Official Go implementation of the Ethereum protocol
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go-ethereum/crypto/bls12381/fp_test.go

1413 lines
30 KiB

core/vm, crypto/bls12381, params: add bls12-381 elliptic curve precompiles (#21018) * crypto: add bls12-381 elliptic curve wrapper * params: add bls12-381 precompile gas parameters * core/vm: add bls12-381 precompiles * core/vm: add bls12-381 precompile tests * go.mod, go.sum: use latest bls12381 lib * core/vm: move point encode/decode functions to base library * crypto/bls12381: introduce bls12-381 library init function * crypto/bls12381: import bls12381 elliptic curve implementation * go.mod, go.sum: remove bls12-381 library * remove unsued frobenious coeffs supress warning for inp that used in asm * add mappings tests for zero inputs fix swu g2 minus z inverse constant * crypto/bls12381: fix typo * crypto/bls12381: better comments for bls12381 constants * crypto/bls12381: swu, use single conditional for e2 * crypto/bls12381: utils, delete empty line * crypto/bls12381: utils, use FromHex for string to big * crypto/bls12381: g1, g2, strict length check for FromBytes * crypto/bls12381: field_element, comparision changes * crypto/bls12381: change swu, isogeny constants with hex values * core/vm: fix point multiplication comments * core/vm: fix multiexp gas calculation and lookup for g1 and g2 * core/vm: simpler imput length check for multiexp and pairing precompiles * core/vm: rm empty multiexp result declarations * crypto/bls12381: remove modulus type definition * crypto/bls12381: use proper init function * crypto/bls12381: get rid of new lines at fatal desciprtions * crypto/bls12-381: fix no-adx assembly multiplication * crypto/bls12-381: remove old config function * crypto/bls12381: update multiplication backend this commit changes mul backend to 6limb eip1962 backend mul assign operations are dropped * core/vm/contracts_tests: externalize test vectors for precompiles * core/vm/contracts_test: externalize failure-cases for precompiles * core/vm: linting * go.mod: tiny up sum file * core/vm: fix goimports linter issues * crypto/bls12381: build tags for plain ASM or ADX implementation Co-authored-by: Martin Holst Swende <martin@swende.se> Co-authored-by: Péter Szilágyi <peterke@gmail.com>
5 years ago
package bls12381
import (
"bytes"
"crypto/rand"
"math/big"
"testing"
)
func TestFpSerialization(t *testing.T) {
t.Run("zero", func(t *testing.T) {
in := make([]byte, 48)
fe, err := fromBytes(in)
if err != nil {
t.Fatal(err)
}
if !fe.isZero() {
t.Fatal("bad serialization")
}
if !bytes.Equal(in, toBytes(fe)) {
t.Fatal("bad serialization")
}
})
t.Run("bytes", func(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, err := fromBytes(toBytes(a))
if err != nil {
t.Fatal(err)
}
if !a.equal(b) {
t.Fatal("bad serialization")
}
}
})
t.Run("string", func(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, err := fromString(toString(a))
if err != nil {
t.Fatal(err)
}
if !a.equal(b) {
t.Fatal("bad encoding or decoding")
}
}
})
t.Run("big", func(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, err := fromBig(toBig(a))
if err != nil {
t.Fatal(err)
}
if !a.equal(b) {
t.Fatal("bad encoding or decoding")
}
}
})
}
func TestFpAdditionCrossAgainstBigInt(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
c := new(fe)
big_a := toBig(a)
big_b := toBig(b)
big_c := new(big.Int)
add(c, a, b)
out_1 := toBytes(c)
out_2 := padBytes(big_c.Add(big_a, big_b).Mod(big_c, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied A")
}
double(c, a)
out_1 = toBytes(c)
out_2 = padBytes(big_c.Add(big_a, big_a).Mod(big_c, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied B")
}
sub(c, a, b)
out_1 = toBytes(c)
out_2 = padBytes(big_c.Sub(big_a, big_b).Mod(big_c, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied C")
}
neg(c, a)
out_1 = toBytes(c)
out_2 = padBytes(big_c.Neg(big_a).Mod(big_c, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied D")
}
}
}
