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api_arith.go
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/
api_arith.go
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package tensor
import (
"github.com/pkg/errors"
)
// exported API for arithmetics and the stupidly crazy amount of overloaded semantics
// Add performs a pointwise a+b. a and b can either be float64 or Tensor
//
// If both operands are Tensor, shape is checked first.
// Even though the underlying data may have the same size (say (2,2) vs (4,1)), if they have different shapes, it will error out.
//
// Add performs elementwise addition on the Tensor(s). These operations are supported:
// Add(*Dense, scalar)
// Add(scalar, *Dense)
// Add(*Dense, *Dense)
// If the Unsafe flag is passed in, the data of the first tensor will be overwritten
func Add(a, b interface{}, opts ...FuncOpt) (retVal Tensor, err error) {
var adder Adder
var oe standardEngine
var ok bool
switch at := a.(type) {
case Tensor:
oe = at.standardEngine()
switch bt := b.(type) {
case Tensor:
if !bt.Shape().IsScalar() && !at.Shape().IsScalar() { // non-scalar Tensor addition
if oe != nil {
return oe.Add(at, bt, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.Add(at, bt, opts...)
}
if adder, ok = at.Engine().(Adder); ok {
return adder.Add(at, bt, opts...)
}
if adder, ok = bt.Engine().(Adder); ok {
return adder.Add(at, bt, opts...)
}
return nil, errors.New("Neither engines of either operand support Add")
} else { // at least one of the operands is a scalar
var leftTensor bool
if !bt.Shape().IsScalar() {
leftTensor = false // a Scalar-Tensor * b Tensor
tmp := at
at = bt
bt = tmp
} else {
leftTensor = true // a Tensor * b Scalar-Tensor
}
if oe != nil {
return oe.AddScalar(at, bt, leftTensor, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.AddScalar(at, bt, leftTensor, opts...)
}
if adder, ok = at.Engine().(Adder); ok {
return adder.AddScalar(at, bt, leftTensor, opts...)
}
if adder, ok = bt.Engine().(Adder); ok {
return adder.AddScalar(at, bt, leftTensor, opts...)
}
return nil, errors.New("Neither engines of either operand support Add")
}
default:
if oe != nil {
return oe.AddScalar(at, bt, true, opts...)
}
if adder, ok = at.Engine().(Adder); ok {
return adder.AddScalar(at, bt, true, opts...)
}
return nil, errors.New("Operand A's engine does not support Add")
}
default:
switch bt := b.(type) {
case Tensor:
if oe = bt.standardEngine(); oe != nil {
return oe.AddScalar(bt, at, false, opts...)
}
if adder, ok = bt.Engine().(Adder); ok {
return adder.AddScalar(bt, at, false, opts...)
}
return nil, errors.New("Operand B's engine does not support Add")
default:
return nil, errors.Errorf("Cannot perform Add of %T and %T", a, b)
}
}
panic("Unreachable")
}
// Sub performs elementwise subtraction on the Tensor(s). These operations are supported:
// Sub(*Dense, scalar)
// Sub(scalar, *Dense)
// Sub(*Dense, *Dense)
// If the Unsafe flag is passed in, the data of the first tensor will be overwritten
func Sub(a, b interface{}, opts ...FuncOpt) (retVal Tensor, err error) {
var suber Suber
var oe standardEngine
var ok bool
switch at := a.(type) {
case Tensor:
oe = at.standardEngine()
switch bt := b.(type) {
case Tensor:
if !bt.Shape().IsScalar() && !at.Shape().IsScalar() { // non-scalar Tensor substraction
if oe != nil {
return oe.Sub(at, bt, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.Sub(at, bt, opts...)
}
if suber, ok = at.Engine().(Suber); ok {
return suber.Sub(at, bt, opts...)
}
if suber, ok = bt.Engine().(Suber); ok {
return suber.Sub(at, bt, opts...)
}
return nil, errors.New("Neither engines of either operand support Sub")
} else { // at least one of the operands is a scalar
var leftTensor bool
if !bt.Shape().IsScalar() {
leftTensor = false // a Scalar-Tensor * b Tensor
tmp := at
at = bt
bt = tmp
} else {
leftTensor = true // a Tensor * b Scalar-Tensor
}
if oe != nil {
return oe.SubScalar(at, bt, leftTensor, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.SubScalar(at, bt, leftTensor, opts...)
