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

 // Copyright ©2015 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

 import (
 	"fmt"
 	"math/rand"
 	"testing"
 )

 type dims struct{ r, c int }

 var productTests = []struct {
 	n       int
 	factors []dims
 	product dims
 	panics  bool
 }{
 	{
 		n:       1,
 		factors: []dims{{3, 4}},
 		product: dims{3, 4},
 		panics:  false,
 	},
 	{
 		n:       1,
 		factors: []dims{{2, 4}},
 		product: dims{3, 4},
 		panics:  true,
 	},
 	{
 		n:       3,
 		factors: []dims{{10, 30}, {30, 5}, {5, 60}},
 		product: dims{10, 60},
 		panics:  false,
 	},
 	{
 		n:       3,
 		factors: []dims{{100, 30}, {30, 5}, {5, 60}},
 		product: dims{10, 60},
 		panics:  true,
 	},
 	{
 		n:       7,
 		factors: []dims{{60, 5}, {5, 5}, {5, 4}, {4, 10}, {10, 22}, {22, 45}, {45, 10}},
 		product: dims{60, 10},
 		panics:  false,
 	},
 	{
 		n:       7,
 		factors: []dims{{60, 5}, {5, 5}, {5, 400}, {4, 10}, {10, 22}, {22, 45}, {45, 10}},
 		product: dims{60, 10},
 		panics:  true,
 	},
 	{
 		n:       3,
 		factors: []dims{{1, 1000}, {1000, 2}, {2, 2}},
 		product: dims{1, 2},
 		panics:  false,
 	},

 	// Random chains.
 	{
 		n:       0,
 		product: dims{0, 0},
 		panics:  false,
 	},
 	{
 		n:       2,
 		product: dims{60, 10},
 		panics:  false,
 	},
 	{
 		n:       3,
 		product: dims{60, 10},
 		panics:  false,
 	},
 	{
 		n:       4,
 		product: dims{60, 10},
 		panics:  false,
 	},
 	{
 		n:       10,
 		product: dims{60, 10},
 		panics:  false,
 	},
 }

 func TestProduct(t *testing.T) {
 	for _, test := range productTests {
 		dimensions := test.factors
 		if dimensions == nil && test.n > 0 {
 			dimensions = make([]dims, test.n)
 			for i := range dimensions {
 				if i != 0 {
 					dimensions[i].r = dimensions[i-1].c
 				}
 				dimensions[i].c = rand.Intn(50) + 1
 			}
 			dimensions[0].r = test.product.r
 			dimensions[test.n-1].c = test.product.c
 		}
 		factors := make([]Matrix, test.n)
 		for i, d := range dimensions {
 			data := make([]float64, d.r*d.c)
 			for i := range data {
 				data[i] = rand.Float64()
 			}
 			factors[i] = NewDense(d.r, d.c, data)
 		}

 		want := &Dense{}
 		if !test.panics {
 			a := &Dense{}
 			for i, b := range factors {
 				if i == 0 {
 					want.Clone(b)
 					continue
 				}
 				a, want = want, &Dense{}
 				want.Mul(a, b)
 			}
 		}

 		got := NewDense(test.product.r, test.product.c, nil)
 		panicked, message := panics(func() {
 			got.Product(factors...)
 		})
 		if test.panics {
 			if !panicked {
 				t.Errorf("fail to panic with product chain dimensions: %+v result dimension: %+v",
 					dimensions, test.product)
 			}
 			continue
 		} else if panicked {
 			t.Errorf("unexpected panic %q with product chain dimensions: %+v result dimension: %+v",
 				message, dimensions, test.product)
 			continue
 		}

 		if len(factors) > 0 {
 			p := newMultiplier(NewDense(test.product.r, test.product.c, nil), factors)
 			p.optimize()
 			gotCost := p.table.at(0, len(factors)-1).cost
 			expr, wantCost, ok := bestExpressionFor(dimensions)
 			if !ok {
 				t.Fatal("unexpected number of expressions in brute force expression search")
 			}
 			if gotCost != wantCost {
 				t.Errorf("unexpected cost for chain dimensions: %+v got: %v want: %v\n%s",
 					dimensions, got, want, expr)
 			}
 		}

 		if !EqualApprox(got, want, 1e-14) {
 			t.Errorf("unexpected result from product chain dimensions: %+v", dimensions)
 		}
 	}
 }

