Package | Description |
---|---|
org.nd4j.linalg.api.buffer | |
org.nd4j.linalg.api.complex |
Modifier and Type | Method and Description |
---|---|
IComplexNumber |
BaseDataBuffer.getComplex(long i) |
IComplexNumber |
DataBuffer.getComplex(long i)
Returns a complex number
|
Modifier and Type | Method and Description |
---|---|
void |
BaseDataBuffer.put(long i,
IComplexNumber result) |
void |
DataBuffer.put(long i,
IComplexNumber result)
Insert a complex number at the given index
|
Modifier and Type | Interface and Description |
---|---|
interface |
IComplexDouble
Complex Double
|
interface |
IComplexFloat
Complex float
|
Modifier and Type | Class and Description |
---|---|
class |
BaseComplexDouble
Base class for complex doubles
|
class |
BaseComplexFloat
Base complex float class
|
Modifier and Type | Method and Description |
---|---|
IComplexNumber |
IComplexNumber.add(IComplexNumber c)
Add two complex numbers.
|
IComplexNumber |
BaseComplexFloat.add(IComplexNumber c)
Add two complex numbers.
|
IComplexNumber |
BaseComplexDouble.add(IComplexNumber c)
Add two complex numbers.
|
IComplexNumber |
IComplexNumber.add(Number c)
Add a realComponent number to a complex number.
|
IComplexNumber |
BaseComplexFloat.add(Number c)
Add a realComponent number to a complex number.
|
IComplexNumber |
BaseComplexDouble.add(Number c)
Add a realComponent number to a complex number.
|
IComplexNumber |
IComplexNumber.addi(IComplexNumber c)
Add two complex numbers in-place storing the result in this.
|
IComplexNumber |
BaseComplexFloat.addi(IComplexNumber c)
Add two complex numbers in-place storing the result in this.
|
IComplexNumber |
BaseComplexDouble.addi(IComplexNumber c)
Add two complex numbers in-place storing the result in this.
|
IComplexNumber |
IComplexNumber.addi(IComplexNumber c,
IComplexNumber result)
Add two complex numbers in-place
|
IComplexNumber |
BaseComplexFloat.addi(IComplexNumber c,
IComplexNumber result)
Add two complex numbers in-place
|
IComplexNumber |
BaseComplexDouble.addi(IComplexNumber c,
IComplexNumber result)
Add two complex numbers in-place
|
IComplexNumber |
IComplexNumber.addi(Number c)
Add a realComponent number to complex number in-place, storing the result in this.
|
IComplexNumber |
BaseComplexFloat.addi(Number c)
Add a realComponent number to complex number in-place, storing the result in this.
|
IComplexNumber |
BaseComplexDouble.addi(Number c)
Add a realComponent number to complex number in-place, storing the result in this.
|
IComplexNumber |
IComplexNumber.addi(Number a,
IComplexNumber result)
Add a realComponent number to a complex number in-place.
|
IComplexNumber |
BaseComplexFloat.addi(Number a,
IComplexNumber result)
Add a realComponent number to a complex number in-place.
|
IComplexNumber |
BaseComplexDouble.addi(Number a,
IComplexNumber result)
Add a realComponent number to a complex number in-place.
|
IComplexNumber |
IComplexNumber.conj()
The conjugate of this
number
|
IComplexNumber |
BaseComplexFloat.conj() |
IComplexNumber |
BaseComplexDouble.conj() |
IComplexNumber |
IComplexNumber.conji()
The inplace conjugate of this
number
|
IComplexNumber |
IComplexNumber.copy(IComplexNumber other) |
IComplexNumber |
BaseComplexFloat.copy(IComplexNumber other) |
IComplexNumber |
BaseComplexDouble.copy(IComplexNumber other) |
IComplexNumber |
IComplexDouble.div(double v) |
IComplexNumber |
BaseComplexDouble.div(double v) |
IComplexNumber |
IComplexFloat.div(float v) |
IComplexNumber |
BaseComplexFloat.div(float v) |
IComplexNumber |
IComplexNumber.div(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
BaseComplexFloat.div(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
BaseComplexDouble.div(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
IComplexNumber.div(Number v) |
IComplexNumber |
BaseComplexFloat.div(Number v) |
IComplexNumber |
BaseComplexDouble.div(Number v) |
IComplexNumber |
IComplexNumber.divi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.divi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.divi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.divi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
BaseComplexFloat.divi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
BaseComplexDouble.divi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
IComplexNumber.divi(Number v) |
IComplexNumber |
BaseComplexFloat.divi(Number v) |
IComplexNumber |
BaseComplexDouble.divi(Number v) |
IComplexNumber |
IComplexNumber.divi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.divi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.divi(Number v,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.dup()
Clone
|
