| /* Originally written by Bodo Moeller for the OpenSSL project. |
| * ==================================================================== |
| * Copyright (c) 1998-2005 The OpenSSL Project. All rights reserved. |
| * |
| * Redistribution and use in source and binary forms, with or without |
| * modification, are permitted provided that the following conditions |
| * are met: |
| * |
| * 1. Redistributions of source code must retain the above copyright |
| * notice, this list of conditions and the following disclaimer. |
| * |
| * 2. Redistributions in binary form must reproduce the above copyright |
| * notice, this list of conditions and the following disclaimer in |
| * the documentation and/or other materials provided with the |
| * distribution. |
| * |
| * 3. All advertising materials mentioning features or use of this |
| * software must display the following acknowledgment: |
| * "This product includes software developed by the OpenSSL Project |
| * for use in the OpenSSL Toolkit. (http://www.openssl.org/)" |
| * |
| * 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to |
| * endorse or promote products derived from this software without |
| * prior written permission. For written permission, please contact |
| * openssl-core@openssl.org. |
| * |
| * 5. Products derived from this software may not be called "OpenSSL" |
| * nor may "OpenSSL" appear in their names without prior written |
| * permission of the OpenSSL Project. |
| * |
| * 6. Redistributions of any form whatsoever must retain the following |
| * acknowledgment: |
| * "This product includes software developed by the OpenSSL Project |
| * for use in the OpenSSL Toolkit (http://www.openssl.org/)" |
| * |
| * THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ``AS IS'' AND ANY |
| * EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
| * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR |
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| * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED |
| * OF THE POSSIBILITY OF SUCH DAMAGE. |
| * ==================================================================== |
| * |
| * This product includes cryptographic software written by Eric Young |
| * (eay@cryptsoft.com). This product includes software written by Tim |
| * Hudson (tjh@cryptsoft.com). |
| * |
| */ |
| /* ==================================================================== |
| * Copyright 2002 Sun Microsystems, Inc. ALL RIGHTS RESERVED. |
| * |
| * Portions of the attached software ("Contribution") are developed by |
| * SUN MICROSYSTEMS, INC., and are contributed to the OpenSSL project. |
| * |
| * The Contribution is licensed pursuant to the OpenSSL open source |
| * license provided above. |
| * |
| * The elliptic curve binary polynomial software is originally written by |
| * Sheueling Chang Shantz and Douglas Stebila of Sun Microsystems |
| * Laboratories. */ |
| |
| #ifndef OPENSSL_HEADER_EC_INTERNAL_H |
| #define OPENSSL_HEADER_EC_INTERNAL_H |
| |
| #include <openssl/base.h> |
| |
| #include <assert.h> |
| |
| #include <openssl/bn.h> |
| #include <openssl/ec.h> |
| #include <openssl/ex_data.h> |
| |
| #include "../bn/internal.h" |
| |
| #if defined(__cplusplus) |
| extern "C" { |
| #endif |
| |
| |
| // EC internals. |
| |
| |
| // Cap the size of all field elements and scalars, including custom curves, to |
| // 66 bytes, large enough to fit secp521r1 and brainpoolP512r1, which appear to |
| // be the largest fields anyone plausibly uses. |
| #define EC_MAX_BYTES 66 |
| #define EC_MAX_WORDS ((EC_MAX_BYTES + BN_BYTES - 1) / BN_BYTES) |
| #define EC_MAX_COMPRESSED (EC_MAX_BYTES + 1) |
| #define EC_MAX_UNCOMPRESSED (2 * EC_MAX_BYTES + 1) |
| |
| static_assert(EC_MAX_WORDS <= BN_SMALL_MAX_WORDS, |
| "bn_*_small functions not usable"); |
| |
| |
| // Scalars. |
| |
| // An EC_SCALAR is an integer fully reduced modulo the order. Only the first |
| // |order->width| words are used. An |EC_SCALAR| is specific to an |EC_GROUP| |
| // and must not be mixed between groups. |
| typedef struct { |
| BN_ULONG words[EC_MAX_WORDS]; |
| } EC_SCALAR; |
| |
| // ec_bignum_to_scalar converts |in| to an |EC_SCALAR| and writes it to |
| // |*out|. It returns one on success and zero if |in| is out of range. |
| OPENSSL_EXPORT int ec_bignum_to_scalar(const EC_GROUP *group, EC_SCALAR *out, |
| const BIGNUM *in); |
| |
| // ec_scalar_to_bytes serializes |in| as a big-endian bytestring to |out| and |
| // sets |*out_len| to the number of bytes written. The number of bytes written |
