/src/openssl/providers/implementations/kem/rsa_kem.c

Source
/*
 * Copyright 2020-2025 The OpenSSL Project Authors. All Rights Reserved.
 *
 * Licensed under the Apache License 2.0 (the "License").  You may not use
 * this file except in compliance with the License.  You can obtain a copy
 * in the file LICENSE in the source distribution or at
 * https://www.openssl.org/source/license.html
 */

/*
 * RSA low level APIs are deprecated for public use, but still ok for
 * internal use.
 */
#include "internal/deprecated.h"
#include "internal/nelem.h"
#include <openssl/crypto.h>
#include <openssl/evp.h>
#include <openssl/core_dispatch.h>
#include <openssl/core_names.h>
#include <openssl/rsa.h>
#include <openssl/params.h>
#include <openssl/err.h>
#include <openssl/proverr.h>
#include "crypto/rsa.h"
#include "internal/cryptlib.h"
#include "prov/provider_ctx.h"
#include "prov/providercommon.h"
#include "prov/implementations.h"
#include "prov/securitycheck.h"
#include "providers/implementations/kem/rsa_kem.inc"

static OSSL_FUNC_kem_newctx_fn rsakem_newctx;
static OSSL_FUNC_kem_encapsulate_init_fn rsakem_encapsulate_init;
static OSSL_FUNC_kem_encapsulate_fn rsakem_generate;
static OSSL_FUNC_kem_decapsulate_init_fn rsakem_decapsulate_init;
static OSSL_FUNC_kem_decapsulate_fn rsakem_recover;
static OSSL_FUNC_kem_freectx_fn rsakem_freectx;
static OSSL_FUNC_kem_dupctx_fn rsakem_dupctx;
static OSSL_FUNC_kem_get_ctx_params_fn rsakem_get_ctx_params;
static OSSL_FUNC_kem_gettable_ctx_params_fn rsakem_gettable_ctx_params;
static OSSL_FUNC_kem_set_ctx_params_fn rsakem_set_ctx_params;
static OSSL_FUNC_kem_settable_ctx_params_fn rsakem_settable_ctx_params;

/*
 * Only the KEM for RSASVE as defined in SP800-56b r2 is implemented
 * currently.
 */
#define KEM_OP_UNDEFINED   -1
#define KEM_OP_RSASVE       0

/*
 * What's passed as an actual key is defined by the KEYMGMT interface.
 * We happen to know that our KEYMGMT simply passes RSA structures, so
 * we use that here too.
 */
typedef struct {
    OSSL_LIB_CTX *libctx;
    RSA *rsa;
    int op;
    OSSL_FIPS_IND_DECLARE
} PROV_RSA_CTX;

static const OSSL_ITEM rsakem_opname_id_map[] = {
    { KEM_OP_RSASVE, OSSL_KEM_PARAM_OPERATION_RSASVE },
};

static int name2id(const char *name, const OSSL_ITEM *map, size_t sz)
{
    size_t i;

    if (name == NULL)
        return -1;

    for (i = 0; i < sz; ++i) {
        if (OPENSSL_strcasecmp(map[i].ptr, name) == 0)
            return map[i].id;
    }
    return -1;
}

static int rsakem_opname2id(const char *name)
{
    return name2id(name, rsakem_opname_id_map, OSSL_NELEM(rsakem_opname_id_map));
}

static void *rsakem_newctx(void *provctx)
{
    PROV_RSA_CTX *prsactx;

    if (!ossl_prov_is_running())
        return NULL;

    prsactx =  OPENSSL_zalloc(sizeof(PROV_RSA_CTX));
    if (prsactx == NULL)
        return NULL;
    prsactx->libctx = PROV_LIBCTX_OF(provctx);
    prsactx->op = KEM_OP_RSASVE;
    OSSL_FIPS_IND_INIT(prsactx)

    return prsactx;
}

static void rsakem_freectx(void *vprsactx)
{
    PROV_RSA_CTX *prsactx = (PROV_RSA_CTX *)vprsactx;

    RSA_free(prsactx->rsa);
    OPENSSL_free(prsactx);
}

static void *rsakem_dupctx(void *vprsactx)
{
    PROV_RSA_CTX *srcctx = (PROV_RSA_CTX *)vprsactx;
    PROV_RSA_CTX *dstctx;

    if (!ossl_prov_is_running())
        return NULL;

    dstctx = OPENSSL_zalloc(sizeof(*srcctx));
    if (dstctx == NULL)
        return NULL;

