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std.complex
This module contains the Complex type, which is used to represent
complex numbers, along with related mathematical operations and functions.
Complex will eventually
replace
the built-in types cfloat, cdouble, creal, ifloat,
idouble, and ireal.
Authors:
Lars Tandle Kyllingstad, Don Clugston
License:
Source std/complex.d
- pure nothrow @nogc @safe auto
complex
(R)(const Rre
)
if (is(R : double));
pure nothrow @nogc @safe autocomplex
(R, I)(const Rre
, const Iim
)
if (is(R : double) && is(I : double)); - Helper function that returns a complex number with the specified real and imaginary parts.Parameters:
R (template parameter) type of real part of complex number I (template parameter) type of imaginary part of complex number R re
real part of complex number to be constructed I im
(optional) imaginary part of complex number, 0 if omitted. Returns:Complex instance with real and imaginary parts set to the values provided as input. If neitherre
norim
are floating-point numbers, the return type will be Complex!double. Otherwise, the return type is deduced using std.traits.CommonType!(R, I).Examples:auto a = complex(1.0); static assert(is(typeof(a) == Complex!double)); writeln(a.re); // 1.0 writeln(a.im); // 0.0 auto b = complex(2.0L); static assert(is(typeof(b) == Complex!real)); writeln(b.re); // 2.0L writeln(b.im); // 0.0L auto c = complex(1.0, 2.0); static assert(is(typeof(c) == Complex!double)); writeln(c.re); // 1.0 writeln(c.im); // 2.0 auto d = complex(3.0, 4.0L); static assert(is(typeof(d) == Complex!real)); writeln(d.re); // 3.0 writeln(d.im); // 4.0L auto e = complex(1); static assert(is(typeof(e) == Complex!double)); writeln(e.re); // 1 writeln(e.im); // 0 auto f = complex(1L, 2); static assert(is(typeof(f) == Complex!double)); writeln(f.re); // 1L writeln(f.im); // 2 auto g = complex(3, 4.0L); static assert(is(typeof(g) == Complex!real)); writeln(g.re); // 3 writeln(g.im); // 4.0L
- struct
Complex
(T) if (isFloatingPoint!T); - A complex number parametrised by a type T, which must be either float, double or real.
- T
re
; - The real part of the number.
- T
im
; - The imaginary part of the number.
- const @safe string
toString
();
const voidtoString
(Writer, Char)(scope Writerw
, ref scope const FormatSpec!CharformatSpec
)
if (isOutputRange!(Writer, const(Char)[])); - Converts the complex number to a string representation.The second form of this function is usually not called directly; instead, it is used via std.string.format, as shown in the examples below. Supported format characters are 'e', 'f', 'g', 'a', and 's'. See the std.format and std.string.format documentation for more information.Examples:
auto c = complex(1.2, 3.4); // Vanilla toString formatting: writeln(c.toString()); // "1.2+3.4i" // Formatting with std.string.format specs: the precision and width // specifiers apply to both the real and imaginary parts of the // complex number. import std.format : format; writeln(format("%.2f", c)); // "1.20+3.40i" writeln(format("%4.1f", c)); // " 1.2+ 3.4i"
- this(R : T)(Complex!R
z
);
this(Rx : T, Ry : T)(const Rxx
, const Ryy
);
this(R : T)(const Rr
); - Construct a complex number with the specified real and imaginary parts. In the case where a single argument is passed that is not complex, the imaginary part of the result will be zero.
- pure nothrow @nogc @safe T
abs
(T)(Complex!Tz
); - Parameters:
Complex!T z
A complex number. Returns:The absolute value (or modulus) ofz
.Examples:static import std.math; writeln(abs(complex(1.0))); // 1.0 writeln(abs(complex(0.0, 1.0))); // 1.0 writeln(abs(complex(1.0L, -2.0L))); // std.math.sqrt(5.0L)
- pure nothrow @nogc @safe T
sqAbs
(T)(Complex!Tz
);
pure nothrow @nogc @safe TsqAbs
(T)(const Tx
)
if (isFloatingPoint!T); - Parameters:
Complex!T z
A complex number. T x
A real number. Returns:The squared modulus ofz