 // node is a subexpression node.
 type node struct {
 	dims
 	left, right *node
 }

 func (n *node) String() string {
 	if n.left == nil || n.right == nil {
 		rows, cols := n.shape()
 		return fmt.Sprintf("[%d×%d]", rows, cols)
 	}
 	rows, cols := n.shape()
 	return fmt.Sprintf("(%s * %s):[%d×%d]", n.left, n.right, rows, cols)
 }

 // shape returns the dimensions of the result of the subexpression.
 func (n *node) shape() (rows, cols int) {
 	if n.left == nil || n.right == nil {
 		return n.r, n.c
 	}
 	rows, _ = n.left.shape()
 	_, cols = n.right.shape()
 	return rows, cols
 }

 // cost returns the cost to evaluate the subexpression.
 func (n *node) cost() int {
 	if n.left == nil || n.right == nil {
 		return 0
 	}
 	lr, lc := n.left.shape()
 	_, rc := n.right.shape()
 	return lr*lc*rc + n.left.cost() + n.right.cost()
 }

 // expressionsFor returns a channel that can be used to iterate over all
 // expressions of the given factor dimensions.
 func expressionsFor(factors []dims) chan *node {
 	if len(factors) == 1 {
 		c := make(chan *node, 1)
 		c <- &node{dims: factors[0]}
 		close(c)
 		return c
 	}
 	c := make(chan *node)
 	go func() {
 		for i := 1; i < len(factors); i++ {
 			for left := range expressionsFor(factors[:i]) {
 				for right := range expressionsFor(factors[i:]) {
 					c <- &node{left: left, right: right}
 				}
 			}
 		}
 		close(c)
 	}()
 	return c
 }

 // catalan returns the nth 0-based Catalan number.
 func catalan(n int) int {
 	p := 1
 	for k := n + 1; k < 2*n+1; k++ {
 		p *= k
 	}
 	for k := 2; k < n+2; k++ {
 		p /= k
 	}
 	return p
 }

 // bestExpressonFor returns the lowest cost expression for the given expression
 // factor dimensions, the cost of the expression and whether the number of
 // expressions searched matches the Catalan number for the number of factors.
 func bestExpressionFor(factors []dims) (exp *node, cost int, ok bool) {
 	const maxInt = int(^uint(0) >> 1)
 	min := maxInt
 	var best *node
 	var n int
 	for exp := range expressionsFor(factors) {
 		n++
 		cost := exp.cost()
 		if cost < min {
 			min = cost
 			best = exp
 		}
 	}
 	return best, min, n == catalan(len(factors)-1)
 }
	// Copyright ©2015 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

	import (
	"fmt"
	"math/rand"
	"testing"
	)

	type dims struct{ r, c int }

	var productTests = []struct {
	n int
	factors []dims
	product dims
	panics bool
	}{
	{
	n: 1,
	factors: []dims{{3, 4}},
	product: dims{3, 4},
	panics: false,
	},
	{
	n: 1,
	factors: []dims{{2, 4}},
	product: dims{3, 4},
	panics: true,
	},
	{
	n: 3,
	factors: []dims{{10, 30}, {30, 5}, {5, 60}},
	product: dims{10, 60},
	panics: false,
	},
	{
	n: 3,
	factors: []dims{{100, 30}, {30, 5}, {5, 60}},
	product: dims{10, 60},
	panics: true,
	},
	{
	n: 7,
	factors: []dims{{60, 5}, {5, 5}, {5, 4}, {4, 10}, {10, 22}, {22, 45}, {45, 10}},
	product: dims{60, 10},
	panics: false,
	},
	{
	n: 7,
	factors: []dims{{60, 5}, {5, 5}, {5, 400}, {4, 10}, {10, 22}, {22, 45}, {45, 10}},
	product: dims{60, 10},
	panics: true,
	},
	{
	n: 3,
	factors: []dims{{1, 1000}, {1000, 2}, {2, 2}},
	product: dims{1, 2},
	panics: false,
	},