    *dstctx = *srcctx;
    if (dstctx->rsa != NULL && !RSA_up_ref(dstctx->rsa)) {
        OPENSSL_free(dstctx);
        return NULL;
    }
    return dstctx;
}

static int rsakem_init(void *vprsactx, void *vrsa,
                       const OSSL_PARAM params[], int operation,
                       const char *desc)
{
    PROV_RSA_CTX *prsactx = (PROV_RSA_CTX *)vprsactx;
    int protect = 0;

    if (!ossl_prov_is_running())
        return 0;

    if (prsactx == NULL || vrsa == NULL)
        return 0;

    if (!ossl_rsa_key_op_get_protect(vrsa, operation, &protect))
        return 0;
    if (!RSA_up_ref(vrsa))
        return 0;
    RSA_free(prsactx->rsa);
    prsactx->rsa = vrsa;

    OSSL_FIPS_IND_SET_APPROVED(prsactx)
    if (!rsakem_set_ctx_params(prsactx, params))
        return 0;
#ifdef FIPS_MODULE
    if (!ossl_fips_ind_rsa_key_check(OSSL_FIPS_IND_GET(prsactx),
                                     OSSL_FIPS_IND_SETTABLE0, prsactx->libctx,
                                     prsactx->rsa, desc, protect))
        return 0;
#endif
    return 1;
}

static int rsakem_encapsulate_init(void *vprsactx, void *vrsa,
                                   const OSSL_PARAM params[])
{
    return rsakem_init(vprsactx, vrsa, params, EVP_PKEY_OP_ENCAPSULATE,
                       "RSA Encapsulate Init");
}

static int rsakem_decapsulate_init(void *vprsactx, void *vrsa,
                                   const OSSL_PARAM params[])
{
    return rsakem_init(vprsactx, vrsa, params, EVP_PKEY_OP_DECAPSULATE,
                       "RSA Decapsulate Init");
}

static int rsakem_get_ctx_params(void *vprsactx, OSSL_PARAM *params)
{
    PROV_RSA_CTX *ctx = (PROV_RSA_CTX *)vprsactx;
    struct rsakem_get_ctx_params_st p;

    if (ctx == NULL || !rsakem_get_ctx_params_decoder(params, &p))
        return 0;

    if (!OSSL_FIPS_IND_GET_CTX_FROM_PARAM(ctx, p.ind))
        return 0;
    return 1;
}

static const OSSL_PARAM *rsakem_gettable_ctx_params(ossl_unused void *vprsactx,
                                                    ossl_unused void *provctx)
{
    return rsakem_get_ctx_params_list;
}

static int rsakem_set_ctx_params(void *vprsactx, const OSSL_PARAM params[])
{
    PROV_RSA_CTX *prsactx = (PROV_RSA_CTX *)vprsactx;
    struct rsakem_set_ctx_params_st p;
    int op;

    if (prsactx == NULL || !rsakem_set_ctx_params_decoder(params, &p))
        return 0;

    if (!OSSL_FIPS_IND_SET_CTX_FROM_PARAM(prsactx, OSSL_FIPS_IND_SETTABLE0,
                                          p.ind_k))
        return 0;

    if (p.op != NULL) {
        if (p.op->data_type != OSSL_PARAM_UTF8_STRING)
            return 0;
        op = rsakem_opname2id(p.op->data);
        if (op < 0)
            return 0;
        prsactx->op = op;
    }
    return 1;
}

static const OSSL_PARAM *rsakem_settable_ctx_params(ossl_unused void *vprsactx,
                                                    ossl_unused void *provctx)
{
    return rsakem_set_ctx_params_list;
}

/*
 * NIST.SP.800-56Br2
 * 7.2.1.2 RSASVE Generate Operation (RSASVE.GENERATE).
 *
 * Generate a random in the range 1 < z < (n – 1)
 */
static int rsasve_gen_rand_bytes(RSA *rsa_pub,
                                 unsigned char *out, int outlen)
{
    int ret = 0;
    BN_CTX *bnctx;
    BIGNUM *z, *nminus3;

    bnctx = BN_CTX_secure_new_ex(ossl_rsa_get0_libctx(rsa_pub));
    if (bnctx == NULL)
        return 0;

