FreeRTOS-Plus/Source/WolfSSL/wolfcrypt/src/rsa.c - nest-detect/1.3/freertos - Git at Google

 /* rsa.c
  *
  * Copyright (C) 2006-2015 wolfSSL Inc.
  *
  * This file is part of wolfSSL. (formerly known as CyaSSL)
  *
  * wolfSSL is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
  * the Free Software Foundation; either version 2 of the License, or
  * (at your option) any later version.
  *
  * wolfSSL is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
  */

 #ifdef HAVE_CONFIG_H
     #include <config.h>
 #endif

 #include <wolfssl/wolfcrypt/settings.h>

 #ifndef NO_RSA

 #include <wolfssl/wolfcrypt/rsa.h>

 #ifdef HAVE_FIPS
 int  wc_InitRsaKey(RsaKey* key, void* ptr)
 {
     return InitRsaKey_fips(key, ptr);
 }


 int  wc_FreeRsaKey(RsaKey* key)
 {
     return FreeRsaKey_fips(key);
 }


 int  wc_RsaPublicEncrypt(const byte* in, word32 inLen, byte* out,
                                  word32 outLen, RsaKey* key, RNG* rng)
 {
     return RsaPublicEncrypt_fips(in, inLen, out, outLen, key, rng);
 }


 int  wc_RsaPrivateDecryptInline(byte* in, word32 inLen, byte** out,
                                         RsaKey* key)
 {
     return RsaPrivateDecryptInline_fips(in, inLen, out, key);
 }


 int  wc_RsaPrivateDecrypt(const byte* in, word32 inLen, byte* out,
                                   word32 outLen, RsaKey* key)
 {
     return RsaPrivateDecrypt_fips(in, inLen, out, outLen, key);
 }


 int  wc_RsaSSL_Sign(const byte* in, word32 inLen, byte* out,
                             word32 outLen, RsaKey* key, RNG* rng)
 {
     return RsaSSL_Sign_fips(in, inLen, out, outLen, key, rng);
 }


 int  wc_RsaSSL_VerifyInline(byte* in, word32 inLen, byte** out, RsaKey* key)
 {
     return RsaSSL_VerifyInline_fips(in, inLen, out, key);
 }


 int  wc_RsaSSL_Verify(const byte* in, word32 inLen, byte* out,
                               word32 outLen, RsaKey* key)
 {
     return RsaSSL_Verify_fips(in, inLen, out, outLen, key);
 }


 int  wc_RsaEncryptSize(RsaKey* key)
 {
     return RsaEncryptSize_fips(key);
 }


 int wc_RsaFlattenPublicKey(RsaKey* key, byte* a, word32* aSz, byte* b,
                            word32* bSz)
 {
     /* not specified as fips so not needing _fips */
     return RsaFlattenPublicKey(key, a, aSz, b, bSz);
 }
 #ifdef WOLFSSL_KEY_GEN
     int wc_MakeRsaKey(RsaKey* key, int size, long e, RNG* rng)
     {
         return MakeRsaKey(key, size, e, rng);
     }
 #endif


 #ifdef HAVE_CAVIUM
     int  wc_RsaInitCavium(RsaKey* key, int i)
     {
         return RsaInitCavium(key, i);
     }


     void wc_RsaFreeCavium(RsaKey* key)
     {
         RsaFreeCavium(key);
     }
 #endif

 /* these are functions in asn and are routed to wolfssl/wolfcrypt/asn.c
 * wc_RsaPrivateKeyDecode
 * wc_RsaPublicKeyDecode
 */

 #else /* else build without fips */
 #include <wolfssl/wolfcrypt/random.h>
 #include <wolfssl/wolfcrypt/error-crypt.h>
 #include <wolfssl/wolfcrypt/logging.h>
 #ifdef NO_INLINE
     #include <wolfssl/wolfcrypt/misc.h>
 #else
     #include <wolfcrypt/src/misc.c>
 #endif

 #ifdef SHOW_GEN
     #ifdef FREESCALE_MQX
         #include <fio.h>
     #else
         #include <stdio.h>
     #endif
 #endif

 #ifdef HAVE_CAVIUM
     static int  InitCaviumRsaKey(RsaKey* key, void* heap);
     static int  FreeCaviumRsaKey(RsaKey* key);
     static int  CaviumRsaPublicEncrypt(const byte* in, word32 inLen, byte* out,
                                        word32 outLen, RsaKey* key);
     static int  CaviumRsaPrivateDecrypt(const byte* in, word32 inLen, byte* out,
                                         word32 outLen, RsaKey* key);
     static int  CaviumRsaSSL_Sign(const byte* in, word32 inLen, byte* out,
                                   word32 outLen, RsaKey* key);
     static int  CaviumRsaSSL_Verify(const byte* in, word32 inLen, byte* out,
                                     word32 outLen, RsaKey* key);
 #endif

 enum {
     RSA_PUBLIC_ENCRYPT  = 0,
     RSA_PUBLIC_DECRYPT  = 1,
     RSA_PRIVATE_ENCRYPT = 2,
     RSA_PRIVATE_DECRYPT = 3,

     RSA_BLOCK_TYPE_1 = 1,
     RSA_BLOCK_TYPE_2 = 2,

     RSA_MIN_SIZE = 512,
     RSA_MAX_SIZE = 4096,

     RSA_MIN_PAD_SZ   = 11      /* seperator + 0 + pad value + 8 pads */
 };


 int wc_InitRsaKey(RsaKey* key, void* heap)
 {
 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
         return InitCaviumRsaKey(key, heap);
 #endif

     key->type = -1;  /* haven't decided yet */
     key->heap = heap;

 /* TomsFastMath doesn't use memory allocation */
 #ifndef USE_FAST_MATH
     key->n.dp = key->e.dp = 0;  /* public  alloc parts */

     key->d.dp = key->p.dp  = 0;  /* private alloc parts */
     key->q.dp = key->dP.dp = 0;
     key->u.dp = key->dQ.dp = 0;
 #else
     mp_init(&key->n);
     mp_init(&key->e);
     mp_init(&key->d);
     mp_init(&key->p);
     mp_init(&key->q);
     mp_init(&key->dP);
     mp_init(&key->dQ);
     mp_init(&key->u);
 #endif

     return 0;
 }


 int wc_FreeRsaKey(RsaKey* key)
 {
     (void)key;

