src/math/big/alias_test.go - go - Git at Google

 // Copyright 2019 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.

 package big_test

 import (
 	cryptorand "crypto/rand"
 	"math/big"
 	"math/rand"
 	"reflect"
 	"testing"
 	"testing/quick"
 )

 func equal(z, x *big.Int) bool {
 	return z.Cmp(x) == 0
 }

 type bigInt struct {
 	*big.Int
 }

 func generatePositiveInt(rand *rand.Rand, size int) *big.Int {
 	n := big.NewInt(1)
 	n.Lsh(n, uint(rand.Intn(size*8)))
 	n.Rand(rand, n)
 	return n
 }

 func (bigInt) Generate(rand *rand.Rand, size int) reflect.Value {
 	n := generatePositiveInt(rand, size)
 	if rand.Intn(4) == 0 {
 		n.Neg(n)
 	}
 	return reflect.ValueOf(bigInt{n})
 }

 type notZeroInt struct {
 	*big.Int
 }

 func (notZeroInt) Generate(rand *rand.Rand, size int) reflect.Value {
 	n := generatePositiveInt(rand, size)
 	if rand.Intn(4) == 0 {
 		n.Neg(n)
 	}
 	if n.Sign() == 0 {
 		n.SetInt64(1)
 	}
 	return reflect.ValueOf(notZeroInt{n})
 }

 type positiveInt struct {
 	*big.Int
 }

 func (positiveInt) Generate(rand *rand.Rand, size int) reflect.Value {
 	n := generatePositiveInt(rand, size)
 	return reflect.ValueOf(positiveInt{n})
 }

 type prime struct {
 	*big.Int
 }

 func (prime) Generate(r *rand.Rand, size int) reflect.Value {
 	n, err := cryptorand.Prime(r, r.Intn(size*8-2)+2)
 	if err != nil {
 		panic(err)
 	}
 	return reflect.ValueOf(prime{n})
 }

 type zeroOrOne struct {
 	uint
 }

 func (zeroOrOne) Generate(rand *rand.Rand, size int) reflect.Value {
 	return reflect.ValueOf(zeroOrOne{uint(rand.Intn(2))})
 }

 type smallUint struct {
 	uint
 }

 func (smallUint) Generate(rand *rand.Rand, size int) reflect.Value {
 	return reflect.ValueOf(smallUint{uint(rand.Intn(1024))})
 }

 // checkAliasingOneArg checks if f returns a correct result when v and x alias.
 //
 // f is a function that takes x as an argument, doesn't modify it, sets v to the
 // result, and returns v. It is the function signature of unbound methods like
 //
 //	func (v *big.Int) m(x *big.Int) *big.Int
 //
 // v and x are two random Int values. v is randomized even if it will be
 // overwritten to test for improper buffer reuse.
 func checkAliasingOneArg(t *testing.T, f func(v, x *big.Int) *big.Int, v, x *big.Int) bool {
 	x1, v1 := new(big.Int).Set(x), new(big.Int).Set(x)

 	// Calculate a reference f(x) without aliasing.
 	if out := f(v, x); out != v {
 		return false
 	}

 	// Test aliasing the argument and the receiver.
 	if out := f(v1, v1); out != v1 || !equal(v1, v) {
 		t.Logf("f(v, x) != f(x, x)")
 		return false
 	}

 	// Ensure the arguments was not modified.
 	return equal(x, x1)
 }

 // checkAliasingTwoArgs checks if f returns a correct result when any
 // combination of v, x and y alias.
 //
 // f is a function that takes x and y as arguments, doesn't modify them, sets v
 // to the result, and returns v. It is the function signature of unbound methods
 // like
 //
 //	func (v *big.Int) m(x, y *big.Int) *big.Int
 //
 // v, x and y are random Int values. v is randomized even if it will be
 // overwritten to test for improper buffer reuse.
 func checkAliasingTwoArgs(t *testing.T, f func(v, x, y *big.Int) *big.Int, v, x, y *big.Int) bool {
 	x1, y1, v1 := new(big.Int).Set(x), new(big.Int).Set(y), new(big.Int).Set(v)

 	// Calculate a reference f(x, y) without aliasing.
 	if out := f(v, x, y); out == nil {
 		// Certain functions like ModInverse return nil for certain inputs.
 		// Check that receiver and arguments were unchanged and move on.
 		return equal(x, x1) && equal(y, y1) && equal(v, v1)
 	} else if out != v {
 		return false
 	}

