mat/dense_example_test.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2017 The Gonum Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package mat_test

 import (
 	"fmt"
 	"log"

 	"gonum.org/v1/gonum/mat"
 )

 func ExampleDense_Add() {
 	// Initialize two matrices, a and b.
 	a := mat.NewDense(2, 2, []float64{
 		1, 0,
 		1, 0,
 	})
 	b := mat.NewDense(2, 2, []float64{
 		0, 1,
 		0, 1,
 	})

 	// Add a and b, placing the result into c.
 	// Notice that the size is automatically adjusted
 	// when the receiver is empty (has zero size).
 	var c mat.Dense
 	c.Add(a, b)

 	// Print the result using the formatter.
 	fc := mat.Formatted(&c, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("c = %v", fc)

 	// Output:
 	//
 	// c = ⎡1  1⎤
 	//     ⎣1  1⎦
 }

 func ExampleDense_Sub() {
 	// Initialize two matrices, a and b.
 	a := mat.NewDense(2, 2, []float64{
 		1, 1,
 		1, 1,
 	})
 	b := mat.NewDense(2, 2, []float64{
 		1, 0,
 		0, 1,
 	})

 	// Subtract b from a, placing the result into a.
 	a.Sub(a, b)

 	// Print the result using the formatter.
 	fa := mat.Formatted(a, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("a = %v", fa)

 	// Output:
 	//
 	// a = ⎡0  1⎤
 	//     ⎣1  0⎦
 }

 func ExampleDense_MulElem() {
 	// Initialize two matrices, a and b.
 	a := mat.NewDense(2, 2, []float64{
 		1, 2,
 		3, 4,
 	})
 	b := mat.NewDense(2, 2, []float64{
 		1, 2,
 		3, 4,
 	})

 	// Multiply the elements of a and b, placing the result into a.
 	a.MulElem(a, b)

 	// Print the result using the formatter.
 	fa := mat.Formatted(a, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("a = %v", fa)

 	// Output:
 	//
 	// a = ⎡1   4⎤
 	//     ⎣9  16⎦
 }

 func ExampleDense_DivElem() {
 	// Initialize two matrices, a and b.
 	a := mat.NewDense(2, 2, []float64{
 		5, 10,
 		15, 20,
 	})
 	b := mat.NewDense(2, 2, []float64{
 		5, 5,
 		5, 5,
 	})

 	// Divide the elements of a by b, placing the result into a.
 	a.DivElem(a, b)

 	// Print the result using the formatter.
 	fa := mat.Formatted(a, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("a = %v", fa)

 	// Output:
 	//
 	// a = ⎡1  2⎤
 	//     ⎣3  4⎦
 }

 func ExampleDense_Inverse() {
 	// Initialize a matrix A.
 	a := mat.NewDense(2, 2, []float64{
 		2, 1,
 		6, 4,
 	})

 	// Compute the inverse of A.
 	var aInv mat.Dense
 	err := aInv.Inverse(a)
 	if err != nil {
 		log.Fatalf("A is not invertible: %v", err)
 	}

 	// Print the result using the formatter.
 	fa := mat.Formatted(&aInv, mat.Prefix("       "), mat.Squeeze())
 	fmt.Printf("aInv = %.2g\n\n", fa)

 	// Confirm that A * A^-1 = I.
 	var I mat.Dense
 	I.Mul(a, &aInv)
 	fi := mat.Formatted(&I, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("I = %v\n\n", fi)

 	// The Inverse operation, however, should typically be avoided. If the
 	// goal is to solve a linear system
 	//  A * X = B,
 	// then the inverse is not needed and computing the solution as
 	// X = A^{-1} * B is slower and has worse stability properties than
 	// solving the original problem. In this case, the SolveVec method of
 	// VecDense (if B is a vector) or Solve method of Dense (if B is a
 	// matrix) should be used instead of computing the Inverse of A.
 	b := mat.NewDense(2, 2, []float64{
 		2, 3,
 		1, 2,
 	})
 	var x mat.Dense
 	err = x.Solve(a, b)
 	if err != nil {
 		log.Fatalf("no solution: %v", err)
 	}

 	// Print the result using the formatter.
 	fx := mat.Formatted(&x, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("x = %.1f", fx)

 	// Output:
 	//
 	// aInv = ⎡ 2  -0.5⎤
 	//        ⎣-3     1⎦
 	//
 	// I = ⎡1  0⎤
 	//     ⎣0  1⎦
 	//
 	// x = ⎡ 3.5   5.0⎤
 	//     ⎣-5.0  -7.0⎦
 }

 func ExampleDense_Mul() {
 	// Initialize two matrices, a and b.
 	a := mat.NewDense(2, 2, []float64{
 		4, 0,
 		0, 4,
 	})
 	b := mat.NewDense(2, 3, []float64{
 		4, 0, 0,
 		0, 0, 4,
 	})