 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
         return FreeCaviumRsaKey(key);
 #endif

 /* TomsFastMath doesn't use memory allocation */
 #ifndef USE_FAST_MATH
     if (key->type == RSA_PRIVATE) {
         mp_clear(&key->u);
         mp_clear(&key->dQ);
         mp_clear(&key->dP);
         mp_clear(&key->q);
         mp_clear(&key->p);
         mp_clear(&key->d);
     }
     mp_clear(&key->e);
     mp_clear(&key->n);
 #endif

     return 0;
 }

 static int wc_RsaPad(const byte* input, word32 inputLen, byte* pkcsBlock,
                    word32 pkcsBlockLen, byte padValue, RNG* rng)
 {
     if (inputLen == 0)
         return 0;

     pkcsBlock[0] = 0x0;       /* set first byte to zero and advance */
     pkcsBlock++; pkcsBlockLen--;
     pkcsBlock[0] = padValue;  /* insert padValue */

     if (padValue == RSA_BLOCK_TYPE_1)
         /* pad with 0xff bytes */
         XMEMSET(&pkcsBlock[1], 0xFF, pkcsBlockLen - inputLen - 2);
     else {
         /* pad with non-zero random bytes */
         word32 padLen = pkcsBlockLen - inputLen - 1, i;
         int    ret    = wc_RNG_GenerateBlock(rng, &pkcsBlock[1], padLen);

         if (ret != 0)
             return ret;

         /* remove zeros */
         for (i = 1; i < padLen; i++)
             if (pkcsBlock[i] == 0) pkcsBlock[i] = 0x01;
     }

     pkcsBlock[pkcsBlockLen-inputLen-1] = 0;     /* separator */
     XMEMCPY(pkcsBlock+pkcsBlockLen-inputLen, input, inputLen);

     return 0;
 }


 /* UnPad plaintext, set start to *output, return length of plaintext,
  * < 0 on error */
 static int RsaUnPad(const byte *pkcsBlock, unsigned int pkcsBlockLen,
                        byte **output, byte padValue)
 {
     word32 maxOutputLen = (pkcsBlockLen > 10) ? (pkcsBlockLen - 10) : 0,
            invalid = 0,
            i = 1,
            outputLen;

     if (pkcsBlock[0] != 0x0) /* skip past zero */
         invalid = 1;
     pkcsBlock++; pkcsBlockLen--;

     /* Require block type padValue */
     invalid = (pkcsBlock[0] != padValue) || invalid;

     /* verify the padding until we find the separator */
     if (padValue == RSA_BLOCK_TYPE_1) {
         while (i<pkcsBlockLen && pkcsBlock[i++] == 0xFF) {/* Null body */}
     }
     else {
         while (i<pkcsBlockLen && pkcsBlock[i++]) {/* Null body */}
     }

     if(!(i==pkcsBlockLen || pkcsBlock[i-1]==0)) {
         WOLFSSL_MSG("RsaUnPad error, bad formatting");
         return RSA_PAD_E;
     }

     outputLen = pkcsBlockLen - i;
     invalid = (outputLen > maxOutputLen) || invalid;

     if (invalid) {
         WOLFSSL_MSG("RsaUnPad error, bad formatting");
         return RSA_PAD_E;
     }

     *output = (byte *)(pkcsBlock + i);
     return outputLen;
 }


 static int wc_RsaFunction(const byte* in, word32 inLen, byte* out,
                           word32* outLen, int type, RsaKey* key)
 {
     #define ERROR_OUT(x) { ret = (x); goto done;}

     mp_int tmp;
     int    ret = 0;
     word32 keyLen, len;

     if (mp_init(&tmp) != MP_OKAY)
         return MP_INIT_E;

     if (mp_read_unsigned_bin(&tmp, (byte*)in, inLen) != MP_OKAY)
         ERROR_OUT(MP_READ_E);

     if (type == RSA_PRIVATE_DECRYPT || type == RSA_PRIVATE_ENCRYPT) {
         #ifdef RSA_LOW_MEM      /* half as much memory but twice as slow */
             if (mp_exptmod(&tmp, &key->d, &key->n, &tmp) != MP_OKAY)
                 ERROR_OUT(MP_EXPTMOD_E);
         #else
             #define INNER_ERROR_OUT(x) { ret = (x); goto inner_done; }

             mp_int tmpa, tmpb;

             if (mp_init(&tmpa) != MP_OKAY)
                 ERROR_OUT(MP_INIT_E);

             if (mp_init(&tmpb) != MP_OKAY) {
                 mp_clear(&tmpa);
                 ERROR_OUT(MP_INIT_E);
             }

             /* tmpa = tmp^dP mod p */
             if (mp_exptmod(&tmp, &key->dP, &key->p, &tmpa) != MP_OKAY)
                 INNER_ERROR_OUT(MP_EXPTMOD_E);

             /* tmpb = tmp^dQ mod q */
             if (mp_exptmod(&tmp, &key->dQ, &key->q, &tmpb) != MP_OKAY)
                 INNER_ERROR_OUT(MP_EXPTMOD_E);

             /* tmp = (tmpa - tmpb) * qInv (mod p) */
             if (mp_sub(&tmpa, &tmpb, &tmp) != MP_OKAY)
                 INNER_ERROR_OUT(MP_SUB_E);

             if (mp_mulmod(&tmp, &key->u, &key->p, &tmp) != MP_OKAY)
                 INNER_ERROR_OUT(MP_MULMOD_E);