| // is |BN_num_bytes(&group->order)|, which is at most |EC_MAX_BYTES|. |
| OPENSSL_EXPORT void ec_scalar_to_bytes(const EC_GROUP *group, uint8_t *out, |
| size_t *out_len, const EC_SCALAR *in); |
| |
| // ec_scalar_from_bytes deserializes |in| and stores the resulting scalar over |
| // group |group| to |out|. It returns one on success and zero if |in| is |
| // invalid. |
| OPENSSL_EXPORT int ec_scalar_from_bytes(const EC_GROUP *group, EC_SCALAR *out, |
| const uint8_t *in, size_t len); |
| |
| // ec_scalar_reduce sets |out| to |words|, reduced modulo the group order. |
| // |words| must be less than order^2. |num| must be at most twice the width of |
| // group order. This function treats |words| as secret. |
| void ec_scalar_reduce(const EC_GROUP *group, EC_SCALAR *out, |
| const BN_ULONG *words, size_t num); |
| |
| // ec_random_nonzero_scalar sets |out| to a uniformly selected random value from |
| // 1 to |group->order| - 1. It returns one on success and zero on error. |
| int ec_random_nonzero_scalar(const EC_GROUP *group, EC_SCALAR *out, |
| const uint8_t additional_data[32]); |
| |
| // ec_scalar_equal_vartime returns one if |a| and |b| are equal and zero |
| // otherwise. Both values are treated as public. |
| int ec_scalar_equal_vartime(const EC_GROUP *group, const EC_SCALAR *a, |
| const EC_SCALAR *b); |
| |
| // ec_scalar_is_zero returns one if |a| is zero and zero otherwise. |
| int ec_scalar_is_zero(const EC_GROUP *group, const EC_SCALAR *a); |
| |
| // ec_scalar_add sets |r| to |a| + |b|. |
| void ec_scalar_add(const EC_GROUP *group, EC_SCALAR *r, const EC_SCALAR *a, |
| const EC_SCALAR *b); |
| |
| // ec_scalar_sub sets |r| to |a| - |b|. |
| void ec_scalar_sub(const EC_GROUP *group, EC_SCALAR *r, const EC_SCALAR *a, |
| const EC_SCALAR *b); |
| |
| // ec_scalar_neg sets |r| to -|a|. |
| void ec_scalar_neg(const EC_GROUP *group, EC_SCALAR *r, const EC_SCALAR *a); |
| |
| // ec_scalar_to_montgomery sets |r| to |a| in Montgomery form. |
| void ec_scalar_to_montgomery(const EC_GROUP *group, EC_SCALAR *r, |
| const EC_SCALAR *a); |
| |
| // ec_scalar_to_montgomery sets |r| to |a| converted from Montgomery form. |
| void ec_scalar_from_montgomery(const EC_GROUP *group, EC_SCALAR *r, |
| const EC_SCALAR *a); |
| |
| // ec_scalar_mul_montgomery sets |r| to |a| * |b| where inputs and outputs are |
| // in Montgomery form. |
| void ec_scalar_mul_montgomery(const EC_GROUP *group, EC_SCALAR *r, |
| const EC_SCALAR *a, const EC_SCALAR *b); |
| |
| // ec_scalar_inv0_montgomery sets |r| to |a|^-1 where inputs and outputs are in |
| // Montgomery form. If |a| is zero, |r| is set to zero. |
| void ec_scalar_inv0_montgomery(const EC_GROUP *group, EC_SCALAR *r, |
| const EC_SCALAR *a); |
| |
| // ec_scalar_to_montgomery_inv_vartime sets |r| to |a|^-1 R. That is, it takes |
| // in |a| not in Montgomery form and computes the inverse in Montgomery form. It |
| // returns one on success and zero if |a| has no inverse. This function assumes |
| // |a| is public and may leak information about it via timing. |
| // |
| // Note this is not the same operation as |ec_scalar_inv0_montgomery|. |
| int ec_scalar_to_montgomery_inv_vartime(const EC_GROUP *group, EC_SCALAR *r, |
| const EC_SCALAR *a); |
| |
| // ec_scalar_select, in constant time, sets |out| to |a| if |mask| is all ones |
| // and |b| if |mask| is all zeros. |
| void ec_scalar_select(const EC_GROUP *group, EC_SCALAR *out, BN_ULONG mask, |
| const EC_SCALAR *a, const EC_SCALAR *b); |
| |
| |
| // Field elements. |
| |
| // An EC_FELEM represents a field element. Only the first |field->width| words |
| // are used. An |EC_FELEM| is specific to an |EC_GROUP| and must not be mixed |
| // between groups. Additionally, the representation (whether or not elements are |
| // represented in Montgomery-form) may vary between |EC_METHOD|s. |
| typedef struct { |
| BN_ULONG words[EC_MAX_WORDS]; |
| } EC_FELEM; |
| |
| // ec_bignum_to_felem converts |in| to an |EC_FELEM|. It returns one on success |
| // and zero if |in| is out of range. |
| int ec_bignum_to_felem(const EC_GROUP *group, EC_FELEM *out, const BIGNUM *in); |
| |
| // ec_felem_to_bignum converts |in| to a |BIGNUM|. It returns one on success and |
| // zero on allocation failure. |
| int ec_felem_to_bignum(const EC_GROUP *group, BIGNUM *out, const EC_FELEM *in); |
| |
| // ec_felem_to_bytes serializes |in| as a big-endian bytestring to |out| and |
| // sets |*out_len| to the number of bytes written. The number of bytes written |