 	// Test aliasing the first argument and the receiver.
 	v1.Set(x)
 	if out := f(v1, v1, y); out != v1 || !equal(v1, v) {
 		t.Logf("f(v, x, y) != f(x, x, y)")
 		return false
 	}
 	// Test aliasing the second argument and the receiver.
 	v1.Set(y)
 	if out := f(v1, x, v1); out != v1 || !equal(v1, v) {
 		t.Logf("f(v, x, y) != f(y, x, y)")
 		return false
 	}

 	// Calculate a reference f(y, y) without aliasing.
 	// We use y because it's the one that commonly has restrictions
 	// like being prime or non-zero.
 	v1.Set(v)
 	y2 := new(big.Int).Set(y)
 	if out := f(v, y, y2); out == nil {
 		return equal(y, y1) && equal(y2, y1) && equal(v, v1)
 	} else if out != v {
 		return false
 	}

 	// Test aliasing the two arguments.
 	if out := f(v1, y, y); out != v1 || !equal(v1, v) {
 		t.Logf("f(v, y1, y2) != f(v, y, y)")
 		return false
 	}
 	// Test aliasing the two arguments and the receiver.
 	v1.Set(y)
 	if out := f(v1, v1, v1); out != v1 || !equal(v1, v) {
 		t.Logf("f(v, y1, y2) != f(y, y, y)")
 		return false
 	}

 	// Ensure the arguments were not modified.
 	return equal(x, x1) && equal(y, y1)
 }

 func TestAliasing(t *testing.T) {
 	for name, f := range map[string]interface{}{
 		"Abs": func(v, x bigInt) bool {
 			return checkAliasingOneArg(t, (*big.Int).Abs, v.Int, x.Int)
 		},
 		"Add": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Add, v.Int, x.Int, y.Int)
 		},
 		"And": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).And, v.Int, x.Int, y.Int)
 		},
 		"AndNot": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).AndNot, v.Int, x.Int, y.Int)
 		},
 		"Div": func(v, x bigInt, y notZeroInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Div, v.Int, x.Int, y.Int)
 		},
 		"Exp-XY": func(v, x, y bigInt, z notZeroInt) bool {
 			return checkAliasingTwoArgs(t, func(v, x, y *big.Int) *big.Int {
 				return v.Exp(x, y, z.Int)
 			}, v.Int, x.Int, y.Int)
 		},
 		"Exp-XZ": func(v, x, y bigInt, z notZeroInt) bool {
 			return checkAliasingTwoArgs(t, func(v, x, z *big.Int) *big.Int {
 				return v.Exp(x, y.Int, z)
 			}, v.Int, x.Int, z.Int)
 		},
 		"Exp-YZ": func(v, x, y bigInt, z notZeroInt) bool {
 			return checkAliasingTwoArgs(t, func(v, y, z *big.Int) *big.Int {
 				return v.Exp(x.Int, y, z)
 			}, v.Int, y.Int, z.Int)
 		},
 		"GCD": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, func(v, x, y *big.Int) *big.Int {
 				return v.GCD(nil, nil, x, y)
 			}, v.Int, x.Int, y.Int)
 		},
 		"GCD-X": func(v, x, y bigInt) bool {
 			a, b := new(big.Int), new(big.Int)
 			return checkAliasingTwoArgs(t, func(v, x, y *big.Int) *big.Int {
 				a.GCD(v, b, x, y)
 				return v
 			}, v.Int, x.Int, y.Int)
 		},
 		"GCD-Y": func(v, x, y bigInt) bool {
 			a, b := new(big.Int), new(big.Int)
 			return checkAliasingTwoArgs(t, func(v, x, y *big.Int) *big.Int {
 				a.GCD(b, v, x, y)
 				return v
 			}, v.Int, x.Int, y.Int)
 		},
 		"Lsh": func(v, x bigInt, n smallUint) bool {
 			return checkAliasingOneArg(t, func(v, x *big.Int) *big.Int {
 				return v.Lsh(x, n.uint)
 			}, v.Int, x.Int)
 		},
 		"Mod": func(v, x bigInt, y notZeroInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Mod, v.Int, x.Int, y.Int)
 		},
 		"ModInverse": func(v, x bigInt, y notZeroInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).ModInverse, v.Int, x.Int, y.Int)
 		},
 		"ModSqrt": func(v, x bigInt, p prime) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).ModSqrt, v.Int, x.Int, p.Int)
 		},
 		"Mul": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Mul, v.Int, x.Int, y.Int)
 		},
 		"Neg": func(v, x bigInt) bool {
 			return checkAliasingOneArg(t, (*big.Int).Neg, v.Int, x.Int)
 		},
 		"Not": func(v, x bigInt) bool {
 			return checkAliasingOneArg(t, (*big.Int).Not, v.Int, x.Int)
 		},
 		"Or": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Or, v.Int, x.Int, y.Int)
 		},
 		"Quo": func(v, x bigInt, y notZeroInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Quo, v.Int, x.Int, y.Int)
 		},
 		"Rand": func(v, x bigInt, seed int64) bool {
 			return checkAliasingOneArg(t, func(v, x *big.Int) *big.Int {
 				rnd := rand.New(rand.NewSource(seed))
 				return v.Rand(rnd, x)
 			}, v.Int, x.Int)
 		},
 		"Rem": func(v, x bigInt, y notZeroInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Rem, v.Int, x.Int, y.Int)
 		},
 		"Rsh": func(v, x bigInt, n smallUint) bool {
 			return checkAliasingOneArg(t, func(v, x *big.Int) *big.Int {
 				return v.Rsh(x, n.uint)
 			}, v.Int, x.Int)
 		},
 		"Set": func(v, x bigInt) bool {
 			return checkAliasingOneArg(t, (*big.Int).Set, v.Int, x.Int)
 		},
 		"SetBit": func(v, x bigInt, i smallUint, b zeroOrOne) bool {
 			return checkAliasingOneArg(t, func(v, x *big.Int) *big.Int {
 				return v.SetBit(x, int(i.uint), b.uint)
 			}, v.Int, x.Int)
 		},
 		"Sqrt": func(v bigInt, x positiveInt) bool {
 			return checkAliasingOneArg(t, (*big.Int).Sqrt, v.Int, x.Int)
 		},
 		"Sub": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Sub, v.Int, x.Int, y.Int)
 		},
 		"Xor": func(v, x, y bigInt) bool {
 			return checkAliasingTwoArgs(t, (*big.Int).Xor, v.Int, x.Int, y.Int)
 		},
 	} {
 		t.Run(name, func(t *testing.T) {
 			scale := 1.0
 			switch name {
 			case "ModInverse", "GCD-Y", "GCD-X":
 				scale /= 5
 			case "Rand":
 				scale /= 10
 			case "Exp-XZ", "Exp-XY", "Exp-YZ":
 				scale /= 50
 			case "ModSqrt":
 				scale /= 500
 			}
 			if err := quick.Check(f, &quick.Config{
 				MaxCountScale: scale,
 			}); err != nil {
 				t.Error(err)
 			}
 		})
 	}
 }
	// Copyright 2019 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.

