File cve-2019-14318-CryptoPP564.patch of Package libcryptopp.31969
--- ecp.cpp
+++ ecp.cpp
@@ -24,6 +24,498 @@
{
return P.identity ? P : ECP::Point(mr.ConvertOut(P.x), mr.ConvertOut(P.y));
}
+
+
+inline Integer IdentityToInteger(bool val)
+{
+ return val ? Integer::One() : Integer::Zero();
+}
+
+struct ProjectivePoint
+{
+ ProjectivePoint() {}
+ ProjectivePoint(const Integer &x, const Integer &y, const Integer &z)
+ : x(x), y(y), z(z) {}
+
+ Integer x, y, z;
+};
+
+/// \brief Addition and Double functions
+/// \sa <A HREF="https://eprint.iacr.org/2015/1060.pdf">Complete
+/// addition formulas for prime order elliptic curves</A>
+struct AdditionFunction
+{
+ explicit AdditionFunction(const ECP::Field& field,
+ const ECP::FieldElement &a, const ECP::FieldElement &b, ECP::Point &r);
+
+ // Double(P)
+ ECP::Point operator()(const ECP::Point& P) const;
+ // Add(P, Q)
+ ECP::Point operator()(const ECP::Point& P, const ECP::Point& Q) const;
+
+protected:
+ /// \brief Parameters and representation for Addition
+ /// \details Addition and Doubling will use different algorithms,
+ /// depending on the <tt>A</tt> coefficient and the representation
+ /// (Affine or Montgomery with precomputation).
+ enum Alpha {
+ /// \brief Coefficient A is 0
+ A_0 = 1,
+ /// \brief Coefficient A is -3
+ A_3 = 2,
+ /// \brief Coefficient A is arbitrary
+ A_Star = 4,
+ /// \brief Representation is Montgomery
+ A_Montgomery = 8
+ };
+
+ const ECP::Field& field;
+ const ECP::FieldElement &a, &b;
+ ECP::Point &R;
+
+ Alpha m_alpha;
+};
+
+#define X p.x
+#define Y p.y
+#define Z p.z
+
+#define X1 p.x
+#define Y1 p.y
+#define Z1 p.z
+
+#define X2 q.x
+#define Y2 q.y
+#define Z2 q.z
+
+#define X3 r.x
+#define Y3 r.y
+#define Z3 r.z
+
+AdditionFunction::AdditionFunction(const ECP::Field& field,
+ const ECP::FieldElement &a, const ECP::FieldElement &b, ECP::Point &r)
+ : field(field), a(a), b(b), R(r), m_alpha(static_cast<Alpha>(0))
+{
+ if (field.IsMontgomeryRepresentation())
+ {
+ m_alpha = A_Montgomery;
+ }
+ else
+ {
+ if (a == 0)
+ {
+ m_alpha = A_0;
+ }
+ else if (a == -3 || (a - field.GetModulus()) == -3)
+ {
+ m_alpha = A_3;
+ }
+ else
+ {
+ m_alpha = A_Star;
+ }
+ }
+}
+
+ECP::Point AdditionFunction::operator()(const ECP::Point& P) const
+{
+ if (m_alpha == A_3)
+ {
+ // Gyrations attempt to maintain constant-timeness
+ // We need either (P.x, P.y, 1) or (0, 1, 0).