| // is |BN_num_bytes(&group->order)|, which is at most |EC_MAX_BYTES|. |
| void ec_felem_to_bytes(const EC_GROUP *group, uint8_t *out, size_t *out_len, |
| const EC_FELEM *in); |
| |
| // ec_felem_from_bytes deserializes |in| and stores the resulting field element |
| // to |out|. It returns one on success and zero if |in| is invalid. |
| int ec_felem_from_bytes(const EC_GROUP *group, EC_FELEM *out, const uint8_t *in, |
| size_t len); |
| |
| // ec_felem_neg sets |out| to -|a|. |
| void ec_felem_neg(const EC_GROUP *group, EC_FELEM *out, const EC_FELEM *a); |
| |
| // ec_felem_add sets |out| to |a| + |b|. |
| void ec_felem_add(const EC_GROUP *group, EC_FELEM *out, const EC_FELEM *a, |
| const EC_FELEM *b); |
| |
| // ec_felem_add sets |out| to |a| - |b|. |
| void ec_felem_sub(const EC_GROUP *group, EC_FELEM *out, const EC_FELEM *a, |
| const EC_FELEM *b); |
| |
| // ec_felem_non_zero_mask returns all ones if |a| is non-zero and all zeros |
| // otherwise. |
| BN_ULONG ec_felem_non_zero_mask(const EC_GROUP *group, const EC_FELEM *a); |
| |
| // ec_felem_select, in constant time, sets |out| to |a| if |mask| is all ones |
| // and |b| if |mask| is all zeros. |
| void ec_felem_select(const EC_GROUP *group, EC_FELEM *out, BN_ULONG mask, |
| const EC_FELEM *a, const EC_FELEM *b); |
| |
| // ec_felem_equal returns one if |a| and |b| are equal and zero otherwise. |
| int ec_felem_equal(const EC_GROUP *group, const EC_FELEM *a, const EC_FELEM *b); |
| |
| |
| // Points. |
| // |
| // Points may represented in affine coordinates as |EC_AFFINE| or Jacobian |
| // coordinates as |EC_JACOBIAN|. Affine coordinates directly represent a |
| // point on the curve, but point addition over affine coordinates requires |
| // costly field inversions, so arithmetic is done in Jacobian coordinates. |
| // Converting from affine to Jacobian is cheap, while converting from Jacobian |
| // to affine costs a field inversion. (Jacobian coordinates amortize the field |
| // inversions needed in a sequence of point operations.) |
| |
| // An EC_JACOBIAN represents an elliptic curve point in Jacobian coordinates. |
| // Unlike |EC_POINT|, it is a plain struct which can be stack-allocated and |
| // needs no cleanup. It is specific to an |EC_GROUP| and must not be mixed |
| // between groups. |
| typedef struct { |
| // X, Y, and Z are Jacobian projective coordinates. They represent |
| // (X/Z^2, Y/Z^3) if Z != 0 and the point at infinity otherwise. |
| EC_FELEM X, Y, Z; |
| } EC_JACOBIAN; |
| |
| // An EC_AFFINE represents an elliptic curve point in affine coordinates. |
| // coordinates. Note the point at infinity cannot be represented in affine |
| // coordinates. |
| typedef struct { |
| EC_FELEM X, Y; |
| } EC_AFFINE; |
| |
| // ec_affine_to_jacobian converts |p| to Jacobian form and writes the result to |
| // |*out|. This operation is very cheap and only costs a few copies. |
| void ec_affine_to_jacobian(const EC_GROUP *group, EC_JACOBIAN *out, |
| const EC_AFFINE *p); |
| |
| // ec_jacobian_to_affine converts |p| to affine form and writes the result to |
| // |*out|. It returns one on success and zero if |p| was the point at infinity. |
| // This operation performs a field inversion and should only be done once per |
| // point. |
| // |
| // If only extracting the x-coordinate, use |ec_get_x_coordinate_*| which is |
| // slightly faster. |
| OPENSSL_EXPORT int ec_jacobian_to_affine(const EC_GROUP *group, EC_AFFINE *out, |
| const EC_JACOBIAN *p); |
| |
| // ec_jacobian_to_affine_batch converts |num| points in |in| from Jacobian |
| // coordinates to affine coordinates and writes the results to |out|. It returns |
| // one on success and zero if any of the input points were infinity. |
| // |
| // This function is not implemented for all curves. Add implementations as |
| // needed. |
| int ec_jacobian_to_affine_batch(const EC_GROUP *group, EC_AFFINE *out, |
| const EC_JACOBIAN *in, size_t num); |
| |
| // ec_point_set_affine_coordinates sets |out|'s to a point with affine |
| // coordinates |x| and |y|. It returns one if the point is on the curve and |
| // zero otherwise. If the point is not on the curve, the value of |out| is |
| // undefined. |
| int ec_point_set_affine_coordinates(const EC_GROUP *group, EC_AFFINE *out, |
| const EC_FELEM *x, const EC_FELEM *y); |
| |
| // ec_point_mul_no_self_test does the same as |EC_POINT_mul|, but doesn't try to |
| // run the self-test first. This is for use in the self tests themselves, to |
| // prevent an infinite loop. |