	// Random chains.
	{
	n: 0,
	product: dims{0, 0},
	panics: false,
	},
	{
	n: 2,
	product: dims{60, 10},
	panics: false,
	},
	{
	n: 3,
	product: dims{60, 10},
	panics: false,
	},
	{
	n: 4,
	product: dims{60, 10},
	panics: false,
	},
	{
	n: 10,
	product: dims{60, 10},
	panics: false,
	},
	}

	func TestProduct(t *testing.T) {
	for _, test := range productTests {
	dimensions := test.factors
	if dimensions == nil && test.n > 0 {
	dimensions = make([]dims, test.n)
	for i := range dimensions {
	if i != 0 {
	dimensions[i].r = dimensions[i-1].c
	}
	dimensions[i].c = rand.Intn(50) + 1
	}
	dimensions[0].r = test.product.r
	dimensions[test.n-1].c = test.product.c
	}
	factors := make([]Matrix, test.n)
	for i, d := range dimensions {
	data := make([]float64, d.r*d.c)
	for i := range data {
	data[i] = rand.Float64()
	}
	factors[i] = NewDense(d.r, d.c, data)
	}

	want := &Dense{}
	if !test.panics {
	a := &Dense{}
	for i, b := range factors {
	if i == 0 {
	want.Clone(b)
	continue
	}
	a, want = want, &Dense{}
	want.Mul(a, b)
	}
	}

	got := NewDense(test.product.r, test.product.c, nil)
	panicked, message := panics(func() {
	got.Product(factors...)
	})
	if test.panics {
	if !panicked {
	t.Errorf("fail to panic with product chain dimensions: %+v result dimension: %+v",
	dimensions, test.product)
	}
	continue
	} else if panicked {
	t.Errorf("unexpected panic %q with product chain dimensions: %+v result dimension: %+v",
	message, dimensions, test.product)
	continue
	}

	if len(factors) > 0 {
	p := newMultiplier(NewDense(test.product.r, test.product.c, nil), factors)
	p.optimize()
	gotCost := p.table.at(0, len(factors)-1).cost
	expr, wantCost, ok := bestExpressionFor(dimensions)
	if !ok {
	t.Fatal("unexpected number of expressions in brute force expression search")
	}
	if gotCost != wantCost {
	t.Errorf("unexpected cost for chain dimensions: %+v got: %v want: %v\n%s",
	dimensions, got, want, expr)
	}
	}

	if !EqualApprox(got, want, 1e-14) {
	t.Errorf("unexpected result from product chain dimensions: %+v", dimensions)
	}
	}
	}

	// node is a subexpression node.
	type node struct {
	dims
	left, right *node
	}

	func (n *node) String() string {
	if n.left == nil \|\| n.right == nil {
	rows, cols := n.shape()
	return fmt.Sprintf("[%d×%d]", rows, cols)
	}
	rows, cols := n.shape()
	return fmt.Sprintf("(%s * %s):[%d×%d]", n.left, n.right, rows, cols)
	}

	// shape returns the dimensions of the result of the subexpression.
	func (n *node) shape() (rows, cols int) {
	if n.left == nil \|\| n.right == nil {
	return n.r, n.c
	}
	rows, _ = n.left.shape()
	_, cols = n.right.shape()
	return rows, cols
	}

	// cost returns the cost to evaluate the subexpression.
	func (n *node) cost() int {
	if n.left == nil \|\| n.right == nil {
	return 0
	}
	lr, lc := n.left.shape()
	_, rc := n.right.shape()
	return lrlcrc + n.left.cost() + n.right.cost()
	}

	// expressionsFor returns a channel that can be used to iterate over all
	// expressions of the given factor dimensions.
	func expressionsFor(factors []dims) chan *node {
	if len(factors) == 1 {
	c := make(chan *node, 1)
	c <- &node{dims: factors[0]}
	close(c)
	return c
	}
	c := make(chan *node)
	go func() {
	for i := 1; i < len(factors); i++ {
	for left := range expressionsFor(factors[:i]) {
	for right := range expressionsFor(factors[i:]) {
	c <- &node{left: left, right: right}
	}
	}
	}
	close(c)
	}()
	return c
	}

	// catalan returns the nth 0-based Catalan number.
	func catalan(n int) int {
	p := 1
	for k := n + 1; k < 2*n+1; k++ {
	p *= k
	}
	for k := 2; k < n+2; k++ {
	p /= k
	}
	return p
	}

	// bestExpressonFor returns the lowest cost expression for the given expression
	// factor dimensions, the cost of the expression and whether the number of
	// expressions searched matches the Catalan number for the number of factors.
	func bestExpressionFor(factors []dims) (exp *node, cost int, ok bool) {
	const maxInt = int(^uint(0) >> 1)
	min := maxInt
	var best *node
	var n int
	for exp := range expressionsFor(factors) {
	n++
	cost := exp.cost()
	if cost < min {
	min = cost
	best = exp
	}
	}
	return best, min, n == catalan(len(factors)-1)
	}