+ const Integer x = P.x * IdentityToInteger(!P.identity);
+ const Integer y = P.y * IdentityToInteger(!P.identity) + 1 * IdentityToInteger(P.identity);
+ const Integer z = 1 * IdentityToInteger(!P.identity);
+
+ ProjectivePoint p(x, y, z), r;
+
+ ECP::FieldElement t0 = field.Square(X);
+ ECP::FieldElement t1 = field.Square(Y);
+ ECP::FieldElement t2 = field.Square(Z);
+ ECP::FieldElement t3 = field.Multiply(X, Y);
+ t3 = field.Add(t3, t3);
+ Z3 = field.Multiply(X, Z);
+ Z3 = field.Add(Z3, Z3);
+ Y3 = field.Multiply(b, t2);
+ Y3 = field.Subtract(Y3, Z3);
+ X3 = field.Add(Y3, Y3);
+ Y3 = field.Add(X3, Y3);
+ X3 = field.Subtract(t1, Y3);
+ Y3 = field.Add(t1, Y3);
+ Y3 = field.Multiply(X3, Y3);
+ X3 = field.Multiply(X3, t3);
+ t3 = field.Add(t2, t2);
+ t2 = field.Add(t2, t3);
+ Z3 = field.Multiply(b, Z3);
+ Z3 = field.Subtract(Z3, t2);
+ Z3 = field.Subtract(Z3, t0);
+ t3 = field.Add(Z3, Z3);
+ Z3 = field.Add(Z3, t3);
+ t3 = field.Add(t0, t0);
+ t0 = field.Add(t3, t0);
+ t0 = field.Subtract(t0, t2);
+ t0 = field.Multiply(t0, Z3);
+ Y3 = field.Add(Y3, t0);
+ t0 = field.Multiply(Y, Z);
+ t0 = field.Add(t0, t0);
+ Z3 = field.Multiply(t0, Z3);
+ X3 = field.Subtract(X3, Z3);
+ Z3 = field.Multiply(t0, t1);
+ Z3 = field.Add(Z3, Z3);
+ Z3 = field.Add(Z3, Z3);
+
+ const ECP::FieldElement inv = field.MultiplicativeInverse(Z3.IsZero() ? Integer::One() : Z3);
+ X3 = field.Multiply(X3, inv); Y3 = field.Multiply(Y3, inv);
+
+ // More gyrations
+ R.x = X3*Z3.NotZero();
+ R.y = Y3*Z3.NotZero();
+ R.identity = Z3.IsZero();
+
+ return R;
+ }
+ else if (m_alpha == A_0)
+ {
+ // Gyrations attempt to maintain constant-timeness
+ // We need either (P.x, P.y, 1) or (0, 1, 0).
+ const Integer x = P.x * IdentityToInteger(!P.identity);
+ const Integer y = P.y * IdentityToInteger(!P.identity) + 1 * IdentityToInteger(P.identity);
+ const Integer z = 1 * IdentityToInteger(!P.identity);
+
+ ProjectivePoint p(x, y, z), r;
+ const ECP::FieldElement b3 = field.Multiply(b, 3);
+
+ ECP::FieldElement t0 = field.Square(Y);
+ Z3 = field.Add(t0, t0);
+ Z3 = field.Add(Z3, Z3);
+ Z3 = field.Add(Z3, Z3);
+ ECP::FieldElement t1 = field.Add(Y, Z);
+ ECP::FieldElement t2 = field.Square(Z);
+ t2 = field.Multiply(b3, t2);
+ X3 = field.Multiply(t2, Z3);
+ Y3 = field.Add(t0, t2);
+ Z3 = field.Multiply(t1, Z3);
+ t1 = field.Add(t2, t2);
+ t2 = field.Add(t1, t2);
+ t0 = field.Subtract(t0, t2);
+ Y3 = field.Multiply(t0, Y3);
+ Y3 = field.Add(X3, Y3);
+ t1 = field.Multiply(X, Y);
+ X3 = field.Multiply(t0, t1);
+ X3 = field.Add(X3, X3);
+
+ const ECP::FieldElement inv = field.MultiplicativeInverse(Z3.IsZero() ? Integer::One() : Z3);
+ X3 = field.Multiply(X3, inv); Y3 = field.Multiply(Y3, inv);
+
+ // More gyrations
+ R.x = X3*Z3.NotZero();
+ R.y = Y3*Z3.NotZero();
+ R.identity = Z3.IsZero();
+
+ return R;
+ }
+ else if (m_alpha == A_Star)
+ {
+ // Gyrations attempt to maintain constant-timeness
+ // We need either (P.x, P.y, 1) or (0, 1, 0).