}
if suber, ok = at.Engine().(Suber); ok {
return suber.SubScalar(at, bt, leftTensor, opts...)
}
if suber, ok = bt.Engine().(Suber); ok {
return suber.SubScalar(at, bt, leftTensor, opts...)
}
return nil, errors.New("Neither engines of either operand support Sub")
}
default:
if oe != nil {
return oe.SubScalar(at, bt, true, opts...)
}
if suber, ok = at.Engine().(Suber); ok {
return suber.SubScalar(at, bt, true, opts...)
}
return nil, errors.New("Operand A's engine does not support Sub")
}
default:
switch bt := b.(type) {
case Tensor:
if oe = bt.standardEngine(); oe != nil {
return oe.SubScalar(bt, at, false, opts...)
}
if suber, ok = bt.Engine().(Suber); ok {
return suber.SubScalar(bt, at, false, opts...)
}
return nil, errors.New("Operand B's engine does not support Sub")
default:
return nil, errors.Errorf("Cannot perform Sub of %T and %T", a, b)
}
}
panic("Unreachable")
}
// Mul performs elementwise multiplication on the Tensor(s). These operations are supported:
// Mul(*Dense, scalar)
// Mul(scalar, *Dense)
// Mul(*Dense, *Dense)
// If the Unsafe flag is passed in, the data of the first tensor will be overwritten
func Mul(a, b interface{}, opts ...FuncOpt) (retVal Tensor, err error) {
var muler Muler
var oe standardEngine
var ok bool
switch at := a.(type) {
case Tensor:
oe = at.standardEngine()
switch bt := b.(type) {
case Tensor:
if !bt.Shape().IsScalar() && !at.Shape().IsScalar() { // non-scalar Tensor multiplication
if oe != nil {
return oe.Mul(at, bt, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.Mul(at, bt, opts...)
}
if muler, ok = at.Engine().(Muler); ok {
return muler.Mul(at, bt, opts...)
}
if muler, ok = bt.Engine().(Muler); ok {
return muler.Mul(at, bt, opts...)
}
return nil, errors.New("Neither engines of either operand support Mul")
} else { // at least one of the operands is a scalar
var leftTensor bool
if !bt.Shape().IsScalar() {
leftTensor = false // a Scalar-Tensor * b Tensor
tmp := at
at = bt
bt = tmp
} else {
leftTensor = true // a Tensor * b Scalar-Tensor
}
if oe != nil {
return oe.MulScalar(at, bt, leftTensor, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.MulScalar(at, bt, leftTensor, opts...)
}
if muler, ok = at.Engine().(Muler); ok {
return muler.MulScalar(at, bt, leftTensor, opts...)
}
if muler, ok = bt.Engine().(Muler); ok {
return muler.MulScalar(at, bt, leftTensor, opts...)
}
return nil, errors.New("Neither engines of either operand support Mul")
}
default: // a Tensor * b interface
if oe != nil {
return oe.MulScalar(at, bt, true, opts...)
}
if muler, ok = at.Engine().(Muler); ok {
return muler.MulScalar(at, bt, true, opts...)
}
return nil, errors.New("Operand A's engine does not support Mul")
}
default:
switch bt := b.(type) {
case Tensor: // b Tensor * a interface
if oe = bt.standardEngine(); oe != nil {
return oe.MulScalar(bt, at, false, opts...)
}
if muler, ok = bt.Engine().(Muler); ok {
return muler.MulScalar(bt, at, false, opts...)
}
return nil, errors.New("Operand B's engine does not support Mul")
default: // b interface * a interface
return nil, errors.Errorf("Cannot perform Mul of %T and %T", a, b)
}
}
panic("Unreachable")
}
// Div performs elementwise division on the Tensor(s). These operations are supported:
// Div(*Dense, scalar)
// Div(scalar, *Dense)
// Div(*Dense, *Dense)
// If the Unsafe flag is passed in, the data of the first tensor will be overwritten
func Div(a, b interface{}, opts ...FuncOpt) (retVal Tensor, err error) {
var diver Diver
var oe standardEngine
var ok bool
switch at := a.(type) {
case Tensor:
oe = at.standardEngine()
switch bt := b.(type) {
case Tensor:
if !bt.Shape().IsScalar() && !at.Shape().IsScalar() { // non-scalar Tensor division
if oe != nil {
return oe.Div(at, bt, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.Div(at, bt, opts...)