	package big_test

	import (
	cryptorand "crypto/rand"
	"math/big"
	"math/rand"
	"reflect"
	"testing"
	"testing/quick"
	)

	func equal(z, x *big.Int) bool {
	return z.Cmp(x) == 0
	}

	type bigInt struct {
	*big.Int
	}

	func generatePositiveInt(rand rand.Rand, size int) big.Int {
	n := big.NewInt(1)
	n.Lsh(n, uint(rand.Intn(size*8)))
	n.Rand(rand, n)
	return n
	}

	func (bigInt) Generate(rand *rand.Rand, size int) reflect.Value {
	n := generatePositiveInt(rand, size)
	if rand.Intn(4) == 0 {
	n.Neg(n)
	}
	return reflect.ValueOf(bigInt{n})
	}

	type notZeroInt struct {
	*big.Int
	}

	func (notZeroInt) Generate(rand *rand.Rand, size int) reflect.Value {
	n := generatePositiveInt(rand, size)
	if rand.Intn(4) == 0 {
	n.Neg(n)
	}
	if n.Sign() == 0 {
	n.SetInt64(1)
	}
	return reflect.ValueOf(notZeroInt{n})
	}

	type positiveInt struct {
	*big.Int
	}

	func (positiveInt) Generate(rand *rand.Rand, size int) reflect.Value {
	n := generatePositiveInt(rand, size)
	return reflect.ValueOf(positiveInt{n})
	}

	type prime struct {
	*big.Int
	}

	func (prime) Generate(r *rand.Rand, size int) reflect.Value {
	n, err := cryptorand.Prime(r, r.Intn(size*8-2)+2)
	if err != nil {
	panic(err)
	}
	return reflect.ValueOf(prime{n})
	}

	type zeroOrOne struct {
	uint
	}

	func (zeroOrOne) Generate(rand *rand.Rand, size int) reflect.Value {
	return reflect.ValueOf(zeroOrOne{uint(rand.Intn(2))})
	}

	type smallUint struct {
	uint
	}

	func (smallUint) Generate(rand *rand.Rand, size int) reflect.Value {
	return reflect.ValueOf(smallUint{uint(rand.Intn(1024))})
	}