    /*
     * Generate a random in the range 1 < z < (n – 1).
     * Since BN_priv_rand_range_ex() returns a value in range 0 <= r < max
     * We can achieve this by adding 2.. but then we need to subtract 3 from
     * the upper bound i.e: 2 + (0 <= r < (n - 3))
     */
    BN_CTX_start(bnctx);
    nminus3 = BN_CTX_get(bnctx);
    z = BN_CTX_get(bnctx);
    ret = (z != NULL
           && (BN_copy(nminus3, RSA_get0_n(rsa_pub)) != NULL)
           && BN_sub_word(nminus3, 3)
           && BN_priv_rand_range_ex(z, nminus3, 0, bnctx)
           && BN_add_word(z, 2)
           && (BN_bn2binpad(z, out, outlen) == outlen));
    BN_CTX_end(bnctx);
    BN_CTX_free(bnctx);
    return ret;
}

/*
 * NIST.SP.800-56Br2
 * 7.2.1.2 RSASVE Generate Operation (RSASVE.GENERATE).
 */
static int rsasve_generate(PROV_RSA_CTX *prsactx,
                           unsigned char *out, size_t *outlen,
                           unsigned char *secret, size_t *secretlen)
{
    int ret;
    size_t nlen;

    /* Step (1): nlen = Ceil(len(n)/8) */
    nlen = RSA_size(prsactx->rsa);

    if (out == NULL) {
        if (nlen == 0) {
            ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_KEY);
            return 0;
        }
        if (outlen == NULL && secretlen == NULL)
            return 0;
        if (outlen != NULL)
            *outlen = nlen;
        if (secretlen != NULL)
            *secretlen = nlen;
        return 1;
    }

    /*
     * If outlen is specified, then it must report the length
     * of the out buffer on input so that we can confirm
     * its size is sufficient for encapsulation
     */
    if (outlen != NULL && *outlen < nlen) {
        ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_OUTPUT_LENGTH);
        return 0;
    }

    /*
     * Step (2): Generate a random byte string z of nlen bytes where
     *            1 < z < n - 1
     */
    if (!rsasve_gen_rand_bytes(prsactx->rsa, secret, (int)nlen))
        return 0;

    /* Step(3): out = RSAEP((n,e), z) */
    ret = RSA_public_encrypt((int)nlen, secret, out, prsactx->rsa,
                             RSA_NO_PADDING);
    if (ret) {
        ret = 1;
        if (outlen != NULL)
            *outlen = nlen;
        if (secretlen != NULL)
            *secretlen = nlen;
    } else {
        OPENSSL_cleanse(secret, nlen);
    }
    return ret;
}

/**
 * rsasve_recover - Recovers a secret value from ciphertext using an RSA
 * private key.  Once, recovered, the secret value is considered to be a
 * shared secret.  Algorithm is performed as per
 * NIST SP 800-56B Rev 2
 * 7.2.1.3 RSASVE Recovery Operation (RSASVE.RECOVER).
 *
 * This function performs RSA decryption using the private key from the
 * provided RSA context (`prsactx`). It takes the input ciphertext, decrypts
 * it, and writes the decrypted message to the output buffer.
 *
 * @prsactx:      The RSA context containing the private key.
 * @out:          The output buffer to store the decrypted message.
 * @outlen:       On input, the size of the output buffer. On successful
 *                completion, the actual length of the decrypted message.
 * @in:           The input buffer containing the ciphertext to be decrypted.
 * @inlen:        The length of the input ciphertext in bytes.
 *
 * Returns 1 on success, or 0 on error. In case of error, appropriate
 * error messages are raised using the ERR_raise function.
 */
static int rsasve_recover(PROV_RSA_CTX *prsactx,
                          unsigned char *out, size_t *outlen,
                          const unsigned char *in, size_t inlen)
{
    size_t nlen;
    int ret;

    /* Step (1): get the byte length of n */
    nlen = RSA_size(prsactx->rsa);

    if (out == NULL) {
        if (nlen == 0) {
            ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_KEY);
            return 0;
        }
        *outlen = nlen;
        return 1;
    }

    /*
     * Step (2): check the input ciphertext 'inlen' matches the nlen
     * and that outlen is at least nlen bytes
     */
    if (inlen != nlen) {
        ERR_raise(ERR_LIB_PROV, PROV_R_BAD_LENGTH);
        return 0;
    }