             /* tmp = tmpb + q * tmp */
             if (mp_mul(&tmp, &key->q, &tmp) != MP_OKAY)
                 INNER_ERROR_OUT(MP_MUL_E);

             if (mp_add(&tmp, &tmpb, &tmp) != MP_OKAY)
                 INNER_ERROR_OUT(MP_ADD_E);

         inner_done:
             mp_clear(&tmpa);
             mp_clear(&tmpb);

             if (ret != 0) return ret;

         #endif   /* RSA_LOW_MEM */
     }
     else if (type == RSA_PUBLIC_ENCRYPT || type == RSA_PUBLIC_DECRYPT) {
         if (mp_exptmod(&tmp, &key->e, &key->n, &tmp) != MP_OKAY)
             ERROR_OUT(MP_EXPTMOD_E);
     }
     else
         ERROR_OUT(RSA_WRONG_TYPE_E);

     keyLen = mp_unsigned_bin_size(&key->n);
     if (keyLen > *outLen)
         ERROR_OUT(RSA_BUFFER_E);

     len = mp_unsigned_bin_size(&tmp);

     /* pad front w/ zeros to match key length */
     while (len < keyLen) {
         *out++ = 0x00;
         len++;
     }

     *outLen = keyLen;

     /* convert */
     if (mp_to_unsigned_bin(&tmp, out) != MP_OKAY)
         ERROR_OUT(MP_TO_E);

 done:
     mp_clear(&tmp);
     if (ret == MP_EXPTMOD_E) {
         WOLFSSL_MSG("RSA_FUNCTION MP_EXPTMOD_E: memory/config problem");
     }
     return ret;
 }


 int wc_RsaPublicEncrypt(const byte* in, word32 inLen, byte* out, word32 outLen,
                      RsaKey* key, RNG* rng)
 {
     int sz, ret;

 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
         return CaviumRsaPublicEncrypt(in, inLen, out, outLen, key);
 #endif

     sz = mp_unsigned_bin_size(&key->n);
     if (sz > (int)outLen)
         return RSA_BUFFER_E;

     if (inLen > (word32)(sz - RSA_MIN_PAD_SZ))
         return RSA_BUFFER_E;

     ret = wc_RsaPad(in, inLen, out, sz, RSA_BLOCK_TYPE_2, rng);
     if (ret != 0)
         return ret;

     if ((ret = wc_RsaFunction(out, sz, out, &outLen,
                               RSA_PUBLIC_ENCRYPT, key)) < 0)
         sz = ret;

     return sz;
 }


 int wc_RsaPrivateDecryptInline(byte* in, word32 inLen, byte** out, RsaKey* key)
 {
     int ret;

 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC) {
         ret = CaviumRsaPrivateDecrypt(in, inLen, in, inLen, key);
         if (ret > 0)
             *out = in;
         return ret;
     }
 #endif

     if ((ret = wc_RsaFunction(in, inLen, in, &inLen, RSA_PRIVATE_DECRYPT, key))
             < 0) {
         return ret;
     }

     return RsaUnPad(in, inLen, out, RSA_BLOCK_TYPE_2);
 }


 int wc_RsaPrivateDecrypt(const byte* in, word32 inLen, byte* out, word32 outLen,
                      RsaKey* key)
 {
     int plainLen;
     byte*  tmp;
     byte*  pad = 0;

 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
         return CaviumRsaPrivateDecrypt(in, inLen, out, outLen, key);
 #endif

     tmp = (byte*)XMALLOC(inLen, key->heap, DYNAMIC_TYPE_RSA);
     if (tmp == NULL) {
         return MEMORY_E;
     }

     XMEMCPY(tmp, in, inLen);

     if ( (plainLen = wc_RsaPrivateDecryptInline(tmp, inLen, &pad, key) ) < 0) {
         XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);
         return plainLen;
     }
     if (plainLen > (int)outLen)
         plainLen = BAD_FUNC_ARG;
     else
         XMEMCPY(out, pad, plainLen);

     ForceZero(tmp, inLen);
     XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);

     return plainLen;
 }


 /* for Rsa Verify */
 int wc_RsaSSL_VerifyInline(byte* in, word32 inLen, byte** out, RsaKey* key)
 {
     int ret;

 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC) {
         ret = CaviumRsaSSL_Verify(in, inLen, in, inLen, key);
         if (ret > 0)
             *out = in;
         return ret;
     }
 #endif

     if ((ret = wc_RsaFunction(in, inLen, in, &inLen, RSA_PUBLIC_DECRYPT, key))
             < 0) {
         return ret;
     }

     return RsaUnPad(in, inLen, out, RSA_BLOCK_TYPE_1);
 }


 int wc_RsaSSL_Verify(const byte* in, word32 inLen, byte* out, word32 outLen,
                      RsaKey* key)
 {
     int plainLen;
     byte*  tmp;
     byte*  pad = 0;

 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
         return CaviumRsaSSL_Verify(in, inLen, out, outLen, key);
 #endif

     tmp = (byte*)XMALLOC(inLen, key->heap, DYNAMIC_TYPE_RSA);
     if (tmp == NULL) {
         return MEMORY_E;
     }

     XMEMCPY(tmp, in, inLen);

     if ( (plainLen = wc_RsaSSL_VerifyInline(tmp, inLen, &pad, key) ) < 0) {
         XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);
         return plainLen;
     }

     if (plainLen > (int)outLen)
         plainLen = BAD_FUNC_ARG;
     else
         XMEMCPY(out, pad, plainLen);

     ForceZero(tmp, inLen);
     XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);

     return plainLen;
 }


 /* for Rsa Sign */
 int wc_RsaSSL_Sign(const byte* in, word32 inLen, byte* out, word32 outLen,
                       RsaKey* key, RNG* rng)
 {
     int sz, ret;