func TestFpAdditionCrossAgainstBigIntAssigned(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
big_a, big_b := toBig(a), toBig(b)
addAssign(a, b)
out_1 := toBytes(a)
out_2 := padBytes(big_a.Add(big_a, big_b).Mod(big_a, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied A")
}
a, _ = new(fe).rand(rand.Reader)
big_a = toBig(a)
doubleAssign(a)
out_1 = toBytes(a)
out_2 = padBytes(big_a.Add(big_a, big_a).Mod(big_a, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied B")
}
a, _ = new(fe).rand(rand.Reader)
b, _ = new(fe).rand(rand.Reader)
big_a, big_b = toBig(a), toBig(b)
subAssign(a, b)
out_1 = toBytes(a)
out_2 = padBytes(big_a.Sub(big_a, big_b).Mod(big_a, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied A")
}
}
}
func TestFpAdditionProperties(t *testing.T) {
for i := 0; i < fuz; i++ {
zero := new(fe).zero()
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
c_1, c_2 := new(fe), new(fe)
add(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a + 0 == a")
}
sub(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a - 0 == a")
}
double(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("2 * 0 == 0")
}
neg(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("-0 == 0")
}
sub(c_1, zero, a)
neg(c_2, a)
if !c_1.equal(c_2) {
t.Fatal("0-a == -a")
}
double(c_1, a)
add(c_2, a, a)
if !c_1.equal(c_2) {
t.Fatal("2 * a == a + a")
}
add(c_1, a, b)
add(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a + b = b + a")
}
sub(c_1, a, b)
sub(c_2, b, a)
neg(c_2, c_2)
if !c_1.equal(c_2) {
t.Fatal("a - b = - ( b - a )")
}
c_x, _ := new(fe).rand(rand.Reader)
add(c_1, a, b)
add(c_1, c_1, c_x)
add(c_2, a, c_x)
add(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a + b) + c == (a + c ) + b")
}
sub(c_1, a, b)
sub(c_1, c_1, c_x)
sub(c_2, a, c_x)
sub(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a - b) - c == (a - c ) -b")
}
}
}
func TestFpAdditionPropertiesAssigned(t *testing.T) {
for i := 0; i < fuz; i++ {
zero := new(fe).zero()
a, b := new(fe), new(fe)
_, _ = a.rand(rand.Reader)
b.set(a)
addAssign(a, zero)
if !a.equal(b) {
t.Fatal("a + 0 == a")
}
subAssign(a, zero)
if !a.equal(b) {
t.Fatal("a - 0 == a")
}
a.set(zero)
doubleAssign(a)
if !a.equal(zero) {
t.Fatal("2 * 0 == 0")
}
a.set(zero)
subAssign(a, b)
neg(b, b)
if !a.equal(b) {
t.Fatal("0-a == -a")
}
_, _ = a.rand(rand.Reader)
b.set(a)
doubleAssign(a)
addAssign(b, b)
if !a.equal(b) {
t.Fatal("2 * a == a + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c_1, c_2 := new(fe).set(a), new(fe).set(b)
addAssign(c_1, b)
addAssign(c_2, a)
if !c_1.equal(c_2) {
t.Fatal("a + b = b + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c_1.set(a)
c_2.set(b)
subAssign(c_1, b)
subAssign(c_2, a)
neg(c_2, c_2)
if !c_1.equal(c_2) {
t.Fatal("a - b = - ( b - a )")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c, _ := new(fe).rand(rand.Reader)
a0 := new(fe).set(a)
addAssign(a, b)
addAssign(a, c)
addAssign(b, c)
addAssign(b, a0)
if !a.equal(b) {
t.Fatal("(a + b) + c == (b + c) + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
_, _ = c.rand(rand.Reader)
a0.set(a)
subAssign(a, b)
subAssign(a, c)
subAssign(a0, c)
subAssign(a0, b)
if !a.equal(a0) {
t.Fatal("(a - b) - c == (a - c) -b")
}
}
}
func TestFpLazyOperations(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
c, _ := new(fe).rand(rand.Reader)
c0 := new(fe)
c1 := new(fe)
ladd(c0, a, b)
add(c1, a, b)
mul(c0, c0, c)
mul(c1, c1, c)
if !c0.equal(c1) {
// l+ operator stands for lazy addition
t.Fatal("(a + b) * c == (a l+ b) * c")
}
_, _ = a.rand(rand.Reader)
b.set(a)
ldouble(a, a)
ladd(b, b, b)
if !a.equal(b) {
t.Fatal("2 l* a = a l+ a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
_, _ = c.rand(rand.Reader)
a0 := new(fe).set(a)
lsubAssign(a, b)
laddAssign(a, &modulus)
mul(a, a, c)
subAssign(a0, b)
mul(a0, a0, c)
if !a.equal(a0) {
t.Fatal("((a l- b) + p) * c = (a-b) * c")
}
}
}
func TestFpMultiplicationCrossAgainstBigInt(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
c := new(fe)
big_a := toBig(a)
big_b := toBig(b)