    /*
     * If outlen is specified, then it must report the length
     * of the out buffer, so that we can confirm that it is of
     * sufficient size to hold the output of decapsulation
     */
    if (outlen != NULL && *outlen < nlen) {
        ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_OUTPUT_LENGTH);
        return 0;
    }

    /* Step (3): out = RSADP((n,d), in) */
    ret = RSA_private_decrypt((int)inlen, in, out, prsactx->rsa, RSA_NO_PADDING);
    if (ret > 0 && outlen != NULL)
        *outlen = ret;
    return ret > 0;
}

static int rsakem_generate(void *vprsactx, unsigned char *out, size_t *outlen,
                           unsigned char *secret, size_t *secretlen)
{
    PROV_RSA_CTX *prsactx = (PROV_RSA_CTX *)vprsactx;

    if (!ossl_prov_is_running())
        return 0;

    switch (prsactx->op) {
        case KEM_OP_RSASVE:
            return rsasve_generate(prsactx, out, outlen, secret, secretlen);
        default:
            return -2;
    }
}

static int rsakem_recover(void *vprsactx, unsigned char *out, size_t *outlen,
                          const unsigned char *in, size_t inlen)
{
    PROV_RSA_CTX *prsactx = (PROV_RSA_CTX *)vprsactx;

    if (!ossl_prov_is_running())
        return 0;

    switch (prsactx->op) {
        case KEM_OP_RSASVE:
            return rsasve_recover(prsactx, out, outlen, in, inlen);
        default:
            return -2;
    }
}

const OSSL_DISPATCH ossl_rsa_asym_kem_functions[] = {
    { OSSL_FUNC_KEM_NEWCTX, (void (*)(void))rsakem_newctx },
    { OSSL_FUNC_KEM_ENCAPSULATE_INIT,
      (void (*)(void))rsakem_encapsulate_init },
    { OSSL_FUNC_KEM_ENCAPSULATE, (void (*)(void))rsakem_generate },
    { OSSL_FUNC_KEM_DECAPSULATE_INIT,
      (void (*)(void))rsakem_decapsulate_init },
    { OSSL_FUNC_KEM_DECAPSULATE, (void (*)(void))rsakem_recover },
    { OSSL_FUNC_KEM_FREECTX, (void (*)(void))rsakem_freectx },
    { OSSL_FUNC_KEM_DUPCTX, (void (*)(void))rsakem_dupctx },
    { OSSL_FUNC_KEM_GET_CTX_PARAMS,
      (void (*)(void))rsakem_get_ctx_params },
    { OSSL_FUNC_KEM_GETTABLE_CTX_PARAMS,
      (void (*)(void))rsakem_gettable_ctx_params },
    { OSSL_FUNC_KEM_SET_CTX_PARAMS,
      (void (*)(void))rsakem_set_ctx_params },
    { OSSL_FUNC_KEM_SETTABLE_CTX_PARAMS,
      (void (*)(void))rsakem_settable_ctx_params },
    OSSL_DISPATCH_END
};