 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
         return CaviumRsaSSL_Sign(in, inLen, out, outLen, key);
 #endif

     sz = mp_unsigned_bin_size(&key->n);
     if (sz > (int)outLen)
         return RSA_BUFFER_E;

     if (inLen > (word32)(sz - RSA_MIN_PAD_SZ))
         return RSA_BUFFER_E;

     ret = wc_RsaPad(in, inLen, out, sz, RSA_BLOCK_TYPE_1, rng);
     if (ret != 0)
         return ret;

     if ((ret = wc_RsaFunction(out, sz, out, &outLen,
                               RSA_PRIVATE_ENCRYPT,key)) < 0)
         sz = ret;

     return sz;
 }


 int wc_RsaEncryptSize(RsaKey* key)
 {
 #ifdef HAVE_CAVIUM
     if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
         return key->c_nSz;
 #endif
     return mp_unsigned_bin_size(&key->n);
 }

 /* flatten RsaKey structure into individual elements (e, n) */
 int wc_RsaFlattenPublicKey(RsaKey* key, byte* e, word32* eSz, byte* n,
                            word32* nSz)
 {
     int sz, ret;

     if (key == NULL || e == NULL || eSz == NULL || n == NULL || nSz == NULL)
        return BAD_FUNC_ARG;

     sz = mp_unsigned_bin_size(&key->e);
     if ((word32)sz > *nSz)
         return RSA_BUFFER_E;
     ret = mp_to_unsigned_bin(&key->e, e);
     if (ret != MP_OKAY)
         return ret;
     *eSz = (word32)sz;

     sz = mp_unsigned_bin_size(&key->n);
     if ((word32)sz > *nSz)
         return RSA_BUFFER_E;
     ret = mp_to_unsigned_bin(&key->n, n);
     if (ret != MP_OKAY)
         return ret;
     *nSz = (word32)sz;

     return 0;
 }


 #ifdef WOLFSSL_KEY_GEN

 static const int USE_BBS = 1;

 static int rand_prime(mp_int* N, int len, RNG* rng, void* heap)
 {
     int   err, res, type;
     byte* buf;

     (void)heap;
     if (N == NULL || rng == NULL)
        return BAD_FUNC_ARG;

     /* get type */
     if (len < 0) {
         type = USE_BBS;
         len = -len;
     } else {
         type = 0;
     }

     /* allow sizes between 2 and 512 bytes for a prime size */
     if (len < 2 || len > 512) {
         return BAD_FUNC_ARG;
     }

     /* allocate buffer to work with */
     buf = (byte*)XMALLOC(len, heap, DYNAMIC_TYPE_RSA);
     if (buf == NULL) {
         return MEMORY_E;
     }
     XMEMSET(buf, 0, len);

     do {
 #ifdef SHOW_GEN
         printf(".");
         fflush(stdout);
 #endif
         /* generate value */
         err = wc_RNG_GenerateBlock(rng, buf, len);
         if (err != 0) {
             XFREE(buf, heap, DYNAMIC_TYPE_RSA);
             return err;
         }

         /* munge bits */
         buf[0]     |= 0x80 | 0x40;
         buf[len-1] |= 0x01 | ((type & USE_BBS) ? 0x02 : 0x00);

         /* load value */
         if ((err = mp_read_unsigned_bin(N, buf, len)) != MP_OKAY) {
             XFREE(buf, heap, DYNAMIC_TYPE_RSA);
             return err;
         }

         /* test */
         if ((err = mp_prime_is_prime(N, 8, &res)) != MP_OKAY) {
             XFREE(buf, heap, DYNAMIC_TYPE_RSA);
             return err;
         }
     } while (res == MP_NO);

     ForceZero(buf, len);
     XFREE(buf, heap, DYNAMIC_TYPE_RSA);

     return 0;
 }


 /* Make an RSA key for size bits, with e specified, 65537 is a good e */
 int wc_MakeRsaKey(RsaKey* key, int size, long e, RNG* rng)
 {
     mp_int p, q, tmp1, tmp2, tmp3;
     int    err;

     if (key == NULL || rng == NULL)
         return BAD_FUNC_ARG;

     if (size < RSA_MIN_SIZE || size > RSA_MAX_SIZE)
         return BAD_FUNC_ARG;

     if (e < 3 || (e & 1) == 0)
         return BAD_FUNC_ARG;

     if ((err = mp_init_multi(&p, &q, &tmp1, &tmp2, &tmp3, NULL)) != MP_OKAY)
         return err;

     err = mp_set_int(&tmp3, e);

     /* make p */
     if (err == MP_OKAY) {
         do {
             err = rand_prime(&p, size/16, rng, key->heap); /* size in bytes/2 */

             if (err == MP_OKAY)
                 err = mp_sub_d(&p, 1, &tmp1);  /* tmp1 = p-1 */

             if (err == MP_OKAY)
                 err = mp_gcd(&tmp1, &tmp3, &tmp2);  /* tmp2 = gcd(p-1, e) */
         } while (err == MP_OKAY && mp_cmp_d(&tmp2, 1) != 0);  /* e divdes p-1 */
     }

     /* make q */
     if (err == MP_OKAY) {
         do {
             err = rand_prime(&q, size/16, rng, key->heap); /* size in bytes/2 */

             if (err == MP_OKAY)
                 err = mp_sub_d(&q, 1, &tmp1);  /* tmp1 = q-1 */

             if (err == MP_OKAY)
                 err = mp_gcd(&tmp1, &tmp3, &tmp2);  /* tmp2 = gcd(q-1, e) */
         } while (err == MP_OKAY && mp_cmp_d(&tmp2, 1) != 0);  /* e divdes q-1 */
     }

     if (err == MP_OKAY)
         err = mp_init_multi(&key->n, &key->e, &key->d, &key->p, &key->q, NULL);

     if (err == MP_OKAY)
         err = mp_init_multi(&key->dP, &key->dQ, &key->u, NULL, NULL, NULL);

     if (err == MP_OKAY)
         err = mp_sub_d(&p, 1, &tmp2);  /* tmp2 = p-1 */

     if (err == MP_OKAY)
         err = mp_lcm(&tmp1, &tmp2, &tmp1);  /* tmp1 = lcm(p-1, q-1),last loop */