}
if diver, ok = at.Engine().(Diver); ok {
return diver.Div(at, bt, opts...)
}
if diver, ok = bt.Engine().(Diver); ok {
return diver.Div(at, bt, opts...)
}
return nil, errors.New("Neither engines of either operand support Div")
} else { // at least one of the operands is a scalar
var leftTensor bool
if !bt.Shape().IsScalar() {
leftTensor = false // a Scalar-Tensor * b Tensor
tmp := at
at = bt
bt = tmp
} else {
leftTensor = true // a Tensor * b Scalar-Tensor
}
if oe != nil {
return oe.DivScalar(at, bt, leftTensor, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.DivScalar(at, bt, leftTensor, opts...)
}
if diver, ok = at.Engine().(Diver); ok {
return diver.DivScalar(at, bt, leftTensor, opts...)
}
if diver, ok = bt.Engine().(Diver); ok {
return diver.DivScalar(at, bt, leftTensor, opts...)
}
return nil, errors.New("Neither engines of either operand support Div")
}
default:
if oe != nil {
return oe.DivScalar(at, bt, true, opts...)
}
if diver, ok = at.Engine().(Diver); ok {
return diver.DivScalar(at, bt, true, opts...)
}
return nil, errors.New("Operand A's engine does not support Div")
}
default:
switch bt := b.(type) {
case Tensor:
if oe = bt.standardEngine(); oe != nil {
return oe.DivScalar(bt, at, false, opts...)
}
if diver, ok = bt.Engine().(Diver); ok {
return diver.DivScalar(bt, at, false, opts...)
}
return nil, errors.New("Operand B's engine does not support Div")
default:
return nil, errors.Errorf("Cannot perform Div of %T and %T", a, b)
}
}
panic("Unreachable")
}
// Pow performs elementwise exponentiation on the Tensor(s). These operations are supported:
// Pow(*Dense, scalar)
// Pow(scalar, *Dense)
// Pow(*Dense, *Dense)
// If the Unsafe flag is passed in, the data of the first tensor will be overwritten
func Pow(a, b interface{}, opts ...FuncOpt) (retVal Tensor, err error) {
var power Power
var oe standardEngine
var ok bool
switch at := a.(type) {
case Tensor:
oe = at.standardEngine()
switch bt := b.(type) {
case Tensor:
if !bt.Shape().IsScalar() && !at.Shape().IsScalar() { // non-scalar Tensor exponentiation
if oe != nil {
return oe.Pow(at, bt, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.Pow(at, bt, opts...)
}
if power, ok = at.Engine().(Power); ok {
return power.Pow(at, bt, opts...)
}
if power, ok = bt.Engine().(Power); ok {
return power.Pow(at, bt, opts...)
}
return nil, errors.New("Neither engines of either operand support Pow")
} else { // at least one of the operands is a scalar
var leftTensor bool
if !bt.Shape().IsScalar() {
leftTensor = false // a Scalar-Tensor * b Tensor
tmp := at
at = bt
bt = tmp
} else {
leftTensor = true // a Tensor * b Scalar-Tensor
}
if oe != nil {
return oe.PowScalar(at, bt, leftTensor, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.PowScalar(at, bt, leftTensor, opts...)
}
if power, ok = at.Engine().(Power); ok {
return power.PowScalar(at, bt, leftTensor, opts...)
}
if power, ok = bt.Engine().(Power); ok {
return power.PowScalar(at, bt, leftTensor, opts...)
}
return nil, errors.New("Neither engines of either operand support Pow")
}
default:
if oe != nil {
return oe.PowScalar(at, bt, true, opts...)
}
if power, ok = at.Engine().(Power); ok {
return power.PowScalar(at, bt, true, opts...)