big_c := new(big.Int)
mul(c, a, b)
out_1 := toBytes(c)
out_2 := padBytes(big_c.Mul(big_a, big_b).Mod(big_c, modulus.big()).Bytes(), 48)
if !bytes.Equal(out_1, out_2) {
t.Fatal("cross test against big.Int is not satisfied")
}
}
}
func TestFpMultiplicationProperties(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
zero, one := new(fe).zero(), new(fe).one()
c_1, c_2 := new(fe), new(fe)
mul(c_1, a, zero)
if !c_1.equal(zero) {
t.Fatal("a * 0 == 0")
}
mul(c_1, a, one)
if !c_1.equal(a) {
t.Fatal("a * 1 == a")
}
mul(c_1, a, b)
mul(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a * b == b * a")
}
c_x, _ := new(fe).rand(rand.Reader)
mul(c_1, a, b)
mul(c_1, c_1, c_x)
mul(c_2, c_x, b)
mul(c_2, c_2, a)
if !c_1.equal(c_2) {
t.Fatal("(a * b) * c == (a * c) * b")
}
square(a, zero)
if !a.equal(zero) {
t.Fatal("0^2 == 0")
}
square(a, one)
if !a.equal(one) {
t.Fatal("1^2 == 1")
}
_, _ = a.rand(rand.Reader)
square(c_1, a)
mul(c_2, a, a)
if !c_1.equal(c_1) {
t.Fatal("a^2 == a*a")
}
}
}
func TestFpExponentiation(t *testing.T) {
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
u := new(fe)
exp(u, a, big.NewInt(0))
if !u.isOne() {
t.Fatal("a^0 == 1")
}
exp(u, a, big.NewInt(1))
if !u.equal(a) {
t.Fatal("a^1 == a")
}
v := new(fe)
mul(u, a, a)
mul(u, u, u)
mul(u, u, u)
exp(v, a, big.NewInt(8))
if !u.equal(v) {
t.Fatal("((a^2)^2)^2 == a^8")
}
p := modulus.big()
exp(u, a, p)
if !u.equal(a) {
t.Fatal("a^p == a")
}
exp(u, a, p.Sub(p, big.NewInt(1)))
if !u.isOne() {
t.Fatal("a^(p-1) == 1")
}
}
}
func TestFpInversion(t *testing.T) {
for i := 0; i < fuz; i++ {
u := new(fe)
zero, one := new(fe).zero(), new(fe).one()
inverse(u, zero)
if !u.equal(zero) {
t.Fatal("(0^-1) == 0)")
}
inverse(u, one)
if !u.equal(one) {
t.Fatal("(1^-1) == 1)")
}
a, _ := new(fe).rand(rand.Reader)
inverse(u, a)
mul(u, u, a)
if !u.equal(one) {
t.Fatal("(r*a) * r*(a^-1) == r)")
}
v := new(fe)
p := modulus.big()
exp(u, a, p.Sub(p, big.NewInt(2)))
inverse(v, a)
if !v.equal(u) {
t.Fatal("a^(p-2) == a^-1")
}
}
}
func TestFpSquareRoot(t *testing.T) {
r := new(fe)
if sqrt(r, nonResidue1) {
t.Fatal("non residue cannot have a sqrt")
}
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
aa, rr, r := &fe{}, &fe{}, &fe{}
square(aa, a)
if !sqrt(r, aa) {
t.Fatal("bad sqrt 1")
}
square(rr, r)
if !rr.equal(aa) {
t.Fatal("bad sqrt 2")
}
}
}
func TestFpNonResidue(t *testing.T) {
if !isQuadraticNonResidue(nonResidue1) {
t.Fatal("element is quadratic non residue, 1")
}
if isQuadraticNonResidue(new(fe).one()) {
t.Fatal("one is not quadratic non residue")
}
if !isQuadraticNonResidue(new(fe).zero()) {
t.Fatal("should accept zero as quadratic non residue")
}
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
square(a, a)
if isQuadraticNonResidue(new(fe).one()) {
t.Fatal("element is not quadratic non residue")
}
}
for i := 0; i < fuz; i++ {
a, _ := new(fe).rand(rand.Reader)
if !sqrt(new(fe), a) {
if !isQuadraticNonResidue(a) {
t.Fatal("element is quadratic non residue, 2", i)
}
} else {
i -= 1
}
}
}
func TestFp2Serialization(t *testing.T) {
field := newFp2()
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
b, err := field.fromBytes(field.toBytes(a))
if err != nil {
t.Fatal(err)
}
if !a.equal(b) {
t.Fatal("bad serialization")
}
}
}
func TestFp2AdditionProperties(t *testing.T) {
field := newFp2()
for i := 0; i < fuz; i++ {
zero := field.zero()
a, _ := new(fe2).rand(rand.Reader)
b, _ := new(fe2).rand(rand.Reader)
c_1 := field.new()
c_2 := field.new()
field.add(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a + 0 == a")
}
field.sub(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a - 0 == a")
}
field.double(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("2 * 0 == 0")
}
field.neg(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("-0 == 0")
}
field.sub(c_1, zero, a)
field.neg(c_2, a)
if !c_1.equal(c_2) {
t.Fatal("0-a == -a")
}
field.double(c_1, a)
field.add(c_2, a, a)
if !c_1.equal(c_2) {
t.Fatal("2 * a == a + a")
}
field.add(c_1, a, b)