. For genericity, if called on a real number, returns its square.Examples:import std.math; writeln(sqAbs(complex(0.0))); // 0.0 writeln(sqAbs(complex(1.0))); // 1.0 writeln(sqAbs(complex(0.0, 1.0))); // 1.0 assert(approxEqual(sqAbs(complex(1.0L, -2.0L)), 5.0L)); assert(approxEqual(sqAbs(complex(-3.0L, 1.0L)), 10.0L)); assert(approxEqual(sqAbs(complex(1.0f,-1.0f)), 2.0f));
- pure nothrow @nogc @safe T
arg
(T)(Complex!Tz
); - Parameters:
Complex!T z
A complex number. Returns:The argument (or phase) ofz
.Examples:import std.math; writeln(arg(complex(1.0))); // 0.0 writeln(arg(complex(0.0L, 1.0L))); // PI_2 writeln(arg(complex(1.0L, 1.0L))); // PI_4
- pure nothrow @nogc @safe T
norm
(T)(Complex!Tz
); - Extracts the norm of a complex number.Parameters:
Complex!T z
A complex number Returns:The squared magnitude ofz
.Examples:import std.math : isClose, PI; writeln(norm(complex(3.0, 4.0))); // 25.0 writeln(norm(fromPolar(5.0, 0.0))); // 25.0 assert(isClose(norm(fromPolar(5.0L, PI / 6)), 25.0L)); assert(isClose(norm(fromPolar(5.0L, 13 * PI / 6)), 25.0L));
- pure nothrow @nogc @safe Complex!T
conj
(T)(Complex!Tz
); - Parameters:
Complex!T z
A complex number. Returns:The complex conjugate ofz
.Examples:writeln(conj(complex(1.0))); // complex(1.0) writeln(conj(complex(1.0, 2.0))); // complex(1.0, -2.0)
- Complex!T
proj
(T)(Complex!Tz
); - Returns the projection of
z
onto the Riemann sphere.Parameters:Complex!T z
A complex number Returns:The projection ofz
onto the Riemann sphere.Examples:writeln(proj(complex(1.0))); // complex(1.0) writeln(proj(complex(double.infinity, 5.0))); // complex(double.infinity, 0.0) writeln(proj(complex(5.0, -double.infinity))); // complex(double.infinity, -0.0)
- pure nothrow @nogc @safe Complex!(CommonType!(T, U))
fromPolar
(T, U)(const Tmodulus
, const Uargument
); - Constructs a complex number given its absolute value and argument.Parameters:
T modulus
The modulus U argument
The argument Returns:The complex number with the given modulus and argument.Examples:import std.math; auto z = fromPolar(std.math.sqrt(2.0), PI_4); assert(approxEqual(z.re, 1.0L, real.epsilon)); assert(approxEqual(z.im, 1.0L, real.epsilon));
- pure nothrow @nogc @safe Complex!T
sin
(T)(Complex!Tz
);
pure nothrow @nogc @safe Complex!Tcos
(T)(Complex!Tz
);
pure nothrow @nogc @safe Complex!Ttan
(T)(Complex!Tz
); - Trigonometric functions on complex numbers.Parameters:
Complex!T z
A complex number. Returns:The sine, cosine and tangent ofz
, respectively.Examples:static import std.math; writeln(sin(complex(0.0))); // 0.0 writeln(sin(complex(2.0L, 0))); // std.math.sin(2.0L)
Examples:static import std.math; writeln(cos(complex(0.0))); // 1.0 writeln(cos(complex(1.3L, 0.0))); // std.math.cos(1.3L) writeln(cos(complex(0.0L, 5.2L))); // std.math.cosh(5.2L)
Examples:static import std.math; assert(ceqrel(tan(complex(1.0, 0.0)), complex(std.math.tan(1.0), 0.0)) >= double.mant_dig - 2); assert(ceqrel(tan(complex(0.0, 1.0)), complex(0.0, std.math.tanh(1.0))) >= double.mant_dig - 2);
- pure nothrow @nogc @trusted Complex!real
expi
(realy
); - Parameters:
real y
A real number. Returns:The value of cos(y) + i sin(y).Note
expi
is included here for convenience and for easy migration of code.Examples:import std.math : cos, sin; writeln(expi(0.0L)); // 1.0L writeln(expi(1.3e5L)); // complex(cos(1.3e5L), sin(1.3e5L))
- pure nothrow @nogc @safe Complex!real
coshisinh
(realy
); - Parameters:
real y
A real number. Returns:The value of cosh(y) + i sinh(y)Note
coshisinh
is included here for convenience and for easy migration of code.Examples:import std.math : cosh, sinh; writeln(coshisinh(3.0L)); // complex(cosh(3.0L), sinh(3.0L))
- pure nothrow @nogc @safe Complex!T
sqrt
(T)(Complex!Tz
); - Parameters:
Complex!T z
A complex number. Returns:The square root ofz
.Examples:static import std.math; writeln(sqrt(complex(0.0))); // 0.0 writeln(sqrt(complex(1.0L, 0))); // std.math.sqrt(1.0L) writeln(sqrt(complex(-1.0L, 0))); // complex(0, 1.0L) writeln(sqrt(complex(-8.0, -6.0))); // complex(1.0, -3.0)