IComplexNumber |
BaseComplexDouble.dup() |
IComplexNumber |
IComplexNumber.eqc(IComplexNumber num)
Equals returning a complex number
|
IComplexNumber |
BaseComplexFloat.eqc(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.eqc(IComplexNumber num) |
IComplexNumber |
IComplexNumber.exp()
The exponent of this complex number
|
IComplexNumber |
BaseComplexFloat.exp() |
IComplexNumber |
BaseComplexDouble.exp() |
IComplexNumber |
IComplexNumber.gt(IComplexNumber num)
Greater than returning a complex number
|
IComplexNumber |
BaseComplexFloat.gt(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.gt(IComplexNumber num) |
IComplexNumber |
IComplexNumber.inv() |
IComplexNumber |
BaseComplexFloat.inv() |
IComplexNumber |
BaseComplexDouble.inv() |
IComplexNumber |
IComplexNumber.invi() |
IComplexNumber |
IComplexNumber.log()
The logarithm of this complex number
|
IComplexNumber |
BaseComplexFloat.log() |
IComplexNumber |
BaseComplexDouble.log() |
IComplexNumber |
IComplexNumber.lt(IComplexNumber num)
Less than returning a complex number
|
IComplexNumber |
BaseComplexFloat.lt(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.lt(IComplexNumber num) |
IComplexNumber |
IComplexNumber.mul(IComplexNumber c)
Multiply two complex numbers
|
IComplexNumber |
BaseComplexFloat.mul(IComplexNumber c)
Multiply two complex numbers
|
IComplexNumber |
BaseComplexDouble.mul(IComplexNumber c)
Multiply two complex numbers
|
IComplexNumber |
IComplexNumber.mul(Number v) |
IComplexNumber |
BaseComplexFloat.mul(Number v) |
IComplexNumber |
BaseComplexDouble.mul(Number v) |
IComplexNumber |
IComplexNumber.muli(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.muli(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.muli(IComplexNumber c) |
IComplexNumber |
IComplexNumber.muli(IComplexNumber c,
IComplexNumber result)
Multiply two complex numbers, inplace
|
IComplexNumber |
BaseComplexFloat.muli(IComplexNumber c,
IComplexNumber result)
Multiply two complex numbers, inplace
|
IComplexNumber |
BaseComplexDouble.muli(IComplexNumber c,
IComplexNumber result)
Multiply two complex numbers, inplace
|
IComplexNumber |
IComplexNumber.muli(Number v) |
IComplexNumber |
BaseComplexFloat.muli(Number v) |
IComplexNumber |
BaseComplexDouble.muli(Number v) |
IComplexNumber |
IComplexNumber.muli(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.muli(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.muli(Number v,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.neg()
The negation of this complex number
|
IComplexNumber |
BaseComplexFloat.neg() |
IComplexNumber |
BaseComplexDouble.neg() |
IComplexNumber |
IComplexNumber.negi()
The inplace negation of this number
|
IComplexNumber |
IComplexNumber.neqc(IComplexNumber num)
Not Equals returning a complex number
|
IComplexNumber |
BaseComplexFloat.neqc(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.neqc(IComplexNumber num) |
IComplexNumber |
IComplexNumber.pow(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.pow(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.pow(IComplexNumber c) |
IComplexNumber |
IComplexNumber.pow(Number v) |
IComplexNumber |
BaseComplexFloat.pow(Number v) |
IComplexNumber |
BaseComplexDouble.pow(Number v) |
IComplexNumber |
IComplexNumber.powi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.powi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.powi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.powi(IComplexNumber c,
IComplexNumber result)
Power two complex numbers
|
IComplexNumber |
BaseComplexFloat.powi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.powi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.powi(Number v) |
IComplexNumber |
BaseComplexFloat.powi(Number v) |
IComplexNumber |
BaseComplexDouble.powi(Number v) |
IComplexNumber |
IComplexNumber.powi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.powi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.powi(Number v,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rdiv(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
BaseComplexFloat.rdiv(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rdiv(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rdiv(Number v) |
IComplexNumber |
BaseComplexFloat.rdiv(Number v) |
IComplexNumber |
BaseComplexDouble.rdiv(Number v) |
IComplexNumber |
IComplexNumber.rdivi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.rdivi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rdivi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rdivi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
BaseComplexFloat.rdivi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rdivi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rdivi(Number v) |