field.add(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a + b = b + a")
}
field.sub(c_1, a, b)
field.sub(c_2, b, a)
field.neg(c_2, c_2)
if !c_1.equal(c_2) {
t.Fatal("a - b = - ( b - a )")
}
c_x, _ := new(fe2).rand(rand.Reader)
field.add(c_1, a, b)
field.add(c_1, c_1, c_x)
field.add(c_2, a, c_x)
field.add(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a + b) + c == (a + c ) + b")
}
field.sub(c_1, a, b)
field.sub(c_1, c_1, c_x)
field.sub(c_2, a, c_x)
field.sub(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a - b) - c == (a - c ) -b")
}
}
}
func TestFp2AdditionPropertiesAssigned(t *testing.T) {
field := newFp2()
for i := 0; i < fuz; i++ {
zero := new(fe2).zero()
a, b := new(fe2), new(fe2)
_, _ = a.rand(rand.Reader)
b.set(a)
field.addAssign(a, zero)
if !a.equal(b) {
t.Fatal("a + 0 == a")
}
field.subAssign(a, zero)
if !a.equal(b) {
t.Fatal("a - 0 == a")
}
a.set(zero)
field.doubleAssign(a)
if !a.equal(zero) {
t.Fatal("2 * 0 == 0")
}
a.set(zero)
field.subAssign(a, b)
field.neg(b, b)
if !a.equal(b) {
t.Fatal("0-a == -a")
}
_, _ = a.rand(rand.Reader)
b.set(a)
field.doubleAssign(a)
field.addAssign(b, b)
if !a.equal(b) {
t.Fatal("2 * a == a + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c_1, c_2 := new(fe2).set(a), new(fe2).set(b)
field.addAssign(c_1, b)
field.addAssign(c_2, a)
if !c_1.equal(c_2) {
t.Fatal("a + b = b + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c_1.set(a)
c_2.set(b)
field.subAssign(c_1, b)
field.subAssign(c_2, a)
field.neg(c_2, c_2)
if !c_1.equal(c_2) {
t.Fatal("a - b = - ( b - a )")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c, _ := new(fe2).rand(rand.Reader)
a0 := new(fe2).set(a)
field.addAssign(a, b)
field.addAssign(a, c)
field.addAssign(b, c)
field.addAssign(b, a0)
if !a.equal(b) {
t.Fatal("(a + b) + c == (b + c) + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
_, _ = c.rand(rand.Reader)
a0.set(a)
field.subAssign(a, b)
field.subAssign(a, c)
field.subAssign(a0, c)
field.subAssign(a0, b)
if !a.equal(a0) {
t.Fatal("(a - b) - c == (a - c) -b")
}
}
}
func TestFp2LazyOperations(t *testing.T) {
field := newFp2()
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
b, _ := new(fe2).rand(rand.Reader)
c, _ := new(fe2).rand(rand.Reader)
c0 := new(fe2)
c1 := new(fe2)
field.ladd(c0, a, b)
field.add(c1, a, b)
field.mulAssign(c0, c)
field.mulAssign(c1, c)
if !c0.equal(c1) {
// l+ operator stands for lazy addition
t.Fatal("(a + b) * c == (a l+ b) * c")
}
_, _ = a.rand(rand.Reader)
b.set(a)
field.ldouble(a, a)
field.ladd(b, b, b)
if !a.equal(b) {
t.Fatal("2 l* a = a l+ a")
}
}
}
func TestFp2MultiplicationProperties(t *testing.T) {
field := newFp2()
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
b, _ := new(fe2).rand(rand.Reader)
zero := field.zero()
one := field.one()
c_1, c_2 := field.new(), field.new()
field.mul(c_1, a, zero)
if !c_1.equal(zero) {
t.Fatal("a * 0 == 0")
}
field.mul(c_1, a, one)
if !c_1.equal(a) {
t.Fatal("a * 1 == a")
}
field.mul(c_1, a, b)
field.mul(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a * b == b * a")
}
c_x, _ := new(fe2).rand(rand.Reader)
field.mul(c_1, a, b)
field.mul(c_1, c_1, c_x)
field.mul(c_2, c_x, b)
field.mul(c_2, c_2, a)
if !c_1.equal(c_2) {
t.Fatal("(a * b) * c == (a * c) * b")
}
field.square(a, zero)
if !a.equal(zero) {
t.Fatal("0^2 == 0")
}
field.square(a, one)
if !a.equal(one) {
t.Fatal("1^2 == 1")
}
_, _ = a.rand(rand.Reader)
field.square(c_1, a)
field.mul(c_2, a, a)
if !c_2.equal(c_1) {
t.Fatal("a^2 == a*a")
}
}
}
func TestFp2MultiplicationPropertiesAssigned(t *testing.T) {
field := newFp2()
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
zero, one := new(fe2).zero(), new(fe2).one()
field.mulAssign(a, zero)
if !a.equal(zero) {
t.Fatal("a * 0 == 0")
}
_, _ = a.rand(rand.Reader)
a0 := new(fe2).set(a)
field.mulAssign(a, one)
if !a.equal(a0) {
t.Fatal("a * 1 == a")
}
_, _ = a.rand(rand.Reader)
b, _ := new(fe2).rand(rand.Reader)
a0.set(a)
field.mulAssign(a, b)
field.mulAssign(b, a0)
if !a.equal(b) {
t.Fatal("a * b == b * a")
}
c, _ := new(fe2).rand(rand.Reader)