+ const Integer x = P.x * IdentityToInteger(!P.identity);
+ const Integer y = P.y * IdentityToInteger(!P.identity) + 1 * IdentityToInteger(P.identity);
+ const Integer z = 1 * IdentityToInteger(!P.identity);
+
+ ProjectivePoint p(x, y, z), r;
+ const ECP::FieldElement b3 = field.Multiply(b, 3);
+
+ ECP::FieldElement t0 = field.Square(Y);
+ Z3 = field.Add(t0, t0);
+ Z3 = field.Add(Z3, Z3);
+ Z3 = field.Add(Z3, Z3);
+ ECP::FieldElement t1 = field.Add(Y, Z);
+ ECP::FieldElement t2 = field.Square(Z);
+ t2 = field.Multiply(b3, t2);
+ X3 = field.Multiply(t2, Z3);
+ Y3 = field.Add(t0, t2);
+ Z3 = field.Multiply(t1, Z3);
+ t1 = field.Add(t2, t2);
+ t2 = field.Add(t1, t2);
+ t0 = field.Subtract(t0, t2);
+ Y3 = field.Multiply(t0, Y3);
+ Y3 = field.Add(X3, Y3);
+ t1 = field.Multiply(X, Y);
+ X3 = field.Multiply(t0, t1);
+ X3 = field.Add(X3, X3);
+
+ const ECP::FieldElement inv = field.MultiplicativeInverse(Z3.IsZero() ? Integer::One() : Z3);
+ X3 = field.Multiply(X3, inv); Y3 = field.Multiply(Y3, inv);
+
+ // More gyrations
+ R.x = X3*Z3.NotZero();
+ R.y = Y3*Z3.NotZero();
+ R.identity = Z3.IsZero();
+
+ return R;
+ }
+ else // A_Montgomery
+ {
+ // More gyrations
+ bool identity = !!(P.identity + (P.y == field.Identity()));
+
+ ECP::FieldElement t = field.Square(P.x);
+ t = field.Add(field.Add(field.Double(t), t), a);
+ t = field.Divide(t, field.Double(P.y));
+ ECP::FieldElement x = field.Subtract(field.Subtract(field.Square(t), P.x), P.x);
+ R.y = field.Subtract(field.Multiply(t, field.Subtract(P.x, x)), P.y);
+ R.x.swap(x);
+
+ // More gyrations
+ R.x *= IdentityToInteger(!identity);
+ R.y *= IdentityToInteger(!identity);
+ R.identity = identity;
+
+ return R;
+ }
+}
+
+ECP::Point AdditionFunction::operator()(const ECP::Point& P, const ECP::Point& Q) const
+{
+ if (m_alpha == A_3)
+ {
+ // Gyrations attempt to maintain constant-timeness
+ // We need either (P.x, P.y, 1) or (0, 1, 0).
+ const Integer x1 = P.x * IdentityToInteger(!P.identity);
+ const Integer y1 = P.y * IdentityToInteger(!P.identity) + 1 * IdentityToInteger(P.identity);
+ const Integer z1 = 1 * IdentityToInteger(!P.identity);
+
+ const Integer x2 = Q.x * IdentityToInteger(!Q.identity);
+ const Integer y2 = Q.y * IdentityToInteger(!Q.identity) + 1 * IdentityToInteger(Q.identity);
+ const Integer z2 = 1 * IdentityToInteger(!Q.identity);
+
+ ProjectivePoint p(x1, y1, z1), q(x2, y2, z2), r;
+
+ ECP::FieldElement t0 = field.Multiply(X1, X2);
+ ECP::FieldElement t1 = field.Multiply(Y1, Y2);
+ ECP::FieldElement t2 = field.Multiply(Z1, Z2);
+ ECP::FieldElement t3 = field.Add(X1, Y1);
+ ECP::FieldElement t4 = field.Add(X2, Y2);
+ t3 = field.Multiply(t3, t4);
+ t4 = field.Add(t0, t1);
+ t3 = field.Subtract(t3, t4);
+ t4 = field.Add(Y1, Z1);
+ X3 = field.Add(Y2, Z2);
+ t4 = field.Multiply(t4, X3);