| int ec_point_mul_no_self_test(const EC_GROUP *group, EC_POINT *r, |
| const BIGNUM *g_scalar, const EC_POINT *p, |
| const BIGNUM *p_scalar, BN_CTX *ctx); |
| |
| // ec_point_mul_scalar sets |r| to |p| * |scalar|. Both inputs are considered |
| // secret. |
| int ec_point_mul_scalar(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_JACOBIAN *p, const EC_SCALAR *scalar); |
| |
| // ec_point_mul_scalar_base sets |r| to generator * |scalar|. |scalar| is |
| // treated as secret. |
| int ec_point_mul_scalar_base(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_SCALAR *scalar); |
| |
| // ec_point_mul_scalar_batch sets |r| to |p0| * |scalar0| + |p1| * |scalar1| + |
| // |p2| * |scalar2|. |p2| may be NULL to skip that term. |
| // |
| // The inputs are treated as secret, however, this function leaks information |
| // about whether intermediate computations add a point to itself. Callers must |
| // ensure that discrete logs between |p0|, |p1|, and |p2| are uniformly |
| // distributed and independent of the scalars, which should be uniformly |
| // selected and not under the attackers control. This ensures the doubling case |
| // will occur with negligible probability. |
| // |
| // This function is not implemented for all curves. Add implementations as |
| // needed. |
| // |
| // TODO(davidben): This function does not use base point tables. For now, it is |
| // only used with the generic |EC_GFp_mont_method| implementation which has |
| // none. If generalizing to tuned curves, this may be useful. However, we still |
| // must double up to the least efficient input, so precomputed tables can only |
| // save table setup and allow a wider window size. |
| int ec_point_mul_scalar_batch(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_JACOBIAN *p0, const EC_SCALAR *scalar0, |
| const EC_JACOBIAN *p1, const EC_SCALAR *scalar1, |
| const EC_JACOBIAN *p2, const EC_SCALAR *scalar2); |
| |
| #define EC_MONT_PRECOMP_COMB_SIZE 5 |
| |
| // An |EC_PRECOMP| stores precomputed information about a point, to optimize |
| // repeated multiplications involving it. It is a union so different |
| // |EC_METHOD|s can store different information in it. |
| typedef union { |
| EC_AFFINE comb[(1 << EC_MONT_PRECOMP_COMB_SIZE) - 1]; |
| } EC_PRECOMP; |
| |
| // ec_init_precomp precomputes multiples of |p| and writes the result to |out|. |
| // It returns one on success and zero on error. The resulting table may be used |
| // with |ec_point_mul_scalar_precomp|. This function will fail if |p| is the |
| // point at infinity. |
| // |
| // This function is not implemented for all curves. Add implementations as |
| // needed. |
| int ec_init_precomp(const EC_GROUP *group, EC_PRECOMP *out, |
| const EC_JACOBIAN *p); |
| |
| // ec_point_mul_scalar_precomp sets |r| to |p0| * |scalar0| + |p1| * |scalar1| + |
| // |p2| * |scalar2|. |p1| or |p2| may be NULL to skip the corresponding term. |
| // The points are represented as |EC_PRECOMP| and must be initialized with |
| // |ec_init_precomp|. This function runs faster than |ec_point_mul_scalar_batch| |
| // but requires setup work per input point, so it is only appropriate for points |
| // which are used frequently. |
| // |
| // The inputs are treated as secret, however, this function leaks information |
| // about whether intermediate computations add a point to itself. Callers must |
| // ensure that discrete logs between |p0|, |p1|, and |p2| are uniformly |
| // distributed and independent of the scalars, which should be uniformly |
| // selected and not under the attackers control. This ensures the doubling case |
| // will occur with negligible probability. |
| // |
| // This function is not implemented for all curves. Add implementations as |
| // needed. |
| // |
| // TODO(davidben): This function does not use base point tables. For now, it is |
| // only used with the generic |EC_GFp_mont_method| implementation which has |
| // none. If generalizing to tuned curves, we should add a parameter for the base |
| // point and arrange for the generic implementation to have base point tables |
| // available. |
| int ec_point_mul_scalar_precomp(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_PRECOMP *p0, const EC_SCALAR *scalar0, |
| const EC_PRECOMP *p1, const EC_SCALAR *scalar1, |
| const EC_PRECOMP *p2, const EC_SCALAR *scalar2); |
| |
| // ec_point_mul_scalar_public sets |r| to |
| // generator * |g_scalar| + |p| * |p_scalar|. It assumes that the inputs are |
| // public so there is no concern about leaking their values through timing. |