IComplexNumber |
BaseComplexFloat.rdivi(Number v) |
IComplexNumber |
BaseComplexDouble.rdivi(Number v) |
IComplexNumber |
IComplexNumber.rdivi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.rdivi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rdivi(Number v,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rsub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
BaseComplexFloat.rsub(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rsub(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rsub(Number r) |
IComplexNumber |
BaseComplexFloat.rsub(Number r) |
IComplexNumber |
BaseComplexDouble.rsub(Number r) |
IComplexNumber |
IComplexNumber.rsubi(IComplexNumber c)
Reverse subtract a number
|
IComplexNumber |
BaseComplexFloat.rsubi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rsubi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rsubi(IComplexNumber a,
IComplexNumber result)
Reverse subtraction
|
IComplexNumber |
BaseComplexFloat.rsubi(IComplexNumber a,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rsubi(IComplexNumber a,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rsubi(Number a) |
IComplexNumber |
BaseComplexFloat.rsubi(Number a) |
IComplexNumber |
BaseComplexDouble.rsubi(Number a) |
IComplexNumber |
IComplexNumber.rsubi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.rsubi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rsubi(Number a,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.set(IComplexNumber set)
Set a complex number's components to be this ones
|
IComplexNumber |
BaseComplexFloat.set(IComplexNumber set) |
IComplexNumber |
BaseComplexDouble.set(IComplexNumber set) |
IComplexNumber |
IComplexNumber.set(Number real,
Number imag)
Set the real and imaginary components
|
IComplexNumber |
BaseComplexFloat.set(Number real,
Number imag) |
IComplexNumber |
BaseComplexDouble.set(Number real,
Number imag) |
IComplexNumber |
IComplexNumber.sqrt()
The sqrt of this
number
|
IComplexNumber |
IComplexNumber.sub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
BaseComplexFloat.sub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
BaseComplexDouble.sub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
IComplexNumber.sub(Number r) |
IComplexNumber |
BaseComplexFloat.sub(Number r) |
IComplexNumber |
BaseComplexDouble.sub(Number r) |
IComplexNumber |
IComplexNumber.subi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.subi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.subi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.subi(IComplexNumber c,
IComplexNumber result)
Subtract two complex numbers, in-place
|
IComplexNumber |
BaseComplexFloat.subi(IComplexNumber c,
IComplexNumber result)
Subtract two complex numbers, in-place
|
IComplexNumber |
BaseComplexDouble.subi(IComplexNumber c,
IComplexNumber result)
Subtract two complex numbers, in-place
|
IComplexNumber |
IComplexNumber.subi(Number a) |
IComplexNumber |
BaseComplexFloat.subi(Number a) |
IComplexNumber |
BaseComplexDouble.subi(Number a) |
IComplexNumber |
IComplexNumber.subi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.subi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.subi(Number a,
IComplexNumber result) |
Modifier and Type | Method and Description |
---|---|
IComplexNumber |
IComplexNumber.add(IComplexNumber c)
Add two complex numbers.
|
IComplexNumber |
BaseComplexFloat.add(IComplexNumber c)
Add two complex numbers.
|
IComplexNumber |
BaseComplexDouble.add(IComplexNumber c)
Add two complex numbers.
|
IComplexNumber |
IComplexNumber.addi(IComplexNumber c)
Add two complex numbers in-place storing the result in this.
|
IComplexNumber |
BaseComplexFloat.addi(IComplexNumber c)
Add two complex numbers in-place storing the result in this.
|
IComplexNumber |
BaseComplexDouble.addi(IComplexNumber c)
Add two complex numbers in-place storing the result in this.
|
IComplexNumber |
IComplexNumber.addi(IComplexNumber c,
IComplexNumber result)
Add two complex numbers in-place
|
IComplexNumber |
BaseComplexFloat.addi(IComplexNumber c,
IComplexNumber result)
Add two complex numbers in-place
|
IComplexNumber |
BaseComplexDouble.addi(IComplexNumber c,
IComplexNumber result)
Add two complex numbers in-place
|
IComplexNumber |
IComplexNumber.addi(Number a,
IComplexNumber result)
Add a realComponent number to a complex number in-place.
|
IComplexNumber |
BaseComplexFloat.addi(Number a,
IComplexNumber result)
Add a realComponent number to a complex number in-place.
|
IComplexNumber |
BaseComplexDouble.addi(Number a,
IComplexNumber result)
Add a realComponent number to a complex number in-place.
