1 files changed, 27 insertions, 1 deletions
diff --git a/src/lib/libcrypto/ec/ec_cvt.c b/src/lib/libcrypto/ec/ec_cvt.c
index d45640bab9..bfcbab35fe 100644
--- a/src/lib/libcrypto/ec/ec_cvt.c
+++ b/src/lib/libcrypto/ec/ec_cvt.c
@@ -78,7 +78,32 @@ EC_GROUP *EC_GROUP_new_curve_GFp(const BIGNUM *p, const BIGNUM *a, const BIGNUM
        const EC_METHOD *meth;
        EC_GROUP *ret;
+#if defined(OPENSSL_BN_ASM_MONT)
+        /*
+         * This might appear controversial, but the fact is that generic
+         * prime method was observed to deliver better performance even
+         * for NIST primes on a range of platforms, e.g.: 60%-15%
+         * improvement on IA-64, ~25% on ARM, 30%-90% on P4, 20%-25%
+         * in 32-bit build and 35%--12% in 64-bit build on Core2...
+         * Coefficients are relative to optimized bn_nist.c for most
+         * intensive ECDSA verify and ECDH operations for 192- and 521-
+         * bit keys respectively. Choice of these boundary values is
+         * arguable, because the dependency of improvement coefficient
+         * from key length is not a "monotone" curve. For example while
+         * 571-bit result is 23% on ARM, 384-bit one is -1%. But it's
+         * generally faster, sometimes "respectfully" faster, sometimes
+         * "tolerably" slower... What effectively happens is that loop
+         * with bn_mul_add_words is put against bn_mul_mont, and the
+         * latter "wins" on short vectors. Correct solution should be
+         * implementing dedicated NxN multiplication subroutines for
+         * small N. But till it materializes, let's stick to generic
+         * prime method...
+         *                                              <appro>
+         */
+        meth = EC_GFp_mont_method();
+#else
        meth = EC_GFp_nist_method();
+#endif
        
        ret = EC_GROUP_new(meth);
        if (ret == NULL)
@@ -122,7 +147,7 @@ EC_GROUP *EC_GROUP_new_curve_GFp(const BIGNUM *p, const BIGNUM *a, const BIGNUM
        return ret;
        }
+#ifndef OPENSSL_NO_EC2M
 EC_GROUP *EC_GROUP_new_curve_GF2m(const BIGNUM *p, const BIGNUM *a, const BIGNUM *b, BN_CTX *ctx)
        {
        const EC_METHOD *meth;
@@ -142,3 +167,4 @@ EC_GROUP *EC_GROUP_new_curve_GF2m(const BIGNUM *p, const BIGNUM *a, const BIGNUM
        return ret;
        }
+#endif

diff --git a/src/lib/libcrypto/ec/ec_cvt.c b/src/lib/libcrypto/ec/ec_cvt.c index d45640bab9..bfcbab35fe 100644 --- a/src/lib/libcrypto/ec/ec_cvt.c +++ b/src/lib/libcrypto/ec/ec_cvt.c
@@ -78,7 +78,32 @@ EC_GROUP EC_GROUP_new_curve_GFp(const BIGNUM p, const BIGNUM *a, const BIGNUM
78	const EC_METHOD *meth;	78	const EC_METHOD *meth;
79	EC_GROUP *ret;	79	EC_GROUP *ret;
80		80
		81	#if defined(OPENSSL_BN_ASM_MONT)
		82	/*
		83	* This might appear controversial, but the fact is that generic
		84	* prime method was observed to deliver better performance even
		85	* for NIST primes on a range of platforms, e.g.: 60%-15%
		86	* improvement on IA-64, ~25% on ARM, 30%-90% on P4, 20%-25%
		87	* in 32-bit build and 35%--12% in 64-bit build on Core2...
		88	* Coefficients are relative to optimized bn_nist.c for most
		89	* intensive ECDSA verify and ECDH operations for 192- and 521-
		90	* bit keys respectively. Choice of these boundary values is
		91	* arguable, because the dependency of improvement coefficient
		92	* from key length is not a "monotone" curve. For example while
		93	* 571-bit result is 23% on ARM, 384-bit one is -1%. But it's
		94	* generally faster, sometimes "respectfully" faster, sometimes
		95	* "tolerably" slower... What effectively happens is that loop
		96	* with bn_mul_add_words is put against bn_mul_mont, and the
		97	* latter "wins" on short vectors. Correct solution should be
		98	* implementing dedicated NxN multiplication subroutines for
		99	* small N. But till it materializes, let's stick to generic
		100	* prime method...
		101	* <appro>
		102	*/
		103	meth = EC_GFp_mont_method();
		104	#else
81	meth = EC_GFp_nist_method();	105	meth = EC_GFp_nist_method();
		106	#endif
82		107
83	ret = EC_GROUP_new(meth);	108	ret = EC_GROUP_new(meth);
84	if (ret == NULL)	109	if (ret == NULL)
@@ -122,7 +147,7 @@ EC_GROUP EC_GROUP_new_curve_GFp(const BIGNUM p, const BIGNUM *a, const BIGNUM
122	return ret;	147	return ret;
123	}	148	}
124		149
125		150	#ifndef OPENSSL_NO_EC2M
126	EC_GROUP EC_GROUP_new_curve_GF2m(const BIGNUM p, const BIGNUM a, const BIGNUM b, BN_CTX *ctx)	151	EC_GROUP EC_GROUP_new_curve_GF2m(const BIGNUM p, const BIGNUM a, const BIGNUM b, BN_CTX *ctx)
127	{	152	{
128	const EC_METHOD *meth;	153	const EC_METHOD *meth;
@@ -142,3 +167,4 @@ EC_GROUP EC_GROUP_new_curve_GF2m(const BIGNUM p, const BIGNUM *a, const BIGNUM
142		167
143	return ret;	168	return ret;
144	}	169	}
		170	#endif