| OPENSSL_EXPORT int ec_point_mul_scalar_public(const EC_GROUP *group, |
| EC_JACOBIAN *r, |
| const EC_SCALAR *g_scalar, |
| const EC_JACOBIAN *p, |
| const EC_SCALAR *p_scalar); |
| |
| // ec_point_mul_scalar_public_batch sets |r| to the sum of generator * |
| // |g_scalar| and |points[i]| * |scalars[i]| where |points| and |scalars| have |
| // |num| elements. It assumes that the inputs are public so there is no concern |
| // about leaking their values through timing. |g_scalar| may be NULL to skip |
| // that term. |
| // |
| // This function is not implemented for all curves. Add implementations as |
| // needed. |
| int ec_point_mul_scalar_public_batch(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_SCALAR *g_scalar, |
| const EC_JACOBIAN *points, |
| const EC_SCALAR *scalars, size_t num); |
| |
| // ec_point_select, in constant time, sets |out| to |a| if |mask| is all ones |
| // and |b| if |mask| is all zeros. |
| void ec_point_select(const EC_GROUP *group, EC_JACOBIAN *out, BN_ULONG mask, |
| const EC_JACOBIAN *a, const EC_JACOBIAN *b); |
| |
| // ec_affine_select behaves like |ec_point_select| but acts on affine points. |
| void ec_affine_select(const EC_GROUP *group, EC_AFFINE *out, BN_ULONG mask, |
| const EC_AFFINE *a, const EC_AFFINE *b); |
| |
| // ec_precomp_select behaves like |ec_point_select| but acts on |EC_PRECOMP|. |
| void ec_precomp_select(const EC_GROUP *group, EC_PRECOMP *out, BN_ULONG mask, |
| const EC_PRECOMP *a, const EC_PRECOMP *b); |
| |
| // ec_cmp_x_coordinate compares the x (affine) coordinate of |p|, mod the group |
| // order, with |r|. It returns one if the values match and zero if |p| is the |
| // point at infinity of the values do not match. |
| int ec_cmp_x_coordinate(const EC_GROUP *group, const EC_JACOBIAN *p, |
| const EC_SCALAR *r); |
| |
| // ec_get_x_coordinate_as_scalar sets |*out| to |p|'s x-coordinate, modulo |
| // |group->order|. It returns one on success and zero if |p| is the point at |
| // infinity. |
| int ec_get_x_coordinate_as_scalar(const EC_GROUP *group, EC_SCALAR *out, |
| const EC_JACOBIAN *p); |
| |
| // ec_get_x_coordinate_as_bytes writes |p|'s affine x-coordinate to |out|, which |
| // must have at must |max_out| bytes. It sets |*out_len| to the number of bytes |
| // written. The value is written big-endian and zero-padded to the size of the |
| // field. This function returns one on success and zero on failure. |
| int ec_get_x_coordinate_as_bytes(const EC_GROUP *group, uint8_t *out, |
| size_t *out_len, size_t max_out, |
| const EC_JACOBIAN *p); |
| |
| // ec_point_byte_len returns the number of bytes in the byte representation of |
| // a non-infinity point in |group|, encoded according to |form|, or zero if |
| // |form| is invalid. |
| size_t ec_point_byte_len(const EC_GROUP *group, point_conversion_form_t form); |
| |
| // ec_point_to_bytes encodes |point| according to |form| and writes the result |
| // |buf|. It returns the size of the output on success or zero on error. At most |
| // |max_out| bytes will be written. The buffer should be at least |
| // |ec_point_byte_len| long to guarantee success. |
| size_t ec_point_to_bytes(const EC_GROUP *group, const EC_AFFINE *point, |
| point_conversion_form_t form, uint8_t *buf, |
| size_t max_out); |
| |
| // ec_point_from_uncompressed parses |in| as a point in uncompressed form and |
| // sets the result to |out|. It returns one on success and zero if the input was |
| // invalid. |
| int ec_point_from_uncompressed(const EC_GROUP *group, EC_AFFINE *out, |
| const uint8_t *in, size_t len); |
| |
| // ec_set_to_safe_point sets |out| to an arbitrary point on |group|, either the |
| // generator or the point at infinity. This is used to guard against callers of |
| // external APIs not checking the return value. |
| void ec_set_to_safe_point(const EC_GROUP *group, EC_JACOBIAN *out); |
| |
| // ec_affine_jacobian_equal returns one if |a| and |b| represent the same point |
| // and zero otherwise. It treats both inputs as secret. |
| int ec_affine_jacobian_equal(const EC_GROUP *group, const EC_AFFINE *a, |
| const EC_JACOBIAN *b); |
| |
| |
| // Implementation details. |
| |
| struct ec_method_st { |
| int (*group_init)(EC_GROUP *); |
| void (*group_finish)(EC_GROUP *); |
| int (*group_set_curve)(EC_GROUP *, const BIGNUM *p, const BIGNUM *a, |
| const BIGNUM *b, BN_CTX *); |
| |
| // point_get_affine_coordinates sets |*x| and |*y| to the affine coordinates |