Coverage Report

Created: 2025-10-28 06:56

Line	Count	Source
1		/*
2		* Copyright 2020-2025 The OpenSSL Project Authors. All Rights Reserved.
3		*
4		* Licensed under the Apache License 2.0 (the "License"). You may not use
5		* this file except in compliance with the License. You can obtain a copy
6		* in the file LICENSE in the source distribution or at
7		* https://www.openssl.org/source/license.html
8		*/
9
10		/*
11		* RSA low level APIs are deprecated for public use, but still ok for
12		* internal use.
13		*/
14		#include "internal/deprecated.h"
15		#include "internal/nelem.h"
16		#include <openssl/crypto.h>
17		#include <openssl/evp.h>
18		#include <openssl/core_dispatch.h>
19		#include <openssl/core_names.h>
20		#include <openssl/rsa.h>
21		#include <openssl/params.h>
22		#include <openssl/err.h>
23		#include <openssl/proverr.h>
24		#include "crypto/rsa.h"
25		#include "internal/cryptlib.h"
26		#include "prov/provider_ctx.h"
27		#include "prov/providercommon.h"
28		#include "prov/implementations.h"
29		#include "prov/securitycheck.h"
30		#include "providers/implementations/kem/rsa_kem.inc"
31
32		static OSSL_FUNC_kem_newctx_fn rsakem_newctx;
33		static OSSL_FUNC_kem_encapsulate_init_fn rsakem_encapsulate_init;
34		static OSSL_FUNC_kem_encapsulate_fn rsakem_generate;
35		static OSSL_FUNC_kem_decapsulate_init_fn rsakem_decapsulate_init;
36		static OSSL_FUNC_kem_decapsulate_fn rsakem_recover;
37		static OSSL_FUNC_kem_freectx_fn rsakem_freectx;
38		static OSSL_FUNC_kem_dupctx_fn rsakem_dupctx;
39		static OSSL_FUNC_kem_get_ctx_params_fn rsakem_get_ctx_params;
40		static OSSL_FUNC_kem_gettable_ctx_params_fn rsakem_gettable_ctx_params;
41		static OSSL_FUNC_kem_set_ctx_params_fn rsakem_set_ctx_params;
42		static OSSL_FUNC_kem_settable_ctx_params_fn rsakem_settable_ctx_params;
43
44		/*
45		* Only the KEM for RSASVE as defined in SP800-56b r2 is implemented
46		* currently.
47		*/
48		#define KEM_OP_UNDEFINED -1
49	0	#define KEM_OP_RSASVE 0
50
51		/*
52		* What's passed as an actual key is defined by the KEYMGMT interface.
53		* We happen to know that our KEYMGMT simply passes RSA structures, so
54		* we use that here too.
55		*/
56		typedef struct {
57		OSSL_LIB_CTX *libctx;
58		RSA *rsa;
59		int op;
60		OSSL_FIPS_IND_DECLARE
61		} PROV_RSA_CTX;
62
63		static const OSSL_ITEM rsakem_opname_id_map[] = {
64		{ KEM_OP_RSASVE, OSSL_KEM_PARAM_OPERATION_RSASVE },
65		};
66
67		static int name2id(const char name, const OSSL_ITEM map, size_t sz)
68	0	{
69	0	size_t i;
70
71	0	if (name == NULL)
72	0	return -1;
73
74	0	for (i = 0; i < sz; ++i) {
75	0	if (OPENSSL_strcasecmp(map[i].ptr, name) == 0)
76	0	return map[i].id;
77	0	}
78	0	return -1;
79	0	}
80
81		static int rsakem_opname2id(const char *name)
82	0	{
83	0	return name2id(name, rsakem_opname_id_map, OSSL_NELEM(rsakem_opname_id_map));
84	0	}
85
86		static void rsakem_newctx(void provctx)
87	0	{
88	0	PROV_RSA_CTX *prsactx;
89
90	0	if (!ossl_prov_is_running())
91	0	return NULL;
92
93	0	prsactx = OPENSSL_zalloc(sizeof(PROV_RSA_CTX));
94	0	if (prsactx == NULL)
95	0	return NULL;
96	0	prsactx->libctx = PROV_LIBCTX_OF(provctx);
97	0	prsactx->op = KEM_OP_RSASVE;
98	0	OSSL_FIPS_IND_INIT(prsactx)
99
100	0	return prsactx;
101	0	}
102
103		static void rsakem_freectx(void *vprsactx)
104	0	{
105	0	PROV_RSA_CTX prsactx = (PROV_RSA_CTX )vprsactx;
106