a0.set(a)
field.mulAssign(a, b)
field.mulAssign(a, c)
field.mulAssign(a0, c)
field.mulAssign(a0, b)
if !a.equal(a0) {
t.Fatal("(a * b) * c == (a * c) * b")
}
a0.set(a)
field.squareAssign(a)
field.mulAssign(a0, a0)
if !a.equal(a0) {
t.Fatal("a^2 == a*a")
}
}
}
func TestFp2Exponentiation(t *testing.T) {
field := newFp2()
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
u := field.new()
field.exp(u, a, big.NewInt(0))
if !u.equal(field.one()) {
t.Fatal("a^0 == 1")
}
field.exp(u, a, big.NewInt(1))
if !u.equal(a) {
t.Fatal("a^1 == a")
}
v := field.new()
field.mul(u, a, a)
field.mul(u, u, u)
field.mul(u, u, u)
field.exp(v, a, big.NewInt(8))
if !u.equal(v) {
t.Fatal("((a^2)^2)^2 == a^8")
}
}
}
func TestFp2Inversion(t *testing.T) {
field := newFp2()
u := field.new()
zero := field.zero()
one := field.one()
field.inverse(u, zero)
if !u.equal(zero) {
t.Fatal("(0 ^ -1) == 0)")
}
field.inverse(u, one)
if !u.equal(one) {
t.Fatal("(1 ^ -1) == 1)")
}
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
field.inverse(u, a)
field.mul(u, u, a)
if !u.equal(one) {
t.Fatal("(r * a) * r * (a ^ -1) == r)")
}
}
}
func TestFp2SquareRoot(t *testing.T) {
field := newFp2()
for z := 0; z < 1000; z++ {
zi := new(fe)
sub(zi, &modulus, &fe{uint64(z * z)})
// r = (-z*z, 0)
r := &fe2{*zi, fe{0}}
toMont(&r[0], &r[0])
toMont(&r[1], &r[1])
c := field.new()
// sqrt((-z*z, 0)) = (0, z)
if !field.sqrt(c, r) {
t.Fatal("z*z does have a square root")
}
e := &fe2{fe{uint64(0)}, fe{uint64(z)}}
toMont(&e[0], &e[0])
toMont(&e[1], &e[1])
field.square(e, e)
field.square(c, c)
if !e.equal(c) {
t.Fatal("square root failed")
}
}
if field.sqrt(field.new(), nonResidue2) {
t.Fatal("non residue cannot have a sqrt")
}
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
aa, rr, r := field.new(), field.new(), field.new()
field.square(aa, a)
if !field.sqrt(r, aa) {
t.Fatal("bad sqrt 1")
}
field.square(rr, r)
if !rr.equal(aa) {
t.Fatal("bad sqrt 2")
}
}
}
func TestFp2NonResidue(t *testing.T) {
field := newFp2()
if !field.isQuadraticNonResidue(nonResidue2) {
t.Fatal("element is quadratic non residue, 1")
}
if field.isQuadraticNonResidue(new(fe2).one()) {
t.Fatal("one is not quadratic non residue")
}
if !field.isQuadraticNonResidue(new(fe2).zero()) {
t.Fatal("should accept zero as quadratic non residue")
}
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
field.squareAssign(a)
if field.isQuadraticNonResidue(new(fe2).one()) {
t.Fatal("element is not quadratic non residue")
}
}
for i := 0; i < fuz; i++ {
a, _ := new(fe2).rand(rand.Reader)
if !field.sqrt(new(fe2), a) {
if !field.isQuadraticNonResidue(a) {
t.Fatal("element is quadratic non residue, 2", i)
}
} else {
i -= 1
}
}
}
func TestFp6Serialization(t *testing.T) {
field := newFp6(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe6).rand(rand.Reader)
b, err := field.fromBytes(field.toBytes(a))
if err != nil {
t.Fatal(err)
}
if !a.equal(b) {
t.Fatal("bad serialization")
}
}
}
func TestFp6AdditionProperties(t *testing.T) {
field := newFp6(nil)
for i := 0; i < fuz; i++ {
zero := field.zero()
a, _ := new(fe6).rand(rand.Reader)
b, _ := new(fe6).rand(rand.Reader)
c_1 := field.new()
c_2 := field.new()
field.add(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a + 0 == a")
}
field.sub(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a - 0 == a")
}
field.double(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("2 * 0 == 0")
}
field.neg(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("-0 == 0")
}
field.sub(c_1, zero, a)
field.neg(c_2, a)
if !c_1.equal(c_2) {
t.Fatal("0-a == -a")
}
field.double(c_1, a)
field.add(c_2, a, a)
if !c_1.equal(c_2) {
t.Fatal("2 * a == a + a")
}
field.add(c_1, a, b)
field.add(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a + b = b + a")
}
field.sub(c_1, a, b)
field.sub(c_2, b, a)
field.neg(c_2, c_2)
if !c_1.equal(c_2) {
t.Fatal("a - b = - ( b - a )")
}
c_x, _ := new(fe6).rand(rand.Reader)
field.add(c_1, a, b)
field.add(c_1, c_1, c_x)
field.add(c_2, a, c_x)