| // of |p|. Either |x| or |y| may be NULL to omit it. It returns one on success |
| // and zero if |p| is the point at infinity. It leaks whether |p| was the |
| // point at infinity, but otherwise treats |p| as secret. |
| int (*point_get_affine_coordinates)(const EC_GROUP *, const EC_JACOBIAN *p, |
| EC_FELEM *x, EC_FELEM *y); |
| |
| // jacobian_to_affine_batch implements |ec_jacobian_to_affine_batch|. |
| int (*jacobian_to_affine_batch)(const EC_GROUP *group, EC_AFFINE *out, |
| const EC_JACOBIAN *in, size_t num); |
| |
| // add sets |r| to |a| + |b|. |
| void (*add)(const EC_GROUP *group, EC_JACOBIAN *r, const EC_JACOBIAN *a, |
| const EC_JACOBIAN *b); |
| // dbl sets |r| to |a| + |a|. |
| void (*dbl)(const EC_GROUP *group, EC_JACOBIAN *r, const EC_JACOBIAN *a); |
| |
| // mul sets |r| to |scalar|*|p|. |
| void (*mul)(const EC_GROUP *group, EC_JACOBIAN *r, const EC_JACOBIAN *p, |
| const EC_SCALAR *scalar); |
| // mul_base sets |r| to |scalar|*generator. |
| void (*mul_base)(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_SCALAR *scalar); |
| // mul_batch implements |ec_mul_scalar_batch|. |
| void (*mul_batch)(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_JACOBIAN *p0, const EC_SCALAR *scalar0, |
| const EC_JACOBIAN *p1, const EC_SCALAR *scalar1, |
| const EC_JACOBIAN *p2, const EC_SCALAR *scalar2); |
| // mul_public sets |r| to |g_scalar|*generator + |p_scalar|*|p|. It assumes |
| // that the inputs are public so there is no concern about leaking their |
| // values through timing. |
| // |
| // This function may be omitted if |mul_public_batch| is provided. |
| void (*mul_public)(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_SCALAR *g_scalar, const EC_JACOBIAN *p, |
| const EC_SCALAR *p_scalar); |
| // mul_public_batch implements |ec_point_mul_scalar_public_batch|. |
| int (*mul_public_batch)(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_SCALAR *g_scalar, const EC_JACOBIAN *points, |
| const EC_SCALAR *scalars, size_t num); |
| |
| // init_precomp implements |ec_init_precomp|. |
| int (*init_precomp)(const EC_GROUP *group, EC_PRECOMP *out, |
| const EC_JACOBIAN *p); |
| // mul_precomp implements |ec_point_mul_scalar_precomp|. |
| void (*mul_precomp)(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_PRECOMP *p0, const EC_SCALAR *scalar0, |
| const EC_PRECOMP *p1, const EC_SCALAR *scalar1, |
| const EC_PRECOMP *p2, const EC_SCALAR *scalar2); |
| |
| // felem_mul and felem_sqr implement multiplication and squaring, |
| // respectively, so that the generic |EC_POINT_add| and |EC_POINT_dbl| |
| // implementations can work both with |EC_GFp_mont_method| and the tuned |
| // operations. |
| // |
| // TODO(davidben): This constrains |EC_FELEM|'s internal representation, adds |
| // many indirect calls in the middle of the generic code, and a bunch of |
| // conversions. If p224-64.c were easily convertable to Montgomery form, we |
| // could say |EC_FELEM| is always in Montgomery form. If we routed the rest of |
| // simple.c to |EC_METHOD|, we could give |EC_POINT| an |EC_METHOD|-specific |
| // representation and say |EC_FELEM| is purely a |EC_GFp_mont_method| type. |
| void (*felem_mul)(const EC_GROUP *, EC_FELEM *r, const EC_FELEM *a, |
| const EC_FELEM *b); |
| void (*felem_sqr)(const EC_GROUP *, EC_FELEM *r, const EC_FELEM *a); |
| |
| void (*felem_to_bytes)(const EC_GROUP *group, uint8_t *out, size_t *out_len, |
| const EC_FELEM *in); |
| int (*felem_from_bytes)(const EC_GROUP *group, EC_FELEM *out, |
| const uint8_t *in, size_t len); |
| |
| // felem_reduce sets |out| to |words|, reduced modulo the field size, p. |
| // |words| must be less than p^2. |num| must be at most twice the width of p. |
| // This function treats |words| as secret. |
| // |
| // This function is only used in hash-to-curve and may be omitted in curves |
| // that do not support it. |
| void (*felem_reduce)(const EC_GROUP *group, EC_FELEM *out, |
| const BN_ULONG *words, size_t num); |
| |
| // felem_exp sets |out| to |a|^|exp|. It treats |a| is secret but |exp| as |
| // public. |
| // |
| // This function is used in hash-to-curve and may be NULL in curves not used |
| // with hash-to-curve. |
| // |
| // TODO(https://crbug.com/boringssl/567): hash-to-curve uses this as part of |
| // computing a square root, which is what compressed coordinates ultimately |
| // needs to avoid |BIGNUM|. Can we unify this a bit? By generalizing to |
| // arbitrary exponentiation, we also miss an opportunity to use a specialized |
| // addition chain. |