107	0	RSA_free(prsactx->rsa);
108	0	OPENSSL_free(prsactx);
109	0	}
110
111		static void rsakem_dupctx(void vprsactx)
112	0	{
113	0	PROV_RSA_CTX srcctx = (PROV_RSA_CTX )vprsactx;
114	0	PROV_RSA_CTX *dstctx;
115
116	0	if (!ossl_prov_is_running())
117	0	return NULL;
118
119	0	dstctx = OPENSSL_zalloc(sizeof(*srcctx));
120	0	if (dstctx == NULL)
121	0	return NULL;
122
123	0	dstctx = srcctx;
124	0	if (dstctx->rsa != NULL && !RSA_up_ref(dstctx->rsa)) {
125	0	OPENSSL_free(dstctx);
126	0	return NULL;
127	0	}
128	0	return dstctx;
129	0	}
130
131		static int rsakem_init(void vprsactx, void vrsa,
132		const OSSL_PARAM params[], int operation,
133		const char *desc)
134	0	{
135	0	PROV_RSA_CTX prsactx = (PROV_RSA_CTX )vprsactx;
136	0	int protect = 0;
137
138	0	if (!ossl_prov_is_running())
139	0	return 0;
140
141	0	if (prsactx == NULL \|\| vrsa == NULL)
142	0	return 0;
143
144	0	if (!ossl_rsa_key_op_get_protect(vrsa, operation, &protect))
145	0	return 0;
146	0	if (!RSA_up_ref(vrsa))
147	0	return 0;
148	0	RSA_free(prsactx->rsa);
149	0	prsactx->rsa = vrsa;
150
151	0	OSSL_FIPS_IND_SET_APPROVED(prsactx)
152	0	if (!rsakem_set_ctx_params(prsactx, params))
153	0	return 0;
154		#ifdef FIPS_MODULE
155		if (!ossl_fips_ind_rsa_key_check(OSSL_FIPS_IND_GET(prsactx),
156		OSSL_FIPS_IND_SETTABLE0, prsactx->libctx,
157		prsactx->rsa, desc, protect))
158		return 0;
159		#endif
160	0	return 1;
161	0	}
162
163		static int rsakem_encapsulate_init(void vprsactx, void vrsa,
164		const OSSL_PARAM params[])
165	0	{
166	0	return rsakem_init(vprsactx, vrsa, params, EVP_PKEY_OP_ENCAPSULATE,
167	0	"RSA Encapsulate Init");
168	0	}
169
170		static int rsakem_decapsulate_init(void vprsactx, void vrsa,
171		const OSSL_PARAM params[])
172	0	{
173	0	return rsakem_init(vprsactx, vrsa, params, EVP_PKEY_OP_DECAPSULATE,
174	0	"RSA Decapsulate Init");
175	0	}
176
177		static int rsakem_get_ctx_params(void vprsactx, OSSL_PARAM params)
178	0	{
179	0	PROV_RSA_CTX ctx = (PROV_RSA_CTX )vprsactx;
180	0	struct rsakem_get_ctx_params_st p;
181
182	0	if (ctx == NULL \|\| !rsakem_get_ctx_params_decoder(params, &p))
183	0	return 0;
184
185	0	if (!OSSL_FIPS_IND_GET_CTX_FROM_PARAM(ctx, p.ind))
186	0	return 0;
187	0	return 1;
188	0	}
189
190		static const OSSL_PARAM rsakem_gettable_ctx_params(ossl_unused void vprsactx,
191		ossl_unused void *provctx)
192	0	{
193	0	return rsakem_get_ctx_params_list;
194	0	}
195
196		static int rsakem_set_ctx_params(void *vprsactx, const OSSL_PARAM params[])
197	0	{
198	0	PROV_RSA_CTX prsactx = (PROV_RSA_CTX )vprsactx;
199	0	struct rsakem_set_ctx_params_st p;
200	0	int op;
201
202	0	if (prsactx == NULL \|\| !rsakem_set_ctx_params_decoder(params, &p))
203	0	return 0;
204
205	0	if (!OSSL_FIPS_IND_SET_CTX_FROM_PARAM(prsactx, OSSL_FIPS_IND_SETTABLE0,
206	0	p.ind_k))
207	0	return 0;
208
209	0	if (p.op != NULL) {
210	0	if (p.op->data_type != OSSL_PARAM_UTF8_STRING)
211	0	return 0;
212	0	op = rsakem_opname2id(p.op->data);
213	0	if (op < 0)
214	0	return 0;
215	0	prsactx->op = op;
216	0	}
217	0	return 1;
218	0	}
219
220		static const OSSL_PARAM rsakem_settable_ctx_params(ossl_unused void vprsactx,
221		ossl_unused void *provctx)
222	0	{
223	0	return rsakem_set_ctx_params_list;
224	0	}
225
226		/*
227		* NIST.SP.800-56Br2
228		* 7.2.1.2 RSASVE Generate Operation (RSASVE.GENERATE).
229		*
230		* Generate a random in the range 1 < z < (n – 1)