 	// Take the matrix product of a and b and place the result in c.
 	var c mat.Dense
 	c.Mul(a, b)

 	// Print the result using the formatter.
 	fc := mat.Formatted(&c, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("c = %v", fc)

 	// Output:
 	//
 	// c = ⎡16  0   0⎤
 	//     ⎣ 0  0  16⎦
 }

 func ExampleDense_Exp() {
 	// Initialize a matrix a with some data.
 	a := mat.NewDense(2, 2, []float64{
 		1, 0,
 		0, 1,
 	})

 	// Take the exponential of the matrix and place the result in m.
 	var m mat.Dense
 	m.Exp(a)

 	// Print the result using the formatter.
 	fm := mat.Formatted(&m, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("m = %4.2f", fm)

 	// Output:
 	//
 	// m = ⎡2.72  0.00⎤
 	//     ⎣0.00  2.72⎦
 }

 func ExampleDense_Pow() {
 	// Initialize a matrix with some data.
 	a := mat.NewDense(2, 2, []float64{
 		4, 4,
 		4, 4,
 	})

 	// Take the second power of matrix a and place the result in m.
 	var m mat.Dense
 	m.Pow(a, 2)

 	// Print the result using the formatter.
 	fm := mat.Formatted(&m, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("m = %v\n\n", fm)

 	// Take the zeroth power of matrix a and place the result in n.
 	// We expect an identity matrix of the same size as matrix a.
 	var n mat.Dense
 	n.Pow(a, 0)

 	// Print the result using the formatter.
 	fn := mat.Formatted(&n, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("n = %v", fn)

 	// Output:
 	//
 	// m = ⎡32  32⎤
 	//     ⎣32  32⎦
 	//
 	// n = ⎡1  0⎤
 	//     ⎣0  1⎦
 }

 func ExampleDense_Scale() {
 	// Initialize a matrix with some data.
 	a := mat.NewDense(2, 2, []float64{
 		4, 4,
 		4, 4,
 	})

 	// Scale the matrix by a factor of 0.25 and place the result in m.
 	var m mat.Dense
 	m.Scale(0.25, a)

 	// Print the result using the formatter.
 	fm := mat.Formatted(&m, mat.Prefix("    "), mat.Squeeze())
 	fmt.Printf("m = %4.3f", fm)

 	// Output:
 	//
 	// m = ⎡1.000  1.000⎤
 	//     ⎣1.000  1.000⎦
 }
	// Copyright ©2017 The Gonum Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package mat_test

	import (
	"fmt"
	"log"

	"gonum.org/v1/gonum/mat"
	)

	func ExampleDense_Add() {
	// Initialize two matrices, a and b.
	a := mat.NewDense(2, 2, []float64{
	1, 0,
	1, 0,
	})
	b := mat.NewDense(2, 2, []float64{
	0, 1,
	0, 1,
	})

	// Add a and b, placing the result into c.
	// Notice that the size is automatically adjusted
	// when the receiver is empty (has zero size).
	var c mat.Dense
	c.Add(a, b)

	// Print the result using the formatter.
	fc := mat.Formatted(&c, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("c = %v", fc)

	// Output:
	//
	// c = ⎡1 1⎤
	// ⎣1 1⎦
	}

	func ExampleDense_Sub() {
	// Initialize two matrices, a and b.
	a := mat.NewDense(2, 2, []float64{
	1, 1,
	1, 1,
	})
	b := mat.NewDense(2, 2, []float64{
	1, 0,
	0, 1,
	})

	// Subtract b from a, placing the result into a.
	a.Sub(a, b)

	// Print the result using the formatter.
	fa := mat.Formatted(a, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("a = %v", fa)

	// Output:
	//
	// a = ⎡0 1⎤
	// ⎣1 0⎦
	}

	func ExampleDense_MulElem() {
	// Initialize two matrices, a and b.
	a := mat.NewDense(2, 2, []float64{
	1, 2,
	3, 4,
	})
	b := mat.NewDense(2, 2, []float64{
	1, 2,
	3, 4,
	})

	// Multiply the elements of a and b, placing the result into a.
	a.MulElem(a, b)

	// Print the result using the formatter.
	fa := mat.Formatted(a, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("a = %v", fa)

	// Output:
	//
	// a = ⎡1 4⎤
	// ⎣9 16⎦
	}

	func ExampleDense_DivElem() {
	// Initialize two matrices, a and b.
	a := mat.NewDense(2, 2, []float64{
	5, 10,
	15, 20,
	})
	b := mat.NewDense(2, 2, []float64{
	5, 5,
	5, 5,
	})