- pure nothrow @nogc @trusted Complex!T
exp
(T)(Complex!Tx
); - Calculates ex.Parameters:
Complex!T x
A complex number Returns:The complex base e exponential ofx
Special Values x exp(x) (±0, +0) (1, +0) (any, +∞) (NAN, NAN) (any, NAN) (NAN, NAN) (+∞, +0) (+∞, +0) (-∞, any) (±0, cis(x.im)) (+∞, any) (±∞, cis(x.im)) (-∞, +∞) (±0, ±0) (+∞, +∞) (±∞, NAN) (-∞, NAN) (±0, ±0) (+∞, NAN) (±∞, NAN) (NAN, +0) (NAN, +0) (NAN, any) (NAN, NAN) (NAN, NAN) (NAN, NAN) Examples:import std.math : isClose, PI; writeln(exp(complex(0.0, 0.0))); // complex(1.0, 0.0) auto a = complex(2.0, 1.0); writeln(exp(conj(a))); // conj(exp(a)) auto b = exp(complex(0.0L, 1.0L) * PI); assert(isClose(b, -1.0L, 0.0, 1e-15));
- pure nothrow @nogc @safe Complex!T
log
(T)(Complex!Tx
); - Calculate the natural logarithm of x. The branch cut is along the negative axis.Parameters:
Complex!T x
A complex number Returns:The complex natural logarithm ofx
Special Values x log(x) (-0, +0) (-∞, π) (+0, +0) (-∞, +0) (any, +∞) (+∞, π/2) (any, NAN) (NAN, NAN) (-∞, any) (+∞, π) (+∞, any) (+∞, +0) (-∞, +∞) (+∞, 3π/4) (+∞, +∞) (+∞, π/4) (±∞, NAN) (+∞, NAN) (NAN, any) (NAN, NAN) (NAN, +∞) (+∞, NAN) (NAN, NAN) (NAN, NAN) Examples:import std.math : sqrt, PI, isClose; auto a = complex(2.0, 1.0); writeln(log(conj(a))); // conj(log(a)) auto b = 2.0 * log10(complex(0.0, 1.0)); auto c = 4.0 * log10(complex(sqrt(2.0) / 2, sqrt(2.0) / 2)); assert(isClose(b, c, 0.0, 1e-15)); writeln(log(complex(-1.0L, 0.0L))); // complex(0.0L, PI) writeln(log(complex(-1.0L, -0.0L))); // complex(0.0L, -PI)
- pure nothrow @nogc @safe Complex!T
log10
(T)(Complex!Tx
); - Calculate the base-10 logarithm of x.Parameters:
Complex!T x
A complex number Returns:The complex base 10 logarithm ofx
Examples:import std.math : LN10, PI, isClose, sqrt; auto a = complex(2.0, 1.0); writeln(log10(a)); // log(a) / log(complex(10.0)) auto b = log10(complex(0.0, 1.0)) * 2.0; auto c = log10(complex(sqrt(2.0) / 2, sqrt(2.0) / 2)) * 4.0; assert(isClose(b, c, 0.0, 1e-15)); assert(ceqrel(log10(complex(-100.0L, 0.0L)), complex(2.0L, PI / LN10)) >= real.mant_dig - 1); assert(ceqrel(log10(complex(-100.0L, -0.0L)), complex(2.0L, -PI / LN10)) >= real.mant_dig - 1);
- pure nothrow @nogc @safe Complex!T
pow
(T, Int)(Complex!Tx
, const Intn
)
if (isIntegral!Int);
pure nothrow @nogc @trusted Complex!Tpow
(T)(Complex!Tx
, const Tn
);
pure nothrow @nogc @trusted Complex!Tpow
(T)(Complex!Tx
, Complex!Ty
);
pure nothrow @nogc @trusted Complex!Tpow
(T)(const Tx
, Complex!Tn
); - Calculates xn. The branch cut is on the negative axis.Parameters:
Complex!T x
base Int n
exponent Returns:x
raised to the power ofn
Examples:import std.math : isClose; auto a = complex(1.0, 2.0); writeln(pow(a, 2)); // a * a writeln(pow(a, 3)); // a * a * a writeln(pow(a, -2)); // 1.0 / (a * a) assert(isClose(pow(a, -3), 1.0 / (a * a * a))); auto b = complex(2.0); assert(isClose(pow(b, 3), exp(3 * log(b))));
Examples:import std.math : isClose; writeln(pow(complex(0.0), 2.0)); // complex(0.0) writeln(pow(complex(5.0), 2.0)); // complex(25.0) auto a = pow(complex(-1.0, 0.0), 0.5); assert(isClose(a, complex(0.0, +1.0), 0.0, 1e-16)); auto b = pow(complex(-1.0, -0.0), 0.5); assert(isClose(b, complex(0.0, -1.0), 0.0, 1e-16));
Examples:import std.math : isClose, exp, PI; auto a = complex(0.0); auto b = complex(2.0); writeln(pow(a, b)); // complex(0.0) auto c = pow(complex(0.0, 1.0), complex(0.0, 1.0)); assert(isClose(c, exp((-PI) / 2)));
Examples:import std.math : isClose; writeln(pow(2.0, complex(0.0))); // complex(1.0) writeln(pow(2.0, complex(5.0))); // complex(32.0) auto a = pow(-2.0, complex(-1.0)); assert(isClose(a, complex(-0.5), 0.0, 1e-16)); auto b = pow(-0.5, complex(-1.0)); assert(isClose(b, complex(-2.0), 0.0, 1e-15));
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