     /* make key */
     if (err == MP_OKAY)
         err = mp_set_int(&key->e, e);  /* key->e = e */

     if (err == MP_OKAY)                /* key->d = 1/e mod lcm(p-1, q-1) */
         err = mp_invmod(&key->e, &tmp1, &key->d);

     if (err == MP_OKAY)
         err = mp_mul(&p, &q, &key->n);  /* key->n = pq */

     if (err == MP_OKAY)
         err = mp_sub_d(&p, 1, &tmp1);

     if (err == MP_OKAY)
         err = mp_sub_d(&q, 1, &tmp2);

     if (err == MP_OKAY)
         err = mp_mod(&key->d, &tmp1, &key->dP);

     if (err == MP_OKAY)
         err = mp_mod(&key->d, &tmp2, &key->dQ);

     if (err == MP_OKAY)
         err = mp_invmod(&q, &p, &key->u);

     if (err == MP_OKAY)
         err = mp_copy(&p, &key->p);

     if (err == MP_OKAY)
         err = mp_copy(&q, &key->q);

     if (err == MP_OKAY)
         key->type = RSA_PRIVATE;

     mp_clear(&tmp3);
     mp_clear(&tmp2);
     mp_clear(&tmp1);
     mp_clear(&q);
     mp_clear(&p);

     if (err != MP_OKAY) {
         wc_FreeRsaKey(key);
         return err;
     }

     return 0;
 }


 #endif /* WOLFSSL_KEY_GEN */


 #ifdef HAVE_CAVIUM

 #include <cyassl/ctaocrypt/logging.h>
 #include "cavium_common.h"

 /* Initiliaze RSA for use with Nitrox device */
 int RsaInitCavium(RsaKey* rsa, int devId)
 {
     if (rsa == NULL)
         return -1;

     if (CspAllocContext(CONTEXT_SSL, &rsa->contextHandle, devId) != 0)
         return -1;

     rsa->devId = devId;
     rsa->magic = WOLFSSL_RSA_CAVIUM_MAGIC;

     return 0;
 }


 /* Free RSA from use with Nitrox device */
 void wc_RsaFreeCavium(RsaKey* rsa)
 {
     if (rsa == NULL)
         return;

     CspFreeContext(CONTEXT_SSL, rsa->contextHandle, rsa->devId);
     rsa->magic = 0;
 }


 /* Initialize cavium RSA key */
 static int InitCaviumRsaKey(RsaKey* key, void* heap)
 {
     if (key == NULL)
         return BAD_FUNC_ARG;

     key->heap = heap;
     key->type = -1;   /* don't know yet */

     key->c_n  = NULL;
     key->c_e  = NULL;
     key->c_d  = NULL;
     key->c_p  = NULL;
     key->c_q  = NULL;
     key->c_dP = NULL;
     key->c_dQ = NULL;
     key->c_u  = NULL;

     key->c_nSz   = 0;
     key->c_eSz   = 0;
     key->c_dSz   = 0;
     key->c_pSz   = 0;
     key->c_qSz   = 0;
     key->c_dP_Sz = 0;
     key->c_dQ_Sz = 0;
     key->c_uSz   = 0;

     return 0;
 }


 /* Free cavium RSA key */
 static int FreeCaviumRsaKey(RsaKey* key)
 {
     if (key == NULL)
         return BAD_FUNC_ARG;

     XFREE(key->c_n,  key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
     XFREE(key->c_e,  key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
     XFREE(key->c_d,  key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
     XFREE(key->c_p,  key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
     XFREE(key->c_q,  key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
     XFREE(key->c_dP, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
     XFREE(key->c_dQ, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
     XFREE(key->c_u,  key->heap, DYNAMIC_TYPE_CAVIUM_TMP);

     return InitCaviumRsaKey(key, key->heap);  /* reset pointers */
 }


 static int CaviumRsaPublicEncrypt(const byte* in, word32 inLen, byte* out,
                                    word32 outLen, RsaKey* key)
 {
     word32 requestId;
     word32 ret;

     if (key == NULL || in == NULL || out == NULL || outLen < (word32)key->c_nSz)
         return -1;

     ret = CspPkcs1v15Enc(CAVIUM_BLOCKING, BT2, key->c_nSz, key->c_eSz,
                          (word16)inLen, key->c_n, key->c_e, (byte*)in, out,
                          &requestId, key->devId);
     if (ret != 0) {
         WOLFSSL_MSG("Cavium Enc BT2 failed");
         return -1;
     }
     return key->c_nSz;
 }


 static INLINE void ato16(const byte* c, word16* u16)
 {
     *u16 = (c[0] << 8) | (c[1]);
 }


 static int CaviumRsaPrivateDecrypt(const byte* in, word32 inLen, byte* out,
                                     word32 outLen, RsaKey* key)
 {
     word32 requestId;
     word32 ret;
     word16 outSz = (word16)outLen;

     if (key == NULL || in == NULL || out == NULL || inLen != (word32)key->c_nSz)
         return -1;

     ret = CspPkcs1v15CrtDec(CAVIUM_BLOCKING, BT2, key->c_nSz, key->c_q,
                             key->c_dQ, key->c_p, key->c_dP, key->c_u,
                             (byte*)in, &outSz, out, &requestId, key->devId);
     if (ret != 0) {
         WOLFSSL_MSG("Cavium CRT Dec BT2 failed");
         return -1;
     }
     ato16((const byte*)&outSz, &outSz);

     return outSz;
 }


 static int CaviumRsaSSL_Sign(const byte* in, word32 inLen, byte* out,
                              word32 outLen, RsaKey* key)
 {
     word32 requestId;
     word32 ret;

     if (key == NULL || in == NULL || out == NULL || inLen == 0 || outLen <
                                                              (word32)key->c_nSz)
         return -1;

     ret = CspPkcs1v15CrtEnc(CAVIUM_BLOCKING, BT1, key->c_nSz, (word16)inLen,
                             key->c_q, key->c_dQ, key->c_p, key->c_dP, key->c_u,
                             (byte*)in, out, &requestId, key->devId);
     if (ret != 0) {
         WOLFSSL_MSG("Cavium CRT Enc BT1 failed");
         return -1;
     }
     return key->c_nSz;
 }