+ X3 = field.Add(t1, t2);
+ t4 = field.Subtract(t4, X3);
+ X3 = field.Add(X1, Z1);
+ Y3 = field.Add(X2, Z2);
+ X3 = field.Multiply(X3, Y3);
+ Y3 = field.Add(t0, t2);
+ Y3 = field.Subtract(X3, Y3);
+ Z3 = field.Multiply(b, t2);
+ X3 = field.Subtract(Y3, Z3);
+ Z3 = field.Add(X3, X3);
+ X3 = field.Add(X3, Z3);
+ Z3 = field.Subtract(t1, X3);
+ X3 = field.Add(t1, X3);
+ Y3 = field.Multiply(b, Y3);
+ t1 = field.Add(t2, t2);
+ t2 = field.Add(t1, t2);
+ Y3 = field.Subtract(Y3, t2);
+ Y3 = field.Subtract(Y3, t0);
+ t1 = field.Add(Y3, Y3);
+ Y3 = field.Add(t1, Y3);
+ t1 = field.Add(t0, t0);
+ t0 = field.Add(t1, t0);
+ t0 = field.Subtract(t0, t2);
+ t1 = field.Multiply(t4, Y3);
+ t2 = field.Multiply(t0, Y3);
+ Y3 = field.Multiply(X3, Z3);
+ Y3 = field.Add(Y3, t2);
+ X3 = field.Multiply(t3, X3);
+ X3 = field.Subtract(X3, t1);
+ Z3 = field.Multiply(t4, Z3);
+ t1 = field.Multiply(t3, t0);
+ Z3 = field.Add(Z3, t1);
+
+ const ECP::FieldElement inv = field.MultiplicativeInverse(Z3.IsZero() ? Integer::One() : Z3);
+ X3 = field.Multiply(X3, inv); Y3 = field.Multiply(Y3, inv);
+
+ // More gyrations
+ R.x = X3*Z3.NotZero();
+ R.y = Y3*Z3.NotZero();
+ R.identity = Z3.IsZero();
+
+ return R;
+ }
+ else if (m_alpha == A_0)
+ {
+ // Gyrations attempt to maintain constant-timeness
+ // We need either (P.x, P.y, 1) or (0, 1, 0).
+ const Integer x1 = P.x * IdentityToInteger(!P.identity);
+ const Integer y1 = P.y * IdentityToInteger(!P.identity) + 1 * IdentityToInteger(P.identity);
+ const Integer z1 = 1 * IdentityToInteger(!P.identity);
+
+ const Integer x2 = Q.x * IdentityToInteger(!Q.identity);
+ const Integer y2 = Q.y * IdentityToInteger(!Q.identity) + 1 * IdentityToInteger(Q.identity);
+ const Integer z2 = 1 * IdentityToInteger(!Q.identity);
+
+ ProjectivePoint p(x1, y1, z1), q(x2, y2, z2), r;
+ const ECP::FieldElement b3 = field.Multiply(b, 3);
+
+ ECP::FieldElement t0 = field.Square(Y);
+ Z3 = field.Add(t0, t0);
+ Z3 = field.Add(Z3, Z3);
+ Z3 = field.Add(Z3, Z3);
+ ECP::FieldElement t1 = field.Add(Y, Z);
+ ECP::FieldElement t2 = field.Square(Z);
+ t2 = field.Multiply(b3, t2);
+ X3 = field.Multiply(t2, Z3);
+ Y3 = field.Add(t0, t2);
+ Z3 = field.Multiply(t1, Z3);
+ t1 = field.Add(t2, t2);
+ t2 = field.Add(t1, t2);
+ t0 = field.Subtract(t0, t2);
+ Y3 = field.Multiply(t0, Y3);
+ Y3 = field.Add(X3, Y3);
+ t1 = field.Multiply(X, Y);
+ X3 = field.Multiply(t0, t1);
+ X3 = field.Add(X3, X3);
+
+ const ECP::FieldElement inv = field.MultiplicativeInverse(Z3.IsZero() ? Integer::One() : Z3);
+ X3 = field.Multiply(X3, inv); Y3 = field.Multiply(Y3, inv);
+
+ // More gyrations
+ R.x = X3*Z3.NotZero();
+ R.y = Y3*Z3.NotZero();
+ R.identity = Z3.IsZero();
+
+ return R;
+ }
+ else if (m_alpha == A_Star)
+ {
+ // Gyrations attempt to maintain constant-timeness
+ // We need either (P.x, P.y, 1) or (0, 1, 0).