field.add(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a + b) + c == (a + c ) + b")
}
field.sub(c_1, a, b)
field.sub(c_1, c_1, c_x)
field.sub(c_2, a, c_x)
field.sub(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a - b) - c == (a - c ) -b")
}
}
}
func TestFp6AdditionPropertiesAssigned(t *testing.T) {
field := newFp6(nil)
for i := 0; i < fuz; i++ {
zero := new(fe6).zero()
a, b := new(fe6), new(fe6)
_, _ = a.rand(rand.Reader)
b.set(a)
field.addAssign(a, zero)
if !a.equal(b) {
t.Fatal("a + 0 == a")
}
field.subAssign(a, zero)
if !a.equal(b) {
t.Fatal("a - 0 == a")
}
a.set(zero)
field.doubleAssign(a)
if !a.equal(zero) {
t.Fatal("2 * 0 == 0")
}
a.set(zero)
field.subAssign(a, b)
field.neg(b, b)
if !a.equal(b) {
t.Fatal("0-a == -a")
}
_, _ = a.rand(rand.Reader)
b.set(a)
field.doubleAssign(a)
field.addAssign(b, b)
if !a.equal(b) {
t.Fatal("2 * a == a + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c_1, c_2 := new(fe6).set(a), new(fe6).set(b)
field.addAssign(c_1, b)
field.addAssign(c_2, a)
if !c_1.equal(c_2) {
t.Fatal("a + b = b + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c_1.set(a)
c_2.set(b)
field.subAssign(c_1, b)
field.subAssign(c_2, a)
field.neg(c_2, c_2)
if !c_1.equal(c_2) {
t.Fatal("a - b = - ( b - a )")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
c, _ := new(fe6).rand(rand.Reader)
a0 := new(fe6).set(a)
field.addAssign(a, b)
field.addAssign(a, c)
field.addAssign(b, c)
field.addAssign(b, a0)
if !a.equal(b) {
t.Fatal("(a + b) + c == (b + c) + a")
}
_, _ = a.rand(rand.Reader)
_, _ = b.rand(rand.Reader)
_, _ = c.rand(rand.Reader)
a0.set(a)
field.subAssign(a, b)
field.subAssign(a, c)
field.subAssign(a0, c)
field.subAssign(a0, b)
if !a.equal(a0) {
t.Fatal("(a - b) - c == (a - c) -b")
}
}
}
func TestFp6SparseMultiplication(t *testing.T) {
fp6 := newFp6(nil)
var a, b, u *fe6
for j := 0; j < fuz; j++ {
a, _ = new(fe6).rand(rand.Reader)
b, _ = new(fe6).rand(rand.Reader)
u, _ = new(fe6).rand(rand.Reader)
b[2].zero()
fp6.mul(u, a, b)
fp6.mulBy01(a, a, &b[0], &b[1])
if !a.equal(u) {
t.Fatal("bad mul by 01")
}
}
for j := 0; j < fuz; j++ {
a, _ = new(fe6).rand(rand.Reader)
b, _ = new(fe6).rand(rand.Reader)
u, _ = new(fe6).rand(rand.Reader)
b[2].zero()
b[0].zero()
fp6.mul(u, a, b)
fp6.mulBy1(a, a, &b[1])
if !a.equal(u) {
t.Fatal("bad mul by 1")
}
}
}
func TestFp6MultiplicationProperties(t *testing.T) {
field := newFp6(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe6).rand(rand.Reader)
b, _ := new(fe6).rand(rand.Reader)
zero := field.zero()
one := field.one()
c_1, c_2 := field.new(), field.new()
field.mul(c_1, a, zero)
if !c_1.equal(zero) {
t.Fatal("a * 0 == 0")
}
field.mul(c_1, a, one)
if !c_1.equal(a) {
t.Fatal("a * 1 == a")
}
field.mul(c_1, a, b)
field.mul(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a * b == b * a")
}
c_x, _ := new(fe6).rand(rand.Reader)
field.mul(c_1, a, b)
field.mul(c_1, c_1, c_x)
field.mul(c_2, c_x, b)
field.mul(c_2, c_2, a)
if !c_1.equal(c_2) {
t.Fatal("(a * b) * c == (a * c) * b")
}
field.square(a, zero)
if !a.equal(zero) {
t.Fatal("0^2 == 0")
}
field.square(a, one)
if !a.equal(one) {
t.Fatal("1^2 == 1")
}
_, _ = a.rand(rand.Reader)
field.square(c_1, a)
field.mul(c_2, a, a)
if !c_2.equal(c_1) {
t.Fatal("a^2 == a*a")
}
}
}
func TestFp6MultiplicationPropertiesAssigned(t *testing.T) {
field := newFp6(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe6).rand(rand.Reader)
zero, one := new(fe6).zero(), new(fe6).one()
field.mulAssign(a, zero)
if !a.equal(zero) {
t.Fatal("a * 0 == 0")
}
_, _ = a.rand(rand.Reader)
a0 := new(fe6).set(a)
field.mulAssign(a, one)
if !a.equal(a0) {
t.Fatal("a * 1 == a")
}
_, _ = a.rand(rand.Reader)
b, _ := new(fe6).rand(rand.Reader)
a0.set(a)
field.mulAssign(a, b)
field.mulAssign(b, a0)
if !a.equal(b) {
t.Fatal("a * b == b * a")
}
c, _ := new(fe6).rand(rand.Reader)
a0.set(a)
field.mulAssign(a, b)
field.mulAssign(a, c)
field.mulAssign(a0, c)
field.mulAssign(a0, b)
if !a.equal(a0) {
t.Fatal("(a * b) * c == (a * c) * b")
}
}
}