 static int CaviumRsaSSL_Verify(const byte* in, word32 inLen, byte* out,
                                word32 outLen, RsaKey* key)
 {
     word32 requestId;
     word32 ret;
     word16 outSz = (word16)outLen;

     if (key == NULL || in == NULL || out == NULL || inLen != (word32)key->c_nSz)
         return -1;

     ret = CspPkcs1v15Dec(CAVIUM_BLOCKING, BT1, key->c_nSz, key->c_eSz,
                          key->c_n, key->c_e, (byte*)in, &outSz, out,
                          &requestId, key->devId);
     if (ret != 0) {
         WOLFSSL_MSG("Cavium Dec BT1 failed");
         return -1;
     }
     outSz = ntohs(outSz);

     return outSz;
 }


 #endif /* HAVE_CAVIUM */

 #endif /* HAVE_FIPS */
 #endif /* NO_RSA */
	/* rsa.c
	*
	* Copyright (C) 2006-2015 wolfSSL Inc.
	*
	* This file is part of wolfSSL. (formerly known as CyaSSL)
	*
	* wolfSSL is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation; either version 2 of the License, or
	* (at your option) any later version.
	*
	* wolfSSL is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
	*/

	#ifdef HAVE_CONFIG_H
	#include <config.h>
	#endif

	#include <wolfssl/wolfcrypt/settings.h>

	#ifndef NO_RSA

	#include <wolfssl/wolfcrypt/rsa.h>

	#ifdef HAVE_FIPS
	int wc_InitRsaKey(RsaKey* key, void* ptr)
	{
	return InitRsaKey_fips(key, ptr);
	}


	int wc_FreeRsaKey(RsaKey* key)
	{
	return FreeRsaKey_fips(key);
	}


	int wc_RsaPublicEncrypt(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key, RNG* rng)
	{
	return RsaPublicEncrypt_fips(in, inLen, out, outLen, key, rng);
	}


	int wc_RsaPrivateDecryptInline(byte* in, word32 inLen, byte** out,
	RsaKey* key)
	{
	return RsaPrivateDecryptInline_fips(in, inLen, out, key);
	}


	int wc_RsaPrivateDecrypt(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key)
	{
	return RsaPrivateDecrypt_fips(in, inLen, out, outLen, key);
	}


	int wc_RsaSSL_Sign(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key, RNG* rng)
	{
	return RsaSSL_Sign_fips(in, inLen, out, outLen, key, rng);
	}


	int wc_RsaSSL_VerifyInline(byte* in, word32 inLen, byte** out, RsaKey* key)
	{
	return RsaSSL_VerifyInline_fips(in, inLen, out, key);
	}


	int wc_RsaSSL_Verify(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key)
	{
	return RsaSSL_Verify_fips(in, inLen, out, outLen, key);
	}


	int wc_RsaEncryptSize(RsaKey* key)
	{
	return RsaEncryptSize_fips(key);
	}


	int wc_RsaFlattenPublicKey(RsaKey* key, byte* a, word32* aSz, byte* b,
	word32* bSz)
	{
	/* not specified as fips so not needing _fips */
	return RsaFlattenPublicKey(key, a, aSz, b, bSz);
	}
	#ifdef WOLFSSL_KEY_GEN
	int wc_MakeRsaKey(RsaKey* key, int size, long e, RNG* rng)
	{
	return MakeRsaKey(key, size, e, rng);
	}
	#endif


	#ifdef HAVE_CAVIUM
	int wc_RsaInitCavium(RsaKey* key, int i)
	{
	return RsaInitCavium(key, i);
	}


	void wc_RsaFreeCavium(RsaKey* key)
	{
	RsaFreeCavium(key);
	}
	#endif

	/* these are functions in asn and are routed to wolfssl/wolfcrypt/asn.c
	* wc_RsaPrivateKeyDecode
	* wc_RsaPublicKeyDecode
	*/

	#else /* else build without fips */
	#include <wolfssl/wolfcrypt/random.h>
	#include <wolfssl/wolfcrypt/error-crypt.h>
	#include <wolfssl/wolfcrypt/logging.h>
	#ifdef NO_INLINE
	#include <wolfssl/wolfcrypt/misc.h>
	#else
	#include <wolfcrypt/src/misc.c>
	#endif

	#ifdef SHOW_GEN
	#ifdef FREESCALE_MQX
	#include <fio.h>
	#else
	#include <stdio.h>
	#endif
	#endif

	#ifdef HAVE_CAVIUM
	static int InitCaviumRsaKey(RsaKey* key, void* heap);
	static int FreeCaviumRsaKey(RsaKey* key);
	static int CaviumRsaPublicEncrypt(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key);
	static int CaviumRsaPrivateDecrypt(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key);
	static int CaviumRsaSSL_Sign(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key);
	static int CaviumRsaSSL_Verify(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key);
	#endif

	enum {
	RSA_PUBLIC_ENCRYPT = 0,
	RSA_PUBLIC_DECRYPT = 1,
	RSA_PRIVATE_ENCRYPT = 2,
	RSA_PRIVATE_DECRYPT = 3,

	RSA_BLOCK_TYPE_1 = 1,
	RSA_BLOCK_TYPE_2 = 2,

	RSA_MIN_SIZE = 512,
	RSA_MAX_SIZE = 4096,

	RSA_MIN_PAD_SZ = 11 /* seperator + 0 + pad value + 8 pads */
	};


	int wc_InitRsaKey(RsaKey* key, void* heap)
	{
	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
	return InitCaviumRsaKey(key, heap);
	#endif

	key->type = -1; /* haven't decided yet */
	key->heap = heap;