+ const Integer x1 = P.x * IdentityToInteger(!P.identity);
+ const Integer y1 = P.y * IdentityToInteger(!P.identity) + 1 * IdentityToInteger(P.identity);
+ const Integer z1 = 1 * IdentityToInteger(!P.identity);
+
+ const Integer x2 = Q.x * IdentityToInteger(!Q.identity);
+ const Integer y2 = Q.y * IdentityToInteger(!Q.identity) + 1 * IdentityToInteger(Q.identity);
+ const Integer z2 = 1 * IdentityToInteger(!Q.identity);
+
+ ProjectivePoint p(x1, y1, z1), q(x2, y2, z2), r;
+ const ECP::FieldElement b3 = field.Multiply(b, 3);
+
+ ECP::FieldElement t0 = field.Multiply(X1, X2);
+ ECP::FieldElement t1 = field.Multiply(Y1, Y2);
+ ECP::FieldElement t2 = field.Multiply(Z1, Z2);
+ ECP::FieldElement t3 = field.Add(X1, Y1);
+ ECP::FieldElement t4 = field.Add(X2, Y2);
+ t3 = field.Multiply(t3, t4);
+ t4 = field.Add(t0, t1);
+ t3 = field.Subtract(t3, t4);
+ t4 = field.Add(X1, Z1);
+ ECP::FieldElement t5 = field.Add(X2, Z2);
+ t4 = field.Multiply(t4, t5);
+ t5 = field.Add(t0, t2);
+ t4 = field.Subtract(t4, t5);
+ t5 = field.Add(Y1, Z1);
+ X3 = field.Add(Y2, Z2);
+ t5 = field.Multiply(t5, X3);
+ X3 = field.Add(t1, t2);
+ t5 = field.Subtract(t5, X3);
+ Z3 = field.Multiply(a, t4);
+ X3 = field.Multiply(b3, t2);
+ Z3 = field.Add(X3, Z3);
+ X3 = field.Subtract(t1, Z3);
+ Z3 = field.Add(t1, Z3);
+ Y3 = field.Multiply(X3, Z3);
+ t1 = field.Add(t0, t0);
+ t1 = field.Add(t1, t0);
+ t2 = field.Multiply(a, t2);
+ t4 = field.Multiply(b3, t4);
+ t1 = field.Add(t1, t2);
+ t2 = field.Subtract(t0, t2);
+ t2 = field.Multiply(a, t2);
+ t4 = field.Add(t4, t2);
+ t0 = field.Multiply(t1, t4);
+ Y3 = field.Add(Y3, t0);
+ t0 = field.Multiply(t5, t4);
+ X3 = field.Multiply(t3, X3);
+ X3 = field.Subtract(X3, t0);
+ t0 = field.Multiply(t3, t1);
+ Z3 = field.Multiply(t5, Z3);
+ Z3 = field.Add(Z3, t0);
+
+ const ECP::FieldElement inv = field.MultiplicativeInverse(Z3.IsZero() ? Integer::One() : Z3);
+ X3 = field.Multiply(X3, inv); Y3 = field.Multiply(Y3, inv);
+
+ // More gyrations
+ R.x = X3*Z3.NotZero();
+ R.y = Y3*Z3.NotZero();
+ R.identity = Z3.IsZero();
+
+ return R;
+ }
+ else // A_Montgomery
+ {
+ // More gyrations
+ bool return_Q = P.identity;
+ bool return_P = Q.identity;
+ bool double_P = field.Equal(P.x, Q.x) && field.Equal(P.y, Q.y);
+ bool identity = field.Equal(P.x, Q.x) && !field.Equal(P.y, Q.y);
+
+ // This code taken from Double(P) for below
+ identity = !!((double_P * (P.identity + (P.y == field.Identity()))) + identity);
+
+ ECP::Point S = R;
+ if (double_P)
+ {
+ // This code taken from Double(P)
+ ECP::FieldElement t = field.Square(P.x);
+ t = field.Add(field.Add(field.Double(t), t), a);
+ t = field.Divide(t, field.Double(P.y));
+ ECP::FieldElement x = field.Subtract(field.Subtract(field.Square(t), P.x), P.x);
+ R.y = field.Subtract(field.Multiply(t, field.Subtract(P.x, x)), P.y);
+ R.x.swap(x);
+ }
+ else
+ {
+ // Original Add(P,Q) code
+ ECP::FieldElement t = field.Subtract(Q.y, P.y);
+ t = field.Divide(t, field.Subtract(Q.x, P.x));