	// checkAliasingOneArg checks if f returns a correct result when v and x alias.
	//
	// f is a function that takes x as an argument, doesn't modify it, sets v to the
	// result, and returns v. It is the function signature of unbound methods like
	//
	// func (v big.Int) m(x big.Int) *big.Int
	//
	// v and x are two random Int values. v is randomized even if it will be
	// overwritten to test for improper buffer reuse.
	func checkAliasingOneArg(t testing.T, f func(v, x big.Int) big.Int, v, x big.Int) bool {
	x1, v1 := new(big.Int).Set(x), new(big.Int).Set(x)

	// Calculate a reference f(x) without aliasing.
	if out := f(v, x); out != v {
	return false
	}

	// Test aliasing the argument and the receiver.
	if out := f(v1, v1); out != v1 \|\| !equal(v1, v) {
	t.Logf("f(v, x) != f(x, x)")
	return false
	}

	// Ensure the arguments was not modified.
	return equal(x, x1)
	}

	// checkAliasingTwoArgs checks if f returns a correct result when any
	// combination of v, x and y alias.
	//
	// f is a function that takes x and y as arguments, doesn't modify them, sets v
	// to the result, and returns v. It is the function signature of unbound methods
	// like
	//
	// func (v big.Int) m(x, y big.Int) *big.Int
	//
	// v, x and y are random Int values. v is randomized even if it will be
	// overwritten to test for improper buffer reuse.
	func checkAliasingTwoArgs(t testing.T, f func(v, x, y big.Int) big.Int, v, x, y big.Int) bool {
	x1, y1, v1 := new(big.Int).Set(x), new(big.Int).Set(y), new(big.Int).Set(v)

	// Calculate a reference f(x, y) without aliasing.
	if out := f(v, x, y); out == nil {
	// Certain functions like ModInverse return nil for certain inputs.
	// Check that receiver and arguments were unchanged and move on.
	return equal(x, x1) && equal(y, y1) && equal(v, v1)
	} else if out != v {
	return false
	}

	// Test aliasing the first argument and the receiver.
	v1.Set(x)
	if out := f(v1, v1, y); out != v1 \|\| !equal(v1, v) {
	t.Logf("f(v, x, y) != f(x, x, y)")
	return false
	}
	// Test aliasing the second argument and the receiver.
	v1.Set(y)
	if out := f(v1, x, v1); out != v1 \|\| !equal(v1, v) {
	t.Logf("f(v, x, y) != f(y, x, y)")
	return false
	}

	// Calculate a reference f(y, y) without aliasing.
	// We use y because it's the one that commonly has restrictions
	// like being prime or non-zero.
	v1.Set(v)
	y2 := new(big.Int).Set(y)
	if out := f(v, y, y2); out == nil {
	return equal(y, y1) && equal(y2, y1) && equal(v, v1)
	} else if out != v {
	return false
	}

	// Test aliasing the two arguments.
	if out := f(v1, y, y); out != v1 \|\| !equal(v1, v) {
	t.Logf("f(v, y1, y2) != f(v, y, y)")
	return false
	}
	// Test aliasing the two arguments and the receiver.
	v1.Set(y)
	if out := f(v1, v1, v1); out != v1 \|\| !equal(v1, v) {
	t.Logf("f(v, y1, y2) != f(y, y, y)")
	return false
	}

	// Ensure the arguments were not modified.
	return equal(x, x1) && equal(y, y1)
	}