	// Divide the elements of a by b, placing the result into a.
	a.DivElem(a, b)

	// Print the result using the formatter.
	fa := mat.Formatted(a, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("a = %v", fa)

	// Output:
	//
	// a = ⎡1 2⎤
	// ⎣3 4⎦
	}

	func ExampleDense_Inverse() {
	// Initialize a matrix A.
	a := mat.NewDense(2, 2, []float64{
	2, 1,
	6, 4,
	})

	// Compute the inverse of A.
	var aInv mat.Dense
	err := aInv.Inverse(a)
	if err != nil {
	log.Fatalf("A is not invertible: %v", err)
	}

	// Print the result using the formatter.
	fa := mat.Formatted(&aInv, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("aInv = %.2g\n\n", fa)

	// Confirm that A * A^-1 = I.
	var I mat.Dense
	I.Mul(a, &aInv)
	fi := mat.Formatted(&I, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("I = %v\n\n", fi)

	// The Inverse operation, however, should typically be avoided. If the
	// goal is to solve a linear system
	// A * X = B,
	// then the inverse is not needed and computing the solution as
	// X = A^{-1} * B is slower and has worse stability properties than
	// solving the original problem. In this case, the SolveVec method of
	// VecDense (if B is a vector) or Solve method of Dense (if B is a
	// matrix) should be used instead of computing the Inverse of A.
	b := mat.NewDense(2, 2, []float64{
	2, 3,
	1, 2,
	})
	var x mat.Dense
	err = x.Solve(a, b)
	if err != nil {
	log.Fatalf("no solution: %v", err)
	}

	// Print the result using the formatter.
	fx := mat.Formatted(&x, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("x = %.1f", fx)

	// Output:
	//
	// aInv = ⎡ 2 -0.5⎤
	// ⎣-3 1⎦
	//
	// I = ⎡1 0⎤
	// ⎣0 1⎦
	//
	// x = ⎡ 3.5 5.0⎤
	// ⎣-5.0 -7.0⎦
	}

	func ExampleDense_Mul() {
	// Initialize two matrices, a and b.
	a := mat.NewDense(2, 2, []float64{
	4, 0,
	0, 4,
	})
	b := mat.NewDense(2, 3, []float64{
	4, 0, 0,
	0, 0, 4,
	})

	// Take the matrix product of a and b and place the result in c.
	var c mat.Dense
	c.Mul(a, b)

	// Print the result using the formatter.
	fc := mat.Formatted(&c, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("c = %v", fc)

	// Output:
	//
	// c = ⎡16 0 0⎤
	// ⎣ 0 0 16⎦
	}

	func ExampleDense_Exp() {
	// Initialize a matrix a with some data.
	a := mat.NewDense(2, 2, []float64{
	1, 0,
	0, 1,
	})

	// Take the exponential of the matrix and place the result in m.
	var m mat.Dense
	m.Exp(a)

	// Print the result using the formatter.
	fm := mat.Formatted(&m, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("m = %4.2f", fm)

	// Output:
	//
	// m = ⎡2.72 0.00⎤
	// ⎣0.00 2.72⎦
	}

	func ExampleDense_Pow() {
	// Initialize a matrix with some data.
	a := mat.NewDense(2, 2, []float64{
	4, 4,
	4, 4,
	})

	// Take the second power of matrix a and place the result in m.
	var m mat.Dense
	m.Pow(a, 2)

	// Print the result using the formatter.
	fm := mat.Formatted(&m, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("m = %v\n\n", fm)

	// Take the zeroth power of matrix a and place the result in n.
	// We expect an identity matrix of the same size as matrix a.
	var n mat.Dense
	n.Pow(a, 0)

	// Print the result using the formatter.
	fn := mat.Formatted(&n, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("n = %v", fn)

	// Output:
	//
	// m = ⎡32 32⎤
	// ⎣32 32⎦
	//
	// n = ⎡1 0⎤
	// ⎣0 1⎦
	}

	func ExampleDense_Scale() {
	// Initialize a matrix with some data.
	a := mat.NewDense(2, 2, []float64{
	4, 4,
	4, 4,
	})

	// Scale the matrix by a factor of 0.25 and place the result in m.
	var m mat.Dense
	m.Scale(0.25, a)

	// Print the result using the formatter.
	fm := mat.Formatted(&m, mat.Prefix(" "), mat.Squeeze())
	fmt.Printf("m = %4.3f", fm)

	// Output:
	//
	// m = ⎡1.000 1.000⎤
	// ⎣1.000 1.000⎦
	}