}
return nil, errors.New("Operand A's engine does not support Pow")
}
default:
switch bt := b.(type) {
case Tensor:
if oe = bt.standardEngine(); oe != nil {
return oe.PowScalar(bt, at, false, opts...)
}
if power, ok = bt.Engine().(Power); ok {
return power.PowScalar(bt, at, false, opts...)
}
return nil, errors.New("Operand B's engine does not support Pow")
default:
return nil, errors.Errorf("Cannot perform Pow of %T and %T", a, b)
}
}
panic("Unreachable")
}
// Mod performs elementwise modulo on the Tensor(s). These operations are supported:
// Mod(*Dense, scalar)
// Mod(scalar, *Dense)
// Mod(*Dense, *Dense)
// If the Unsafe flag is passed in, the data of the first tensor will be overwritten
func Mod(a, b interface{}, opts ...FuncOpt) (retVal Tensor, err error) {
var moder Moder
var oe standardEngine
var ok bool
switch at := a.(type) {
case Tensor:
oe = at.standardEngine()
switch bt := b.(type) {
case Tensor:
if !bt.Shape().IsScalar() && !at.Shape().IsScalar() { // non-scalar Tensor modulo
if oe != nil {
return oe.Mod(at, bt, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.Mod(at, bt, opts...)
}
if moder, ok = at.Engine().(Moder); ok {
return moder.Mod(at, bt, opts...)
}
if moder, ok = bt.Engine().(Moder); ok {
return moder.Mod(at, bt, opts...)
}
return nil, errors.New("Neither engines of either operand support Mod")
} else { // at least one of the operands is a scalar
var leftTensor bool
if !bt.Shape().IsScalar() {
leftTensor = false // a Scalar-Tensor * b Tensor
tmp := at
at = bt
bt = tmp
} else {
leftTensor = true // a Tensor * b Scalar-Tensor
}
if oe != nil {
return oe.ModScalar(at, bt, leftTensor, opts...)
}
if oe = bt.standardEngine(); oe != nil {
return oe.ModScalar(at, bt, leftTensor, opts...)
}
if moder, ok = at.Engine().(Moder); ok {
return moder.ModScalar(at, bt, leftTensor, opts...)
}
if moder, ok = bt.Engine().(Moder); ok {
return moder.ModScalar(at, bt, leftTensor, opts...)
}
return nil, errors.New("Neither engines of either operand support Mod")
}
default:
if oe != nil {
return oe.ModScalar(at, bt, true, opts...)
}
if moder, ok = at.Engine().(Moder); ok {
return moder.ModScalar(at, bt, true, opts...)
}
return nil, errors.New("Operand A's engine does not support Mod")
}
default:
switch bt := b.(type) {
case Tensor:
if oe = bt.standardEngine(); oe != nil {
return oe.ModScalar(bt, at, false, opts...)
}
if moder, ok = bt.Engine().(Moder); ok {
return moder.ModScalar(bt, at, false, opts...)
}
return nil, errors.New("Operand B's engine does not support Mod")
default:
return nil, errors.Errorf("Cannot perform Mod of %T and %T", a, b)
}
}
panic("Unreachable")
}
// Dot is a highly opinionated API for performing dot product operations on two *Denses, a and b.
// This function is opinionated with regard to the vector operations because of how it treats operations with vectors.
// Vectors in this package comes in two flavours - column or row vectors. Column vectors have shape (x, 1), while row vectors have shape (1, x).
//
// As such, it is easy to assume that performing a linalg operation on vectors would follow the same rules (i.e shapes have to be aligned for things to work).
// For the most part in this package, this is true. This function is one of the few notable exceptions.
//
// Here I give three specific examples of how the expectations of vector operations will differ.
// Given two vectors, a, b with shapes (4, 1) and (4, 1), Dot() will perform an inner product as if the shapes were (1, 4) and (4, 1). This will result in a scalar value
// Given matrix A and vector b with shapes (2, 4) and (1, 4), Dot() will perform a matrix-vector multiplication as if the shapes were (2,4) and (4,1). This will result in a column vector with shape (2,1)
// Given vector a and matrix B with shapes (3, 1) and (3, 2), Dot() will perform a matrix-vector multiplication as if it were Bᵀ * a
//
// The main reason why this opinionated route was taken was due to the author's familiarity with NumPy, and general laziness in translating existing machine learning algorithms
// to fit the API of the package.
func Dot(x, y Tensor, opts ...FuncOpt) (retVal Tensor, err error) {
if xdottir, ok := x.Engine().(Dotter); ok {
return xdottir.Dot(x, y, opts...)
