go/test/hilbert.go

// $G $D/$F.go && $L $F.$A && ./$A.out

// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

// A little test program for rational arithmetics.
// Computes a Hilbert matrix, its inverse, multiplies them
// and verifies that the product is the identity matrix.

package main

import Big "bignum"
import Fmt "fmt"


func assert(p bool) {
	if !p {
		panic("assert failed");
	}
}


var (
	Zero = Big.Rat(0, 1);
	One = Big.Rat(1, 1);
)


type Matrix struct {
	n, m int;
	a []*Big.Rational;
}


func (a *Matrix) at(i, j int) *Big.Rational {
	assert(0 <= i && i < a.n && 0 <= j && j < a.m);
	return a.a[i*a.m + j];
}


func (a *Matrix) set(i, j int, x *Big.Rational) {
	assert(0 <= i && i < a.n && 0 <= j && j < a.m);
	a.a[i*a.m + j] = x;
}


func NewMatrix(n, m int) *Matrix {
	assert(0 <= n && 0 <= m);
	a := new(Matrix);
	a.n = n;
	a.m = m;
	a.a = make([]*Big.Rational, n*m);
	return a;
}


func NewUnit(n int) *Matrix {
	a := NewMatrix(n, n);
	for i := 0; i < n; i++ {
		for j := 0; j < n; j++ {
			x := Zero;
			if i == j {
				x = One;
			}
			a.set(i, j, x);
		}
	}
	return a;
}


func NewHilbert(n int) *Matrix {
	a := NewMatrix(n, n);
	for i := 0; i < n; i++ {
		for j := 0; j < n; j++ {
			x := Big.Rat(1, i + j + 1);
			a.set(i, j, x);
		}
	}
	return a;
}


func MakeRat(x Big.Natural) *Big.Rational {
	return Big.MakeRat(Big.MakeInt(false, x), Big.Nat(1));
}


func NewInverseHilbert(n int) *Matrix {
	a := NewMatrix(n, n);
	for i := 0; i < n; i++ {
		for j := 0; j < n; j++ {
			x0 := One;
			if (i+j)&1 != 0 {
				x0 = x0.Neg();
			}
			x1 := Big.Rat(i + j + 1, 1);
			x2 := MakeRat(Big.Binomial(uint(n+i), uint(n-j-1)));
			x3 := MakeRat(Big.Binomial(uint(n+j), uint(n-i-1)));
			x4 := MakeRat(Big.Binomial(uint(i+j), uint(i)));
			x4 = x4.Mul(x4);
			a.set(i, j, x0.Mul(x1).Mul(x2).Mul(x3).Mul(x4));
		}
	}
	return a;
}


func (a *Matrix) Mul(b *Matrix) *Matrix {
	assert(a.m == b.n);
	c := NewMatrix(a.n, b.m);
	for i := 0; i < c.n; i++ {
		for j := 0; j < c.m; j++ {
			x := Zero;
			for k := 0; k < a.m; k++ {
				x = x.Add(a.at(i, k).Mul(b.at(k, j)));
			}
			c.set(i, j, x);
		}
	}
	return c;
}


func (a *Matrix) Eql(b *Matrix) bool {
	if a.n != b.n || a.m != b.m {
		return false;
	}
	for i := 0; i < a.n; i++ {
		for j := 0; j < a.m; j++ {
			if a.at(i, j).Cmp(b.at(i,j)) != 0 {
				return false;
			}
		}
	}
	return true;
}


func (a *Matrix) String() string {
	s := "";
	for i := 0; i < a.n; i++ {
		for j := 0; j < a.m; j++ {
			s += Fmt.Sprintf("\t%s", a.at(i, j));
		}
		s += "\n";
	}
	return s;
}


func main() {
	n := 10;
	a := NewHilbert(n);
	b := NewInverseHilbert(n);
	I := NewUnit(n);
	ab := a.Mul(b);
	if !ab.Eql(I) {
		Fmt.Println("a =", a);
		Fmt.Println("b =", b);
		Fmt.Println("a*b =", ab);
		Fmt.Println("I =", I);
		panic("FAILED");
	}
}
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`// $G $D/$F.go && $L $F.$A && ./$A.out`

			`// Copyright 2009 The Go Authors. All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`// A little test program for rational arithmetics.`
			`// Computes a Hilbert matrix, its inverse, multiplies them`
			`// and verifies that the product is the identity matrix.`

			`package main`

			`import Big "bignum"`
			`import Fmt "fmt"`


			`func assert(p bool) {`
			`if !p {`
			`panic("assert failed");`
			`}`
			`}`


delete export TBR=r OCL=23121 CL=23127 2009-01-20 15:40:40 -07:00			`var (`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`Zero = Big.Rat(0, 1);`
			`One = Big.Rat(1, 1);`
			`)`


delete export TBR=r OCL=23121 CL=23127 2009-01-20 15:40:40 -07:00			`type Matrix struct {`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`n, m int;`
convert *[] to []. R=r OCL=21563 CL=21571 2008-12-18 23:37:22 -07:00			`a []*Big.Rational;`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`}`


			`func (a Matrix) at(i, j int) Big.Rational {`
			`assert(0 <= i && i < a.n && 0 <= j && j < a.m);`
			`return a.a[i*a.m + j];`
			`}`