	/* TomsFastMath doesn't use memory allocation */
	#ifndef USE_FAST_MATH
	key->n.dp = key->e.dp = 0; /* public alloc parts */

	key->d.dp = key->p.dp = 0; /* private alloc parts */
	key->q.dp = key->dP.dp = 0;
	key->u.dp = key->dQ.dp = 0;
	#else
	mp_init(&key->n);
	mp_init(&key->e);
	mp_init(&key->d);
	mp_init(&key->p);
	mp_init(&key->q);
	mp_init(&key->dP);
	mp_init(&key->dQ);
	mp_init(&key->u);
	#endif

	return 0;
	}


	int wc_FreeRsaKey(RsaKey* key)
	{
	(void)key;

	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
	return FreeCaviumRsaKey(key);
	#endif

	/* TomsFastMath doesn't use memory allocation */
	#ifndef USE_FAST_MATH
	if (key->type == RSA_PRIVATE) {
	mp_clear(&key->u);
	mp_clear(&key->dQ);
	mp_clear(&key->dP);
	mp_clear(&key->q);
	mp_clear(&key->p);
	mp_clear(&key->d);
	}
	mp_clear(&key->e);
	mp_clear(&key->n);
	#endif

	return 0;
	}

	static int wc_RsaPad(const byte* input, word32 inputLen, byte* pkcsBlock,
	word32 pkcsBlockLen, byte padValue, RNG* rng)
	{
	if (inputLen == 0)
	return 0;

	pkcsBlock[0] = 0x0; /* set first byte to zero and advance */
	pkcsBlock++; pkcsBlockLen--;
	pkcsBlock[0] = padValue; /* insert padValue */

	if (padValue == RSA_BLOCK_TYPE_1)
	/* pad with 0xff bytes */
	XMEMSET(&pkcsBlock[1], 0xFF, pkcsBlockLen - inputLen - 2);
	else {
	/* pad with non-zero random bytes */
	word32 padLen = pkcsBlockLen - inputLen - 1, i;
	int ret = wc_RNG_GenerateBlock(rng, &pkcsBlock[1], padLen);

	if (ret != 0)
	return ret;

	/* remove zeros */
	for (i = 1; i < padLen; i++)
	if (pkcsBlock[i] == 0) pkcsBlock[i] = 0x01;
	}

	pkcsBlock[pkcsBlockLen-inputLen-1] = 0; /* separator */
	XMEMCPY(pkcsBlock+pkcsBlockLen-inputLen, input, inputLen);

	return 0;
	}


	/* UnPad plaintext, set start to *output, return length of plaintext,
	* < 0 on error */
	static int RsaUnPad(const byte *pkcsBlock, unsigned int pkcsBlockLen,
	byte **output, byte padValue)
	{
	word32 maxOutputLen = (pkcsBlockLen > 10) ? (pkcsBlockLen - 10) : 0,
	invalid = 0,
	i = 1,
	outputLen;

	if (pkcsBlock[0] != 0x0) /* skip past zero */
	invalid = 1;
	pkcsBlock++; pkcsBlockLen--;

	/* Require block type padValue */
	invalid = (pkcsBlock[0] != padValue) \|\| invalid;

	/* verify the padding until we find the separator */
	if (padValue == RSA_BLOCK_TYPE_1) {
	while (i<pkcsBlockLen && pkcsBlock[i++] == 0xFF) {/* Null body */}
	}
	else {
	while (i<pkcsBlockLen && pkcsBlock[i++]) {/* Null body */}
	}

	if(!(i==pkcsBlockLen \|\| pkcsBlock[i-1]==0)) {
	WOLFSSL_MSG("RsaUnPad error, bad formatting");
	return RSA_PAD_E;
	}

	outputLen = pkcsBlockLen - i;
	invalid = (outputLen > maxOutputLen) \|\| invalid;

	if (invalid) {
	WOLFSSL_MSG("RsaUnPad error, bad formatting");
	return RSA_PAD_E;
	}

	output = (byte )(pkcsBlock + i);
	return outputLen;
	}


	static int wc_RsaFunction(const byte* in, word32 inLen, byte* out,
	word32* outLen, int type, RsaKey* key)
	{
	#define ERROR_OUT(x) { ret = (x); goto done;}

	mp_int tmp;
	int ret = 0;
	word32 keyLen, len;

	if (mp_init(&tmp) != MP_OKAY)
	return MP_INIT_E;

	if (mp_read_unsigned_bin(&tmp, (byte*)in, inLen) != MP_OKAY)
	ERROR_OUT(MP_READ_E);

	if (type == RSA_PRIVATE_DECRYPT \|\| type == RSA_PRIVATE_ENCRYPT) {
	#ifdef RSA_LOW_MEM /* half as much memory but twice as slow */
	if (mp_exptmod(&tmp, &key->d, &key->n, &tmp) != MP_OKAY)
	ERROR_OUT(MP_EXPTMOD_E);
	#else
	#define INNER_ERROR_OUT(x) { ret = (x); goto inner_done; }

	mp_int tmpa, tmpb;

	if (mp_init(&tmpa) != MP_OKAY)
	ERROR_OUT(MP_INIT_E);

	if (mp_init(&tmpb) != MP_OKAY) {
	mp_clear(&tmpa);
	ERROR_OUT(MP_INIT_E);
	}

	/* tmpa = tmp^dP mod p */
	if (mp_exptmod(&tmp, &key->dP, &key->p, &tmpa) != MP_OKAY)
	INNER_ERROR_OUT(MP_EXPTMOD_E);

	/* tmpb = tmp^dQ mod q */
	if (mp_exptmod(&tmp, &key->dQ, &key->q, &tmpb) != MP_OKAY)
	INNER_ERROR_OUT(MP_EXPTMOD_E);

	/* tmp = (tmpa - tmpb) * qInv (mod p) */
	if (mp_sub(&tmpa, &tmpb, &tmp) != MP_OKAY)
	INNER_ERROR_OUT(MP_SUB_E);

	if (mp_mulmod(&tmp, &key->u, &key->p, &tmp) != MP_OKAY)
	INNER_ERROR_OUT(MP_MULMOD_E);