| void (*felem_exp)(const EC_GROUP *group, EC_FELEM *out, const EC_FELEM *a, |
| const BN_ULONG *exp, size_t num_exp); |
| |
| // scalar_inv0_montgomery implements |ec_scalar_inv0_montgomery|. |
| void (*scalar_inv0_montgomery)(const EC_GROUP *group, EC_SCALAR *out, |
| const EC_SCALAR *in); |
| |
| // scalar_to_montgomery_inv_vartime implements |
| // |ec_scalar_to_montgomery_inv_vartime|. |
| int (*scalar_to_montgomery_inv_vartime)(const EC_GROUP *group, EC_SCALAR *out, |
| const EC_SCALAR *in); |
| |
| // cmp_x_coordinate compares the x (affine) coordinate of |p|, mod the group |
| // order, with |r|. It returns one if the values match and zero if |p| is the |
| // point at infinity of the values do not match. |
| int (*cmp_x_coordinate)(const EC_GROUP *group, const EC_JACOBIAN *p, |
| const EC_SCALAR *r); |
| } /* EC_METHOD */; |
| |
| const EC_METHOD *EC_GFp_mont_method(void); |
| |
| struct ec_group_st { |
| const EC_METHOD *meth; |
| |
| // Unlike all other |EC_POINT|s, |generator| does not own |generator->group| |
| // to avoid a reference cycle. Additionally, Z is guaranteed to be one, so X |
| // and Y are suitable for use as an |EC_AFFINE|. |
| EC_POINT *generator; |
| |
| int curve_name; // optional NID for named curve |
| |
| BN_MONT_CTX *order; |
| |
| // The following members are handled by the method functions, |
| // even if they appear generic |
| |
| BIGNUM field; // For curves over GF(p), this is the modulus. |
| |
| EC_FELEM a, b; // Curve coefficients. |
| |
| // a_is_minus3 is one if |a| is -3 mod |field| and zero otherwise. Point |
| // arithmetic is optimized for -3. |
| int a_is_minus3; |
| |
| // field_greater_than_order is one if |field| is greate than |order| and zero |
| // otherwise. |
| int field_greater_than_order; |
| |
| // field_minus_order, if |field_greater_than_order| is true, is |field| minus |
| // |order| represented as an |EC_FELEM|. Otherwise, it is zero. |
| // |
| // Note: unlike |EC_FELEM|s used as intermediate values internal to the |
| // |EC_METHOD|, this value is not encoded in Montgomery form. |
| EC_FELEM field_minus_order; |
| |
| CRYPTO_refcount_t references; |
| |
| BN_MONT_CTX *mont; // Montgomery structure. |
| |
| EC_FELEM one; // The value one. |
| } /* EC_GROUP */; |
| |
| struct ec_point_st { |
| // group is an owning reference to |group|, unless this is |
| // |group->generator|. |
| EC_GROUP *group; |
| // raw is the group-specific point data. Functions that take |EC_POINT| |
| // typically check consistency with |EC_GROUP| while functions that take |
| // |EC_JACOBIAN| do not. Thus accesses to this field should be externally |
| // checked for consistency. |
| EC_JACOBIAN raw; |
| } /* EC_POINT */; |
| |
| EC_GROUP *ec_group_new(const EC_METHOD *meth); |
| |
| void ec_GFp_mont_mul(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_JACOBIAN *p, const EC_SCALAR *scalar); |
| void ec_GFp_mont_mul_base(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_SCALAR *scalar); |
| void ec_GFp_mont_mul_batch(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_JACOBIAN *p0, const EC_SCALAR *scalar0, |
| const EC_JACOBIAN *p1, const EC_SCALAR *scalar1, |
| const EC_JACOBIAN *p2, const EC_SCALAR *scalar2); |
| int ec_GFp_mont_init_precomp(const EC_GROUP *group, EC_PRECOMP *out, |
| const EC_JACOBIAN *p); |
| void ec_GFp_mont_mul_precomp(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_PRECOMP *p0, const EC_SCALAR *scalar0, |
| const EC_PRECOMP *p1, const EC_SCALAR *scalar1, |
| const EC_PRECOMP *p2, const EC_SCALAR *scalar2); |
| void ec_GFp_mont_felem_reduce(const EC_GROUP *group, EC_FELEM *out, |
| const BN_ULONG *words, size_t num); |
| void ec_GFp_mont_felem_exp(const EC_GROUP *group, EC_FELEM *out, |
| const EC_FELEM *a, const BN_ULONG *exp, |
| size_t num_exp); |
| |
| // ec_compute_wNAF writes the modified width-(w+1) Non-Adjacent Form (wNAF) of |
| // |scalar| to |out|. |out| must have room for |bits| + 1 elements, each of |
| // which will be either zero or odd with an absolute value less than 2^w |
| // satisfying |
| // scalar = \sum_j out[j]*2^j |
| // where at most one of any w+1 consecutive digits is non-zero |
| // with the exception that the most significant digit may be only |
| // w-1 zeros away from that next non-zero digit. |
| void ec_compute_wNAF(const EC_GROUP *group, int8_t *out, |
| const EC_SCALAR *scalar, size_t bits, int w); |
| |
| int ec_GFp_mont_mul_public_batch(const EC_GROUP *group, EC_JACOBIAN *r, |
| const EC_SCALAR *g_scalar, |
| const EC_JACOBIAN *points, |