231		*/
232		static int rsasve_gen_rand_bytes(RSA *rsa_pub,
233		unsigned char *out, int outlen)
234	0	{
235	0	int ret = 0;
236	0	BN_CTX *bnctx;
237	0	BIGNUM z, nminus3;
238
239	0	bnctx = BN_CTX_secure_new_ex(ossl_rsa_get0_libctx(rsa_pub));
240	0	if (bnctx == NULL)
241	0	return 0;
242
243		/*
244		* Generate a random in the range 1 < z < (n – 1).
245		* Since BN_priv_rand_range_ex() returns a value in range 0 <= r < max
246		* We can achieve this by adding 2.. but then we need to subtract 3 from
247		* the upper bound i.e: 2 + (0 <= r < (n - 3))
248		*/
249	0	BN_CTX_start(bnctx);
250	0	nminus3 = BN_CTX_get(bnctx);
251	0	z = BN_CTX_get(bnctx);
252	0	ret = (z != NULL
253	0	&& (BN_copy(nminus3, RSA_get0_n(rsa_pub)) != NULL)
254	0	&& BN_sub_word(nminus3, 3)
255	0	&& BN_priv_rand_range_ex(z, nminus3, 0, bnctx)
256	0	&& BN_add_word(z, 2)
257	0	&& (BN_bn2binpad(z, out, outlen) == outlen));
258	0	BN_CTX_end(bnctx);
259	0	BN_CTX_free(bnctx);
260	0	return ret;
261	0	}
262
263		/*
264		* NIST.SP.800-56Br2
265		* 7.2.1.2 RSASVE Generate Operation (RSASVE.GENERATE).
266		*/
267		static int rsasve_generate(PROV_RSA_CTX *prsactx,
268		unsigned char out, size_t outlen,
269		unsigned char secret, size_t secretlen)
270	0	{
271	0	int ret;
272	0	size_t nlen;
273
274		/* Step (1): nlen = Ceil(len(n)/8) */
275	0	nlen = RSA_size(prsactx->rsa);
276
277	0	if (out == NULL) {
278	0	if (nlen == 0) {
279	0	ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_KEY);
280	0	return 0;
281	0	}
282	0	if (outlen == NULL && secretlen == NULL)
283	0	return 0;
284	0	if (outlen != NULL)
285	0	*outlen = nlen;
286	0	if (secretlen != NULL)
287	0	*secretlen = nlen;
288	0	return 1;
289	0	}
290
291		/*
292		* If outlen is specified, then it must report the length
293		* of the out buffer on input so that we can confirm
294		* its size is sufficient for encapsulation
295		*/
296	0	if (outlen != NULL && *outlen < nlen) {
297	0	ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_OUTPUT_LENGTH);
298	0	return 0;
299	0	}
300
301		/*
302		* Step (2): Generate a random byte string z of nlen bytes where
303		* 1 < z < n - 1
304		*/
305	0	if (!rsasve_gen_rand_bytes(prsactx->rsa, secret, (int)nlen))
306	0	return 0;
307
308		/* Step(3): out = RSAEP((n,e), z) */
309	0	ret = RSA_public_encrypt((int)nlen, secret, out, prsactx->rsa,
310	0	RSA_NO_PADDING);
311	0	if (ret) {
312	0	ret = 1;
313	0	if (outlen != NULL)
314	0	*outlen = nlen;
315	0	if (secretlen != NULL)
316	0	*secretlen = nlen;
317	0	} else {
318	0	OPENSSL_cleanse(secret, nlen);
319	0	}
320	0	return ret;
321	0	}
322
323		/**
324		* rsasve_recover - Recovers a secret value from ciphertext using an RSA
325		* private key. Once, recovered, the secret value is considered to be a
326		* shared secret. Algorithm is performed as per
327		* NIST SP 800-56B Rev 2
328		* 7.2.1.3 RSASVE Recovery Operation (RSASVE.RECOVER).
329		*
330		* This function performs RSA decryption using the private key from the
331		* provided RSA context (`prsactx`). It takes the input ciphertext, decrypts
332		* it, and writes the decrypted message to the output buffer.
333		*
334		* @prsactx: The RSA context containing the private key.
335		* @out: The output buffer to store the decrypted message.
336		* @outlen: On input, the size of the output buffer. On successful
337		* completion, the actual length of the decrypted message.