}
if ydottir, ok := y.Engine().(Dotter); ok {
return ydottir.Dot(x, y, opts...)
}
return nil, errors.New("Neither x's nor y's engines support Dot")
}
// FMA performs Y = A * X + Y.
func FMA(a Tensor, x interface{}, y Tensor) (retVal Tensor, err error) {
if xTensor, ok := x.(Tensor); ok {
if oe := a.standardEngine(); oe != nil {
return oe.FMA(a, xTensor, y)
}
if oe := xTensor.standardEngine(); oe != nil {
return oe.FMA(a, xTensor, y)
}
if oe := y.standardEngine(); oe != nil {
return oe.FMA(a, xTensor, y)
}
if e, ok := a.Engine().(FMAer); ok {
return e.FMA(a, xTensor, y)
}
if e, ok := xTensor.Engine().(FMAer); ok {
return e.FMA(a, xTensor, y)
}
if e, ok := y.Engine().(FMAer); ok {
return e.FMA(a, xTensor, y)
}
} else {
if oe := a.standardEngine(); oe != nil {
return oe.FMAScalar(a, x, y)
}
if oe := y.standardEngine(); oe != nil {
return oe.FMAScalar(a, x, y)
}
if e, ok := a.Engine().(FMAer); ok {
return e.FMAScalar(a, x, y)
}
if e, ok := y.Engine().(FMAer); ok {
return e.FMAScalar(a, x, y)
}
}
return Mul(a, x, WithIncr(y))
}
// MatMul performs matrix-matrix multiplication between two Tensors
func MatMul(a, b Tensor, opts ...FuncOpt) (retVal Tensor, err error) {
if a.Dtype() != b.Dtype() {
err = errors.Errorf(dtypeMismatch, a.Dtype(), b.Dtype())
return
}
switch at := a.(type) {
case *Dense:
bt := b.(*Dense)
return at.MatMul(bt, opts...)
}
panic("Unreachable")
}
// MatVecMul performs matrix-vector multiplication between two Tensors. `a` is expected to be a matrix, and `b` is expected to be a vector
func MatVecMul(a, b Tensor, opts ...FuncOpt) (retVal Tensor, err error) {
if a.Dtype() != b.Dtype() {
err = errors.Errorf(dtypeMismatch, a.Dtype(), b.Dtype())
return
}
switch at := a.(type) {
case *Dense:
bt := b.(*Dense)
return at.MatVecMul(bt, opts...)
}
panic("Unreachable")
}
// Inner finds the inner products of two vector Tensors. Both arguments to the functions are eexpected to be vectors.
func Inner(a, b Tensor) (retVal interface{}, err error) {
if a.Dtype() != b.Dtype() {
err = errors.Errorf(dtypeMismatch, a.Dtype(), b.Dtype())
return
}
switch at := a.(type) {
case *Dense:
bt := b.(*Dense)
return at.Inner(bt)
}
panic("Unreachable")
}
// Outer performs the outer product of two vector Tensors. Both arguments to the functions are expected to be vectors.
func Outer(a, b Tensor, opts ...FuncOpt) (retVal Tensor, err error) {
if a.Dtype() != b.Dtype() {
err = errors.Errorf(dtypeMismatch, a.Dtype(), b.Dtype())
return
}
switch at := a.(type) {
case *Dense:
bt := b.(*Dense)
return at.Outer(bt, opts...)
}
panic("Unreachable")
}
// Contract performs a contraction of given tensors along given axes
func Contract(a, b Tensor, aAxes, bAxes []int) (retVal Tensor, err error) {
if a.Dtype() != b.Dtype() {
err = errors.Errorf(dtypeMismatch, a.Dtype(), b.Dtype())
return
}
switch at := a.(type) {
case *Dense:
bt := b.(*Dense)
return at.TensorMul(bt, aAxes, bAxes)
default:
panic("Unreachable")
}
}