+ ECP::FieldElement x = field.Subtract(field.Subtract(field.Square(t), P.x), Q.x);
+ R.y = field.Subtract(field.Multiply(t, field.Subtract(P.x, x)), P.y);
+ R.x.swap(x);
+ }
+
+ // More gyrations
+ R.x = R.x * IdentityToInteger(!identity);
+ R.y = R.y * IdentityToInteger(!identity);
+ R.identity = identity;
+
+ if (return_Q)
+ return (R = S), Q;
+ else if (return_P)
+ return (R = S), P;
+ else
+ return (S = R), R;
+ }
+}
+
+#undef X
+#undef Y
+#undef Z
+
+#undef X1
+#undef Y1
+#undef Z1
+
+#undef X2
+#undef Y2
+#undef Z2
+
+#undef X3
+#undef Y3
+#undef Z3
NAMESPACE_END
ECP::ECP(const ECP &ecp, bool convertToMontgomeryRepresentation)
@@ -219,34 +711,14 @@
const ECP::Point& ECP::Add(const Point &P, const Point &Q) const
{
- if (P.identity) return Q;
- if (Q.identity) return P;
- if (GetField().Equal(P.x, Q.x))
- return GetField().Equal(P.y, Q.y) ? Double(P) : Identity();
-
- FieldElement t = GetField().Subtract(Q.y, P.y);
- t = GetField().Divide(t, GetField().Subtract(Q.x, P.x));
- FieldElement x = GetField().Subtract(GetField().Subtract(GetField().Square(t), P.x), Q.x);
- m_R.y = GetField().Subtract(GetField().Multiply(t, GetField().Subtract(P.x, x)), P.y);
-
- m_R.x.swap(x);
- m_R.identity = false;
- return m_R;
+ AdditionFunction add(GetField(), m_a, m_b, m_R);
+ return (m_R = add(P, Q));
}
const ECP::Point& ECP::Double(const Point &P) const
{
- if (P.identity || P.y==GetField().Identity()) return Identity();
-
- FieldElement t = GetField().Square(P.x);
- t = GetField().Add(GetField().Add(GetField().Double(t), t), m_a);
- t = GetField().Divide(t, GetField().Double(P.y));
- FieldElement x = GetField().Subtract(GetField().Subtract(GetField().Square(t), P.x), P.x);
- m_R.y = GetField().Subtract(GetField().Multiply(t, GetField().Subtract(P.x, x)), P.y);
-
- m_R.x.swap(x);
- m_R.identity = false;
- return m_R;
+ AdditionFunction add(GetField(), m_a, m_b, m_R);
+ return (m_R = add(P));
}
template <class T, class Iterator> void ParallelInvert(const AbstractRing<T> &ring, Iterator begin, Iterator end)
@@ -286,15 +758,6 @@
}
}
-struct ProjectivePoint
-{
- ProjectivePoint() {}
- ProjectivePoint(const Integer &x, const Integer &y, const Integer &z)
- : x(x), y(y), z(z) {}
-
- Integer x,y,z;
-};
-
class ProjectiveDoubling
{
public:
--- pubkey.h
+++ pubkey.h
@@ -1497,9 +1497,19 @@
// after virtual machine rollback
if (rng.CanIncorporateEntropy())
rng.IncorporateEntropy(representative, representative.size());
+
Integer k(rng, 1, params.GetSubgroupOrder()-1);
+ const Integer& q = params.GetSubgroupOrder();
+
+ // Due to timing attack on nonce length by Jancar
+ // https://github.com/weidai11/cryptopp/issues/869
+ Integer ks = k + q;
+ if (ks.BitCount() == q.BitCount()) {
+ ks += q;
+ }
+
Integer r, s;
- r = params.ConvertElementToInteger(params.ExponentiateBase(k));
+ r = params.ConvertElementToInteger(params.ExponentiateBase(ks));
alg.Sign(params, key.GetPrivateExponent(), k, e, r, s);
/*