|
IComplexNumber |
IComplexNumber.copy(IComplexNumber other) |
IComplexNumber |
BaseComplexFloat.copy(IComplexNumber other) |
IComplexNumber |
BaseComplexDouble.copy(IComplexNumber other) |
IComplexNumber |
IComplexNumber.div(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
BaseComplexFloat.div(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
BaseComplexDouble.div(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
IComplexNumber.divi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.divi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.divi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.divi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
BaseComplexFloat.divi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
BaseComplexDouble.divi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
IComplexNumber.divi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.divi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.divi(Number v,
IComplexNumber result) |
boolean |
IComplexNumber.eq(IComplexNumber c) |
boolean |
BaseComplexFloat.eq(IComplexNumber c) |
boolean |
BaseComplexDouble.eq(IComplexNumber c) |
IComplexNumber |
IComplexNumber.eqc(IComplexNumber num)
Equals returning a complex number
|
IComplexNumber |
BaseComplexFloat.eqc(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.eqc(IComplexNumber num) |
IComplexNumber |
IComplexNumber.gt(IComplexNumber num)
Greater than returning a complex number
|
IComplexNumber |
BaseComplexFloat.gt(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.gt(IComplexNumber num) |
IComplexNumber |
IComplexNumber.lt(IComplexNumber num)
Less than returning a complex number
|
IComplexNumber |
BaseComplexFloat.lt(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.lt(IComplexNumber num) |
IComplexNumber |
IComplexNumber.mul(IComplexNumber c)
Multiply two complex numbers
|
IComplexNumber |
BaseComplexFloat.mul(IComplexNumber c)
Multiply two complex numbers
|
IComplexNumber |
BaseComplexDouble.mul(IComplexNumber c)
Multiply two complex numbers
|
IComplexNumber |
IComplexNumber.muli(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.muli(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.muli(IComplexNumber c) |
IComplexNumber |
IComplexNumber.muli(IComplexNumber c,
IComplexNumber result)
Multiply two complex numbers, inplace
|
IComplexNumber |
BaseComplexFloat.muli(IComplexNumber c,
IComplexNumber result)
Multiply two complex numbers, inplace
|
IComplexNumber |
BaseComplexDouble.muli(IComplexNumber c,
IComplexNumber result)
Multiply two complex numbers, inplace
|
IComplexNumber |
IComplexNumber.muli(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.muli(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.muli(Number v,
IComplexNumber result) |
boolean |
IComplexNumber.ne(IComplexNumber c) |
boolean |
BaseComplexFloat.ne(IComplexNumber c) |
boolean |
BaseComplexDouble.ne(IComplexNumber c) |
IComplexNumber |
IComplexNumber.neqc(IComplexNumber num)
Not Equals returning a complex number
|
IComplexNumber |
BaseComplexFloat.neqc(IComplexNumber num) |
IComplexNumber |
BaseComplexDouble.neqc(IComplexNumber num) |
IComplexNumber |
IComplexNumber.pow(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.pow(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.pow(IComplexNumber c) |
IComplexNumber |
IComplexNumber.powi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.powi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.powi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.powi(IComplexNumber c,
IComplexNumber result)
Power two complex numbers
|
IComplexNumber |
BaseComplexFloat.powi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.powi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.powi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.powi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.powi(Number v,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rdiv(IComplexNumber c)
Divide two complex numbers
|
IComplexNumber |
BaseComplexFloat.rdiv(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rdiv(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rdivi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.rdivi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rdivi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rdivi(IComplexNumber c,
IComplexNumber result)
Divide two complex numbers, in-place
|
IComplexNumber |
BaseComplexFloat.rdivi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rdivi(IComplexNumber c,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rdivi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.rdivi(Number v,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rdivi(Number v,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rsub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
BaseComplexFloat.rsub(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rsub(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rsubi(IComplexNumber c)
Reverse subtract a number
|
IComplexNumber |
BaseComplexFloat.rsubi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.rsubi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.rsubi(IComplexNumber a,
IComplexNumber result)
Reverse subtraction
|
IComplexNumber |
BaseComplexFloat.rsubi(IComplexNumber a,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rsubi(IComplexNumber a,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.rsubi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.rsubi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.rsubi(Number a,
IComplexNumber result) |
IComplexNumber |
IComplexNumber.set(IComplexNumber set)
Set a complex number's components to be this ones
|
IComplexNumber |
BaseComplexFloat.set(IComplexNumber set) |
IComplexNumber |
BaseComplexDouble.set(IComplexNumber set) |
IComplexNumber |
IComplexNumber.sub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
BaseComplexFloat.sub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
BaseComplexDouble.sub(IComplexNumber c)
Subtract two complex numbers
|
IComplexNumber |
IComplexNumber.subi(IComplexNumber c) |
IComplexNumber |
BaseComplexFloat.subi(IComplexNumber c) |
IComplexNumber |
BaseComplexDouble.subi(IComplexNumber c) |
IComplexNumber |
IComplexNumber.subi(IComplexNumber c,
IComplexNumber result)
Subtract two complex numbers, in-place
|
IComplexNumber |
BaseComplexFloat.subi(IComplexNumber c,
IComplexNumber result)
Subtract two complex numbers, in-place
|
IComplexNumber |
BaseComplexDouble.subi(IComplexNumber c,
IComplexNumber result)
Subtract two complex numbers, in-place
|
IComplexNumber |
IComplexNumber.subi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexFloat.subi(Number a,
IComplexNumber result) |
IComplexNumber |
BaseComplexDouble.subi(Number a,
IComplexNumber result) |
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