mathext/ell_complete_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 mathext

 import (
 	"math"
 	"testing"
 )

 // TestCompleteKE checks if the Legendre's relation for m=0.0001(0.0001)0.9999
 // is satisfied with accuracy 1e-14.
 func TestCompleteKE(t *testing.T) {
 	t.Parallel()
 	const tol = 1.0e-14

 	for m := 1; m <= 9999; m++ {
 		mf := float64(m) / 10000
 		mp := 1 - mf
 		K, Kp := CompleteK(mf), CompleteK(mp)
 		E, Ep := CompleteE(mf), CompleteE(mp)
 		legendre := math.Abs(E*Kp + Ep*K - K*Kp - math.Pi/2)
 		if legendre > tol {
 			t.Fatalf("legendre > tol: m=%v, legendre=%v, tol=%v", mf, legendre, tol)
 		}
 	}
 }

 // TestCompleteBD checks if the relations between two associate elliptic integrals B(m), D(m)
 // and more common Legendre's elliptic integrals K(m), E(m) are satisfied with accuracy 1e-14
 // for m=0.0001(0.0001)0.9999.
 //
 // K(m) and E(m) can be computed without cancellation problems as following:
 //	K(m) = B(m) + D(m),
 //	E(m) = B(m) + (1-m)D(m).
 func TestCompleteBD(t *testing.T) {
 	t.Parallel()
 	const tol = 1.0e-14

 	for m := 1; m <= 9999; m++ {
 		mf := float64(m) / 10000
 		B, D := CompleteB(mf), CompleteD(mf)
 		K, E := CompleteK(mf), CompleteE(mf)
 		difference1 := math.Abs(K - (B + D))
 		difference2 := math.Abs(E - (B + (1-mf)*D))
 		if difference1 > tol {
 			t.Fatalf("difference1 > tol: m=%v, difference1=%v, tol=%v", mf, difference1, tol)
 		}
 		if difference2 > tol {
 			t.Fatalf("difference2 > tol: m=%v, difference2=%v, tol=%v", mf, difference2, tol)
 		}
 	}
 }
	// 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 mathext

	import (
	"math"
	"testing"
	)

	// TestCompleteKE checks if the Legendre's relation for m=0.0001(0.0001)0.9999
	// is satisfied with accuracy 1e-14.
	func TestCompleteKE(t *testing.T) {
	t.Parallel()
	const tol = 1.0e-14

	for m := 1; m <= 9999; m++ {
	mf := float64(m) / 10000
	mp := 1 - mf
	K, Kp := CompleteK(mf), CompleteK(mp)
	E, Ep := CompleteE(mf), CompleteE(mp)
	legendre := math.Abs(EKp + EpK - K*Kp - math.Pi/2)
	if legendre > tol {
	t.Fatalf("legendre > tol: m=%v, legendre=%v, tol=%v", mf, legendre, tol)
	}
	}
	}

	// TestCompleteBD checks if the relations between two associate elliptic integrals B(m), D(m)
	// and more common Legendre's elliptic integrals K(m), E(m) are satisfied with accuracy 1e-14
	// for m=0.0001(0.0001)0.9999.
	//
	// K(m) and E(m) can be computed without cancellation problems as following:
	// K(m) = B(m) + D(m),
	// E(m) = B(m) + (1-m)D(m).
	func TestCompleteBD(t *testing.T) {
	t.Parallel()
	const tol = 1.0e-14

	for m := 1; m <= 9999; m++ {
	mf := float64(m) / 10000
	B, D := CompleteB(mf), CompleteD(mf)
	K, E := CompleteK(mf), CompleteE(mf)
	difference1 := math.Abs(K - (B + D))
	difference2 := math.Abs(E - (B + (1-mf)*D))
	if difference1 > tol {
	t.Fatalf("difference1 > tol: m=%v, difference1=%v, tol=%v", mf, difference1, tol)
	}
	if difference2 > tol {
	t.Fatalf("difference2 > tol: m=%v, difference2=%v, tol=%v", mf, difference2, tol)
	}
	}
	}