func TestFp6Exponentiation(t *testing.T) {
field := newFp6(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe6).rand(rand.Reader)
u := field.new()
field.exp(u, a, big.NewInt(0))
if !u.equal(field.one()) {
t.Fatal("a^0 == 1")
}
field.exp(u, a, big.NewInt(1))
if !u.equal(a) {
t.Fatal("a^1 == a")
}
v := field.new()
field.mul(u, a, a)
field.mul(u, u, u)
field.mul(u, u, u)
field.exp(v, a, big.NewInt(8))
if !u.equal(v) {
t.Fatal("((a^2)^2)^2 == a^8")
}
}
}
func TestFp6Inversion(t *testing.T) {
field := newFp6(nil)
for i := 0; i < fuz; i++ {
u := field.new()
zero := field.zero()
one := field.one()
field.inverse(u, zero)
if !u.equal(zero) {
t.Fatal("(0^-1) == 0)")
}
field.inverse(u, one)
if !u.equal(one) {
t.Fatal("(1^-1) == 1)")
}
a, _ := new(fe6).rand(rand.Reader)
field.inverse(u, a)
field.mul(u, u, a)
if !u.equal(one) {
t.Fatal("(r*a) * r*(a^-1) == r)")
}
}
}
func TestFp12Serialization(t *testing.T) {
field := newFp12(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe12).rand(rand.Reader)
b, err := field.fromBytes(field.toBytes(a))
if err != nil {
t.Fatal(err)
}
if !a.equal(b) {
t.Fatal("bad serialization")
}
}
}
func TestFp12AdditionProperties(t *testing.T) {
field := newFp12(nil)
for i := 0; i < fuz; i++ {
zero := field.zero()
a, _ := new(fe12).rand(rand.Reader)
b, _ := new(fe12).rand(rand.Reader)
c_1 := field.new()
c_2 := field.new()
field.add(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a + 0 == a")
}
field.sub(c_1, a, zero)
if !c_1.equal(a) {
t.Fatal("a - 0 == a")
}
field.double(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("2 * 0 == 0")
}
field.neg(c_1, zero)
if !c_1.equal(zero) {
t.Fatal("-0 == 0")
}
field.sub(c_1, zero, a)
field.neg(c_2, a)
if !c_1.equal(c_2) {
t.Fatal("0-a == -a")
}
field.double(c_1, a)
field.add(c_2, a, a)
if !c_1.equal(c_2) {
t.Fatal("2 * a == a + a")
}
field.add(c_1, a, b)
field.add(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a + b = b + a")
}
field.sub(c_1, a, b)
field.sub(c_2, b, a)
field.neg(c_2, c_2)
if !c_1.equal(c_2) {
t.Fatal("a - b = - ( b - a )")
}
c_x, _ := new(fe12).rand(rand.Reader)
field.add(c_1, a, b)
field.add(c_1, c_1, c_x)
field.add(c_2, a, c_x)
field.add(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a + b) + c == (a + c ) + b")
}
field.sub(c_1, a, b)
field.sub(c_1, c_1, c_x)
field.sub(c_2, a, c_x)
field.sub(c_2, c_2, b)
if !c_1.equal(c_2) {
t.Fatal("(a - b) - c == (a - c ) -b")
}
}
}
func TestFp12MultiplicationProperties(t *testing.T) {
field := newFp12(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe12).rand(rand.Reader)
b, _ := new(fe12).rand(rand.Reader)
zero := field.zero()
one := field.one()
c_1, c_2 := field.new(), field.new()
field.mul(c_1, a, zero)
if !c_1.equal(zero) {
t.Fatal("a * 0 == 0")
}
field.mul(c_1, a, one)
if !c_1.equal(a) {
t.Fatal("a * 1 == a")
}
field.mul(c_1, a, b)
field.mul(c_2, b, a)
if !c_1.equal(c_2) {
t.Fatal("a * b == b * a")
}
c_x, _ := new(fe12).rand(rand.Reader)
field.mul(c_1, a, b)
field.mul(c_1, c_1, c_x)
field.mul(c_2, c_x, b)
field.mul(c_2, c_2, a)
if !c_1.equal(c_2) {
t.Fatal("(a * b) * c == (a * c) * b")
}
field.square(a, zero)
if !a.equal(zero) {
t.Fatal("0^2 == 0")
}
field.square(a, one)
if !a.equal(one) {
t.Fatal("1^2 == 1")
}
_, _ = a.rand(rand.Reader)
field.square(c_1, a)
field.mul(c_2, a, a)
if !c_2.equal(c_1) {
t.Fatal("a^2 == a*a")
}
}
}
func TestFp12MultiplicationPropertiesAssigned(t *testing.T) {
field := newFp12(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe12).rand(rand.Reader)
zero, one := new(fe12).zero(), new(fe12).one()
field.mulAssign(a, zero)
if !a.equal(zero) {
t.Fatal("a * 0 == 0")
}
_, _ = a.rand(rand.Reader)
a0 := new(fe12).set(a)
field.mulAssign(a, one)
if !a.equal(a0) {
t.Fatal("a * 1 == a")
}
_, _ = a.rand(rand.Reader)
b, _ := new(fe12).rand(rand.Reader)
a0.set(a)
field.mulAssign(a, b)
field.mulAssign(b, a0)
if !a.equal(b) {
t.Fatal("a * b == b * a")
}
c, _ := new(fe12).rand(rand.Reader)
a0.set(a)
field.mulAssign(a, b)
field.mulAssign(a, c)
field.mulAssign(a0, c)