338		* @in: The input buffer containing the ciphertext to be decrypted.
339		* @inlen: The length of the input ciphertext in bytes.
340		*
341		* Returns 1 on success, or 0 on error. In case of error, appropriate
342		* error messages are raised using the ERR_raise function.
343		*/
344		static int rsasve_recover(PROV_RSA_CTX *prsactx,
345		unsigned char out, size_t outlen,
346		const unsigned char *in, size_t inlen)
347	0	{
348	0	size_t nlen;
349	0	int ret;
350
351		/* Step (1): get the byte length of n */
352	0	nlen = RSA_size(prsactx->rsa);
353
354	0	if (out == NULL) {
355	0	if (nlen == 0) {
356	0	ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_KEY);
357	0	return 0;
358	0	}
359	0	*outlen = nlen;
360	0	return 1;
361	0	}
362
363		/*
364		* Step (2): check the input ciphertext 'inlen' matches the nlen
365		* and that outlen is at least nlen bytes
366		*/
367	0	if (inlen != nlen) {
368	0	ERR_raise(ERR_LIB_PROV, PROV_R_BAD_LENGTH);
369	0	return 0;
370	0	}
371
372		/*
373		* If outlen is specified, then it must report the length
374		* of the out buffer, so that we can confirm that it is of
375		* sufficient size to hold the output of decapsulation
376		*/
377	0	if (outlen != NULL && *outlen < nlen) {
378	0	ERR_raise(ERR_LIB_PROV, PROV_R_INVALID_OUTPUT_LENGTH);
379	0	return 0;
380	0	}
381
382		/* Step (3): out = RSADP((n,d), in) */
383	0	ret = RSA_private_decrypt((int)inlen, in, out, prsactx->rsa, RSA_NO_PADDING);
384	0	if (ret > 0 && outlen != NULL)
385	0	*outlen = ret;
386	0	return ret > 0;
387	0	}
388
389		static int rsakem_generate(void vprsactx, unsigned char out, size_t *outlen,
390		unsigned char secret, size_t secretlen)
391	0	{
392	0	PROV_RSA_CTX prsactx = (PROV_RSA_CTX )vprsactx;
393
394	0	if (!ossl_prov_is_running())
395	0	return 0;
396
397	0	switch (prsactx->op) {
398	0	case KEM_OP_RSASVE:
399	0	return rsasve_generate(prsactx, out, outlen, secret, secretlen);
400	0	default:
401	0	return -2;
402	0	}
403	0	}
404
405		static int rsakem_recover(void vprsactx, unsigned char out, size_t *outlen,
406		const unsigned char *in, size_t inlen)
407	0	{
408	0	PROV_RSA_CTX prsactx = (PROV_RSA_CTX )vprsactx;
409
410	0	if (!ossl_prov_is_running())
411	0	return 0;
412
413	0	switch (prsactx->op) {
414	0	case KEM_OP_RSASVE:
415	0	return rsasve_recover(prsactx, out, outlen, in, inlen);
416	0	default:
417	0	return -2;
418	0	}
419	0	}
420
421		const OSSL_DISPATCH ossl_rsa_asym_kem_functions[] = {
422		{ OSSL_FUNC_KEM_NEWCTX, (void (*)(void))rsakem_newctx },
423		{ OSSL_FUNC_KEM_ENCAPSULATE_INIT,
424		(void (*)(void))rsakem_encapsulate_init },
425		{ OSSL_FUNC_KEM_ENCAPSULATE, (void (*)(void))rsakem_generate },
426		{ OSSL_FUNC_KEM_DECAPSULATE_INIT,
427		(void (*)(void))rsakem_decapsulate_init },
428		{ OSSL_FUNC_KEM_DECAPSULATE, (void (*)(void))rsakem_recover },
429		{ OSSL_FUNC_KEM_FREECTX, (void (*)(void))rsakem_freectx },
430		{ OSSL_FUNC_KEM_DUPCTX, (void (*)(void))rsakem_dupctx },
431		{ OSSL_FUNC_KEM_GET_CTX_PARAMS,
432		(void (*)(void))rsakem_get_ctx_params },
433		{ OSSL_FUNC_KEM_GETTABLE_CTX_PARAMS,
434		(void (*)(void))rsakem_gettable_ctx_params },
435		{ OSSL_FUNC_KEM_SET_CTX_PARAMS,
436		(void (*)(void))rsakem_set_ctx_params },
437		{ OSSL_FUNC_KEM_SETTABLE_CTX_PARAMS,
438		(void (*)(void))rsakem_settable_ctx_params },
439		OSSL_DISPATCH_END
440		};