \n asinh(a[i]);
\anchor cwisetable_acosh a.\link ArrayBase::acosh cohs\endlink(); \n \link Eigen::acosh acosh\endlink(a);	computes hyperbolic cosine	using std::acosh; \n acosh(a[i]);
\anchor cwisetable_atanh a.\link ArrayBase::atanh atanh\endlink(); \n \link Eigen::atanh atanh\endlink(a);	computes hyperbolic tangent	using std::atanh; \n atanh(a[i]);
Nearest integer floating point operations
\anchor cwisetable_ceil a.\link ArrayBase::ceil ceil\endlink(); \n \link Eigen::ceil ceil\endlink(a);	nearest integer not less than the given value	using std::ceil; \n ceil(a[i]);	SSE4,AVX,ZVector (f,d)
\anchor cwisetable_floor a.\link ArrayBase::floor floor\endlink(); \n \link Eigen::floor floor\endlink(a);	nearest integer not greater than the given value	using std::floor; \n floor(a[i]);	SSE4,AVX,ZVector (f,d)
\anchor cwisetable_round a.\link ArrayBase::round round\endlink(); \n \link Eigen::round round\endlink(a);	nearest integer, \n rounding away from zero in halfway cases	built-in generic implementation \n based on \c floor and \c ceil,\n plus \c using \c std::round ; \cpp11	SSE4,AVX,ZVector (f,d)
\anchor cwisetable_rint a.\link ArrayBase::rint rint\endlink(); \n \link Eigen::rint rint\endlink(a);	nearest integer, \n rounding to nearest even in halfway cases	built-in generic implementation using \c std::rint ; \cpp11 or \c rintf ;	SSE4,AVX (f,d)
Floating point manipulation functions
Classification and comparison
\anchor cwisetable_isfinite a.\link ArrayBase::isFinite isFinite\endlink(); \n \link Eigen::isfinite isfinite\endlink(a);	checks if the given number has finite value	built-in generic implementation,\n plus \c using \c std::isfinite ; \cpp11
\anchor cwisetable_isinf a.\link ArrayBase::isInf isInf\endlink(); \n \link Eigen::isinf isinf\endlink(a);	checks if the given number is infinite	built-in generic implementation,\n plus \c using \c std::isinf ; \cpp11
\anchor cwisetable_isnan a.\link ArrayBase::isNaN isNaN\endlink(); \n \link Eigen::isnan isnan\endlink(a);	checks if the given number is not a number	built-in generic implementation,\n plus \c using \c std::isnan ; \cpp11
Error and gamma functions
Require \c \#include \c
\anchor cwisetable_erf a.\link ArrayBase::erf erf\endlink(); \n \link Eigen::erf erf\endlink(a);	error function	using std::erf; \cpp11 \n erf(a[i]);
\anchor cwisetable_erfc a.\link ArrayBase::erfc erfc\endlink(); \n \link Eigen::erfc erfc\endlink(a);	complementary error function	using std::erfc; \cpp11 \n erfc(a[i]);
\anchor cwisetable_lgamma a.\link ArrayBase::lgamma lgamma\endlink(); \n \link Eigen::lgamma lgamma\endlink(a);	natural logarithm of the gamma function	using std::lgamma; \cpp11 \n lgamma(a[i]);
\anchor cwisetable_digamma a.\link ArrayBase::digamma digamma\endlink(); \n \link Eigen::digamma digamma\endlink(a);	logarithmic derivative of the gamma function	built-in for float and double
\anchor cwisetable_igamma \link Eigen::igamma igamma\endlink(a,x);	lower incomplete gamma integral \n \f$ \gamma(a_i,x_i)= \frac{1}{\|a_i\|} \int_{0}^{x_i}e^{\text{-}t} t^{a_i-1} \mathrm{d} t \f$	built-in for float and double,\n but requires \cpp11
\anchor cwisetable_igammac \link Eigen::igammac igammac\endlink(a,x);	upper incomplete gamma integral \n \f$ \Gamma(a_i,x_i) = \frac{1}{\|a_i\|} \int_{x_i}^{\infty}e^{\text{-}t} t^{a_i-1} \mathrm{d} t \f$	built-in for float and double,\n but requires \cpp11
Special functions
Require \c \#include \c
\anchor cwisetable_polygamma \link Eigen::polygamma polygamma\endlink(n,x);	n-th derivative of digamma at x	built-in generic based on\n \c lgamma , \c digamma and \c zeta .
\anchor cwisetable_betainc \link Eigen::betainc betainc\endlink(a,b,x);	Incomplete beta function	built-in for float and double,\n but requires \cpp11
\anchor cwisetable_zeta \link Eigen::zeta zeta\endlink(a,b); \n a.\link ArrayBase::zeta zeta\endlink(b);	Hurwitz zeta function \n \f$ \zeta(a_i,b_i)=\sum_{k=0}^{\infty}(b_i+k)^{\text{-}a_i} \f$	built-in for float and double
\anchor cwisetable_ndtri a.\link ArrayBase::ndtri ndtri\endlink(); \n \link Eigen::ndtri ndtri\endlink(a);	Inverse of the CDF of the Normal distribution function	built-in for float and double

\n */ }