			`func (a Matrix) set(i, j int, x Big.Rational) {`
			`assert(0 <= i && i < a.n && 0 <= j && j < a.m);`
			`a.a[i*a.m + j] = x;`
			`}`


delete export TBR=r OCL=23121 CL=23127 2009-01-20 15:40:40 -07:00			`func NewMatrix(n, m int) *Matrix {`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`assert(0 <= n && 0 <= m);`
new new & make R=r OCL=22166 CL=22166 2009-01-06 16:19:02 -07:00			`a := new(Matrix);`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`a.n = n;`
			`a.m = m;`
new new & make R=r OCL=22166 CL=22166 2009-01-06 16:19:02 -07:00			`a.a = make([]Big.Rational, nm);`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`return a;`
			`}`


delete export TBR=r OCL=23121 CL=23127 2009-01-20 15:40:40 -07:00			`func NewUnit(n int) *Matrix {`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`a := NewMatrix(n, n);`
			`for i := 0; i < n; i++ {`
			`for j := 0; j < n; j++ {`
			`x := Zero;`
			`if i == j {`
			`x = One;`
			`}`
			`a.set(i, j, x);`
			`}`
			`}`
			`return a;`
			`}`


delete export TBR=r OCL=23121 CL=23127 2009-01-20 15:40:40 -07:00			`func NewHilbert(n int) *Matrix {`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`a := NewMatrix(n, n);`
			`for i := 0; i < n; i++ {`
			`for j := 0; j < n; j++ {`
			`x := Big.Rat(1, i + j + 1);`
			`a.set(i, j, x);`
			`}`
			`}`
			`return a;`
			`}`


delete export TBR=r OCL=23121 CL=23127 2009-01-20 15:40:40 -07:00			`func MakeRat(x Big.Natural) *Big.Rational {`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`return Big.MakeRat(Big.MakeInt(false, x), Big.Nat(1));`
			`}`


delete export TBR=r OCL=23121 CL=23127 2009-01-20 15:40:40 -07:00			`func NewInverseHilbert(n int) *Matrix {`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`a := NewMatrix(n, n);`
			`for i := 0; i < n; i++ {`
			`for j := 0; j < n; j++ {`
			`x0 := One;`
			`if (i+j)&1 != 0 {`
			`x0 = x0.Neg();`
			`}`
			`x1 := Big.Rat(i + j + 1, 1);`
			`x2 := MakeRat(Big.Binomial(uint(n+i), uint(n-j-1)));`
			`x3 := MakeRat(Big.Binomial(uint(n+j), uint(n-i-1)));`
			`x4 := MakeRat(Big.Binomial(uint(i+j), uint(i)));`
			`x4 = x4.Mul(x4);`
allow slices (open arrays) to be receivers in methods. put back original code for hilbert/bignum R=r OCL=21910 CL=21920 2008-12-30 15:02:20 -07:00			`a.set(i, j, x0.Mul(x1).Mul(x2).Mul(x3).Mul(x4));`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`}`
			`}`
			`return a;`
			`}`


			`func (a Matrix) Mul(b Matrix) *Matrix {`
			`assert(a.m == b.n);`
			`c := NewMatrix(a.n, b.m);`
			`for i := 0; i < c.n; i++ {`
			`for j := 0; j < c.m; j++ {`
			`x := Zero;`
			`for k := 0; k < a.m; k++ {`
allow slices (open arrays) to be receivers in methods. put back original code for hilbert/bignum R=r OCL=21910 CL=21920 2008-12-30 15:02:20 -07:00			`x = x.Add(a.at(i, k).Mul(b.at(k, j)));`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`}`
			`c.set(i, j, x);`
			`}`
			`}`
			`return c;`
			`}`


			`func (a Matrix) Eql(b Matrix) bool {`
			`if a.n != b.n \|\| a.m != b.m {`
			`return false;`
			`}`
			`for i := 0; i < a.n; i++ {`
			`for j := 0; j < a.m; j++ {`
allow slices (open arrays) to be receivers in methods. put back original code for hilbert/bignum R=r OCL=21910 CL=21920 2008-12-30 15:02:20 -07:00			`if a.at(i, j).Cmp(b.at(i,j)) != 0 {`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`return false;`
			`}`
			`}`
			`}`
			`return true;`
			`}`


			`func (a *Matrix) String() string {`
			`s := "";`
			`for i := 0; i < a.n; i++ {`
			`for j := 0; j < a.m; j++ {`
printf->Printf etc. the raw fmt routines will be another, smaller but subtler pass. R=rsc DELTA=157 (0 added, 0 deleted, 157 changed) OCL=22851 CL=22851 2009-01-15 14:48:11 -07:00			`s += Fmt.Sprintf("\t%s", a.at(i, j));`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`}`
			`s += "\n";`
			`}`
			`return s;`
			`}`


			`func main() {`
			`n := 10;`
			`a := NewHilbert(n);`
			`b := NewInverseHilbert(n);`
			`I := NewUnit(n);`
			`ab := a.Mul(b);`
			`if !ab.Eql(I) {`
printf->Printf etc. the raw fmt routines will be another, smaller but subtler pass. R=rsc DELTA=157 (0 added, 0 deleted, 157 changed) OCL=22851 CL=22851 2009-01-15 14:48:11 -07:00			`Fmt.Println("a =", a);`
			`Fmt.Println("b =", b);`
			`Fmt.Println("a*b =", ab);`
			`Fmt.Println("I =", I);`
A recreational programming exercise: Multiplication of a Hilbert matrix with its inverse using Bignum.Rationals as a test case for rational arithmetic. R=r OCL=18706 CL=18706 2008-11-06 15:23:49 -07:00			`panic("FAILED");`
			`}`
			`}`