	func TestAliasing(t *testing.T) {
	for name, f := range map[string]interface{}{
	"Abs": func(v, x bigInt) bool {
	return checkAliasingOneArg(t, (*big.Int).Abs, v.Int, x.Int)
	},
	"Add": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Add, v.Int, x.Int, y.Int)
	},
	"And": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).And, v.Int, x.Int, y.Int)
	},
	"AndNot": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).AndNot, v.Int, x.Int, y.Int)
	},
	"Div": func(v, x bigInt, y notZeroInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Div, v.Int, x.Int, y.Int)
	},
	"Exp-XY": func(v, x, y bigInt, z notZeroInt) bool {
	return checkAliasingTwoArgs(t, func(v, x, y big.Int) big.Int {
	return v.Exp(x, y, z.Int)
	}, v.Int, x.Int, y.Int)
	},
	"Exp-XZ": func(v, x, y bigInt, z notZeroInt) bool {
	return checkAliasingTwoArgs(t, func(v, x, z big.Int) big.Int {
	return v.Exp(x, y.Int, z)
	}, v.Int, x.Int, z.Int)
	},
	"Exp-YZ": func(v, x, y bigInt, z notZeroInt) bool {
	return checkAliasingTwoArgs(t, func(v, y, z big.Int) big.Int {
	return v.Exp(x.Int, y, z)
	}, v.Int, y.Int, z.Int)
	},
	"GCD": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, func(v, x, y big.Int) big.Int {
	return v.GCD(nil, nil, x, y)
	}, v.Int, x.Int, y.Int)
	},
	"GCD-X": func(v, x, y bigInt) bool {
	a, b := new(big.Int), new(big.Int)
	return checkAliasingTwoArgs(t, func(v, x, y big.Int) big.Int {
	a.GCD(v, b, x, y)
	return v
	}, v.Int, x.Int, y.Int)
	},
	"GCD-Y": func(v, x, y bigInt) bool {
	a, b := new(big.Int), new(big.Int)
	return checkAliasingTwoArgs(t, func(v, x, y big.Int) big.Int {
	a.GCD(b, v, x, y)
	return v
	}, v.Int, x.Int, y.Int)
	},
	"Lsh": func(v, x bigInt, n smallUint) bool {
	return checkAliasingOneArg(t, func(v, x big.Int) big.Int {
	return v.Lsh(x, n.uint)
	}, v.Int, x.Int)
	},
	"Mod": func(v, x bigInt, y notZeroInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Mod, v.Int, x.Int, y.Int)
	},
	"ModInverse": func(v, x bigInt, y notZeroInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).ModInverse, v.Int, x.Int, y.Int)
	},
	"ModSqrt": func(v, x bigInt, p prime) bool {
	return checkAliasingTwoArgs(t, (*big.Int).ModSqrt, v.Int, x.Int, p.Int)
	},
	"Mul": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Mul, v.Int, x.Int, y.Int)
	},
	"Neg": func(v, x bigInt) bool {
	return checkAliasingOneArg(t, (*big.Int).Neg, v.Int, x.Int)
	},
	"Not": func(v, x bigInt) bool {
	return checkAliasingOneArg(t, (*big.Int).Not, v.Int, x.Int)
	},
	"Or": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Or, v.Int, x.Int, y.Int)
	},
	"Quo": func(v, x bigInt, y notZeroInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Quo, v.Int, x.Int, y.Int)
	},
	"Rand": func(v, x bigInt, seed int64) bool {
	return checkAliasingOneArg(t, func(v, x big.Int) big.Int {
	rnd := rand.New(rand.NewSource(seed))
	return v.Rand(rnd, x)
	}, v.Int, x.Int)
	},
	"Rem": func(v, x bigInt, y notZeroInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Rem, v.Int, x.Int, y.Int)
	},
	"Rsh": func(v, x bigInt, n smallUint) bool {
	return checkAliasingOneArg(t, func(v, x big.Int) big.Int {
	return v.Rsh(x, n.uint)
	}, v.Int, x.Int)
	},
	"Set": func(v, x bigInt) bool {
	return checkAliasingOneArg(t, (*big.Int).Set, v.Int, x.Int)
	},
	"SetBit": func(v, x bigInt, i smallUint, b zeroOrOne) bool {
	return checkAliasingOneArg(t, func(v, x big.Int) big.Int {
	return v.SetBit(x, int(i.uint), b.uint)
	}, v.Int, x.Int)
	},
	"Sqrt": func(v bigInt, x positiveInt) bool {
	return checkAliasingOneArg(t, (*big.Int).Sqrt, v.Int, x.Int)
	},
	"Sub": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Sub, v.Int, x.Int, y.Int)
	},
	"Xor": func(v, x, y bigInt) bool {
	return checkAliasingTwoArgs(t, (*big.Int).Xor, v.Int, x.Int, y.Int)
	},
	} {
	t.Run(name, func(t *testing.T) {
	scale := 1.0
	switch name {
	case "ModInverse", "GCD-Y", "GCD-X":
	scale /= 5
	case "Rand":
	scale /= 10
	case "Exp-XZ", "Exp-XY", "Exp-YZ":
	scale /= 50
	case "ModSqrt":
	scale /= 500
	}
	if err := quick.Check(f, &quick.Config{
	MaxCountScale: scale,
	}); err != nil {
	t.Error(err)
	}
	})
	}
	}