| const EC_SCALAR *scalars, size_t num); |
| |
| // method functions in simple.c |
| int ec_GFp_simple_group_init(EC_GROUP *); |
| void ec_GFp_simple_group_finish(EC_GROUP *); |
| int ec_GFp_simple_group_set_curve(EC_GROUP *, const BIGNUM *p, const BIGNUM *a, |
| const BIGNUM *b, BN_CTX *); |
| int ec_GFp_simple_group_get_curve(const EC_GROUP *, BIGNUM *p, BIGNUM *a, |
| BIGNUM *b); |
| void ec_GFp_simple_point_init(EC_JACOBIAN *); |
| void ec_GFp_simple_point_copy(EC_JACOBIAN *, const EC_JACOBIAN *); |
| void ec_GFp_simple_point_set_to_infinity(const EC_GROUP *, EC_JACOBIAN *); |
| void ec_GFp_mont_add(const EC_GROUP *, EC_JACOBIAN *r, const EC_JACOBIAN *a, |
| const EC_JACOBIAN *b); |
| void ec_GFp_mont_dbl(const EC_GROUP *, EC_JACOBIAN *r, const EC_JACOBIAN *a); |
| void ec_GFp_simple_invert(const EC_GROUP *, EC_JACOBIAN *); |
| int ec_GFp_simple_is_at_infinity(const EC_GROUP *, const EC_JACOBIAN *); |
| int ec_GFp_simple_is_on_curve(const EC_GROUP *, const EC_JACOBIAN *); |
| int ec_GFp_simple_points_equal(const EC_GROUP *, const EC_JACOBIAN *a, |
| const EC_JACOBIAN *b); |
| void ec_simple_scalar_inv0_montgomery(const EC_GROUP *group, EC_SCALAR *r, |
| const EC_SCALAR *a); |
| |
| int ec_simple_scalar_to_montgomery_inv_vartime(const EC_GROUP *group, |
| EC_SCALAR *r, |
| const EC_SCALAR *a); |
| |
| int ec_GFp_simple_cmp_x_coordinate(const EC_GROUP *group, const EC_JACOBIAN *p, |
| const EC_SCALAR *r); |
| |
| void ec_GFp_simple_felem_to_bytes(const EC_GROUP *group, uint8_t *out, |
| size_t *out_len, const EC_FELEM *in); |
| int ec_GFp_simple_felem_from_bytes(const EC_GROUP *group, EC_FELEM *out, |
| const uint8_t *in, size_t len); |
| |
| // method functions in montgomery.c |
| int ec_GFp_mont_group_init(EC_GROUP *); |
| int ec_GFp_mont_group_set_curve(EC_GROUP *, const BIGNUM *p, const BIGNUM *a, |
| const BIGNUM *b, BN_CTX *); |
| void ec_GFp_mont_group_finish(EC_GROUP *); |
| void ec_GFp_mont_felem_mul(const EC_GROUP *, EC_FELEM *r, const EC_FELEM *a, |
| const EC_FELEM *b); |
| void ec_GFp_mont_felem_sqr(const EC_GROUP *, EC_FELEM *r, const EC_FELEM *a); |
| |
| void ec_GFp_mont_felem_to_bytes(const EC_GROUP *group, uint8_t *out, |
| size_t *out_len, const EC_FELEM *in); |
| int ec_GFp_mont_felem_from_bytes(const EC_GROUP *group, EC_FELEM *out, |
| const uint8_t *in, size_t len); |
| |
| void ec_GFp_nistp_recode_scalar_bits(crypto_word_t *sign, crypto_word_t *digit, |
| crypto_word_t in); |
| |
| const EC_METHOD *EC_GFp_nistp224_method(void); |
| const EC_METHOD *EC_GFp_nistp256_method(void); |
| |
| // EC_GFp_nistz256_method is a GFp method using montgomery multiplication, with |
| // x86-64 optimized P256. See http://eprint.iacr.org/2013/816. |
| const EC_METHOD *EC_GFp_nistz256_method(void); |
| |
| // An EC_WRAPPED_SCALAR is an |EC_SCALAR| with a parallel |BIGNUM| |
| // representation. It exists to support the |EC_KEY_get0_private_key| API. |
| typedef struct { |
| BIGNUM bignum; |
| EC_SCALAR scalar; |
| } EC_WRAPPED_SCALAR; |
| |
| struct ec_key_st { |
| EC_GROUP *group; |
| |
| // Ideally |pub_key| would be an |EC_AFFINE| so serializing it does not pay an |
| // inversion each time, but the |EC_KEY_get0_public_key| API implies public |
| // keys are stored in an |EC_POINT|-compatible form. |
| EC_POINT *pub_key; |
| EC_WRAPPED_SCALAR *priv_key; |
| |
| unsigned int enc_flag; |
| point_conversion_form_t conv_form; |
| |
| CRYPTO_refcount_t references; |
| |
| ECDSA_METHOD *ecdsa_meth; |
| |
| CRYPTO_EX_DATA ex_data; |
| } /* EC_KEY */; |
| |
| struct built_in_curve { |
| int nid; |
| const uint8_t *oid; |
| uint8_t oid_len; |
| // comment is a human-readable string describing the curve. |
| const char *comment; |
| // param_len is the number of bytes needed to store a field element. |
| uint8_t param_len; |
| // params points to an array of 6*|param_len| bytes which hold the field |
| // elements of the following (in big-endian order): prime, a, b, generator x, |
| // generator y, order. |
| const uint8_t *params; |
| const EC_METHOD *method; |
| }; |
| |
| #define OPENSSL_NUM_BUILT_IN_CURVES 4 |
| |
| struct built_in_curves { |
| struct built_in_curve curves[OPENSSL_NUM_BUILT_IN_CURVES]; |
| }; |
| |
| // OPENSSL_built_in_curves returns a pointer to static information about |
| // standard curves. The array is terminated with an entry where |nid| is |
| // |NID_undef|. |
| const struct built_in_curves *OPENSSL_built_in_curves(void); |
| |
| #if defined(__cplusplus) |
| } // extern C |
| #endif |
| |
| #endif // OPENSSL_HEADER_EC_INTERNAL_H |