field.mulAssign(a0, b)
if !a.equal(a0) {
t.Fatal("(a * b) * c == (a * c) * b")
}
}
}
func TestFp12SparseMultiplication(t *testing.T) {
fp12 := newFp12(nil)
var a, b, u *fe12
for j := 0; j < fuz; j++ {
a, _ = new(fe12).rand(rand.Reader)
b, _ = new(fe12).rand(rand.Reader)
u, _ = new(fe12).rand(rand.Reader)
b[0][2].zero()
b[1][0].zero()
b[1][2].zero()
fp12.mul(u, a, b)
fp12.mulBy014Assign(a, &b[0][0], &b[0][1], &b[1][1])
if !a.equal(u) {
t.Fatal("bad mul by 01")
}
}
}
func TestFp12Exponentiation(t *testing.T) {
field := newFp12(nil)
for i := 0; i < fuz; i++ {
a, _ := new(fe12).rand(rand.Reader)
u := field.new()
field.exp(u, a, big.NewInt(0))
if !u.equal(field.one()) {
t.Fatal("a^0 == 1")
}
field.exp(u, a, big.NewInt(1))
if !u.equal(a) {
t.Fatal("a^1 == a")
}
v := field.new()
field.mul(u, a, a)
field.mul(u, u, u)
field.mul(u, u, u)
field.exp(v, a, big.NewInt(8))
if !u.equal(v) {
t.Fatal("((a^2)^2)^2 == a^8")
}
}
}
func TestFp12Inversion(t *testing.T) {
field := newFp12(nil)
for i := 0; i < fuz; i++ {
u := field.new()
zero := field.zero()
one := field.one()
field.inverse(u, zero)
if !u.equal(zero) {
t.Fatal("(0^-1) == 0)")
}
field.inverse(u, one)
if !u.equal(one) {
t.Fatal("(1^-1) == 1)")
}
a, _ := new(fe12).rand(rand.Reader)
field.inverse(u, a)
field.mul(u, u, a)
if !u.equal(one) {
t.Fatal("(r*a) * r*(a^-1) == r)")
}
}
}
func BenchmarkMultiplication(t *testing.B) {
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
c, _ := new(fe).rand(rand.Reader)
t.ResetTimer()
for i := 0; i < t.N; i++ {
mul(c, a, b)
}
}
func BenchmarkInverse(t *testing.B) {
a, _ := new(fe).rand(rand.Reader)
b, _ := new(fe).rand(rand.Reader)
t.ResetTimer()
for i := 0; i < t.N; i++ {
inverse(a, b)
}
}
core/vm, crypto/bls12381, params: add bls12-381 elliptic curve precompiles (#21018) * crypto: add bls12-381 elliptic curve wrapper * params: add bls12-381 precompile gas parameters * core/vm: add bls12-381 precompiles * core/vm: add bls12-381 precompile tests * go.mod, go.sum: use latest bls12381 lib * core/vm: move point encode/decode functions to base library * crypto/bls12381: introduce bls12-381 library init function * crypto/bls12381: import bls12381 elliptic curve implementation * go.mod, go.sum: remove bls12-381 library * remove unsued frobenious coeffs supress warning for inp that used in asm * add mappings tests for zero inputs fix swu g2 minus z inverse constant * crypto/bls12381: fix typo * crypto/bls12381: better comments for bls12381 constants * crypto/bls12381: swu, use single conditional for e2 * crypto/bls12381: utils, delete empty line * crypto/bls12381: utils, use FromHex for string to big * crypto/bls12381: g1, g2, strict length check for FromBytes * crypto/bls12381: field_element, comparision changes * crypto/bls12381: change swu, isogeny constants with hex values * core/vm: fix point multiplication comments * core/vm: fix multiexp gas calculation and lookup for g1 and g2 * core/vm: simpler imput length check for multiexp and pairing precompiles * core/vm: rm empty multiexp result declarations * crypto/bls12381: remove modulus type definition * crypto/bls12381: use proper init function * crypto/bls12381: get rid of new lines at fatal desciprtions * crypto/bls12-381: fix no-adx assembly multiplication * crypto/bls12-381: remove old config function * crypto/bls12381: update multiplication backend this commit changes mul backend to 6limb eip1962 backend mul assign operations are dropped * core/vm/contracts_tests: externalize test vectors for precompiles * core/vm/contracts_test: externalize failure-cases for precompiles * core/vm: linting * go.mod: tiny up sum file * core/vm: fix goimports linter issues * crypto/bls12381: build tags for plain ASM or ADX implementation Co-authored-by: Martin Holst Swende <martin@swende.se> Co-authored-by: Péter Szilágyi <peterke@gmail.com>
5 years ago
func padBytes(in []byte, size int) []byte {
out := make([]byte, size)
if len(in) > size {
panic("bad input for padding")
}
copy(out[size-len(in):], in)
return out
}