	/* tmp = tmpb + q * tmp */
	if (mp_mul(&tmp, &key->q, &tmp) != MP_OKAY)
	INNER_ERROR_OUT(MP_MUL_E);

	if (mp_add(&tmp, &tmpb, &tmp) != MP_OKAY)
	INNER_ERROR_OUT(MP_ADD_E);

	inner_done:
	mp_clear(&tmpa);
	mp_clear(&tmpb);

	if (ret != 0) return ret;

	#endif /* RSA_LOW_MEM */
	}
	else if (type == RSA_PUBLIC_ENCRYPT \|\| type == RSA_PUBLIC_DECRYPT) {
	if (mp_exptmod(&tmp, &key->e, &key->n, &tmp) != MP_OKAY)
	ERROR_OUT(MP_EXPTMOD_E);
	}
	else
	ERROR_OUT(RSA_WRONG_TYPE_E);

	keyLen = mp_unsigned_bin_size(&key->n);
	if (keyLen > *outLen)
	ERROR_OUT(RSA_BUFFER_E);

	len = mp_unsigned_bin_size(&tmp);

	/* pad front w/ zeros to match key length */
	while (len < keyLen) {
	*out++ = 0x00;
	len++;
	}

	*outLen = keyLen;

	/* convert */
	if (mp_to_unsigned_bin(&tmp, out) != MP_OKAY)
	ERROR_OUT(MP_TO_E);

	done:
	mp_clear(&tmp);
	if (ret == MP_EXPTMOD_E) {
	WOLFSSL_MSG("RSA_FUNCTION MP_EXPTMOD_E: memory/config problem");
	}
	return ret;
	}


	int wc_RsaPublicEncrypt(const byte* in, word32 inLen, byte* out, word32 outLen,
	RsaKey* key, RNG* rng)
	{
	int sz, ret;

	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
	return CaviumRsaPublicEncrypt(in, inLen, out, outLen, key);
	#endif

	sz = mp_unsigned_bin_size(&key->n);
	if (sz > (int)outLen)
	return RSA_BUFFER_E;

	if (inLen > (word32)(sz - RSA_MIN_PAD_SZ))
	return RSA_BUFFER_E;

	ret = wc_RsaPad(in, inLen, out, sz, RSA_BLOCK_TYPE_2, rng);
	if (ret != 0)
	return ret;

	if ((ret = wc_RsaFunction(out, sz, out, &outLen,
	RSA_PUBLIC_ENCRYPT, key)) < 0)
	sz = ret;

	return sz;
	}


	int wc_RsaPrivateDecryptInline(byte* in, word32 inLen, byte** out, RsaKey* key)
	{
	int ret;

	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC) {
	ret = CaviumRsaPrivateDecrypt(in, inLen, in, inLen, key);
	if (ret > 0)
	*out = in;
	return ret;
	}
	#endif

	if ((ret = wc_RsaFunction(in, inLen, in, &inLen, RSA_PRIVATE_DECRYPT, key))
	< 0) {
	return ret;
	}

	return RsaUnPad(in, inLen, out, RSA_BLOCK_TYPE_2);
	}


	int wc_RsaPrivateDecrypt(const byte* in, word32 inLen, byte* out, word32 outLen,
	RsaKey* key)
	{
	int plainLen;
	byte* tmp;
	byte* pad = 0;

	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
	return CaviumRsaPrivateDecrypt(in, inLen, out, outLen, key);
	#endif

	tmp = (byte*)XMALLOC(inLen, key->heap, DYNAMIC_TYPE_RSA);
	if (tmp == NULL) {
	return MEMORY_E;
	}

	XMEMCPY(tmp, in, inLen);

	if ( (plainLen = wc_RsaPrivateDecryptInline(tmp, inLen, &pad, key) ) < 0) {
	XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);
	return plainLen;
	}
	if (plainLen > (int)outLen)
	plainLen = BAD_FUNC_ARG;
	else
	XMEMCPY(out, pad, plainLen);

	ForceZero(tmp, inLen);
	XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);

	return plainLen;
	}


	/* for Rsa Verify */
	int wc_RsaSSL_VerifyInline(byte* in, word32 inLen, byte** out, RsaKey* key)
	{
	int ret;

	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC) {
	ret = CaviumRsaSSL_Verify(in, inLen, in, inLen, key);
	if (ret > 0)
	*out = in;
	return ret;
	}
	#endif

	if ((ret = wc_RsaFunction(in, inLen, in, &inLen, RSA_PUBLIC_DECRYPT, key))
	< 0) {
	return ret;
	}

	return RsaUnPad(in, inLen, out, RSA_BLOCK_TYPE_1);
	}


	int wc_RsaSSL_Verify(const byte* in, word32 inLen, byte* out, word32 outLen,
	RsaKey* key)
	{
	int plainLen;
	byte* tmp;
	byte* pad = 0;

	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
	return CaviumRsaSSL_Verify(in, inLen, out, outLen, key);
	#endif

	tmp = (byte*)XMALLOC(inLen, key->heap, DYNAMIC_TYPE_RSA);
	if (tmp == NULL) {
	return MEMORY_E;
	}

	XMEMCPY(tmp, in, inLen);

	if ( (plainLen = wc_RsaSSL_VerifyInline(tmp, inLen, &pad, key) ) < 0) {
	XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);
	return plainLen;
	}

	if (plainLen > (int)outLen)
	plainLen = BAD_FUNC_ARG;
	else
	XMEMCPY(out, pad, plainLen);

	ForceZero(tmp, inLen);
	XFREE(tmp, key->heap, DYNAMIC_TYPE_RSA);

	return plainLen;
	}


	/* for Rsa Sign */
	int wc_RsaSSL_Sign(const byte* in, word32 inLen, byte* out, word32 outLen,
	RsaKey* key, RNG* rng)
	{
	int sz, ret;

	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
	return CaviumRsaSSL_Sign(in, inLen, out, outLen, key);
	#endif

	sz = mp_unsigned_bin_size(&key->n);
	if (sz > (int)outLen)
	return RSA_BUFFER_E;

	if (inLen > (word32)(sz - RSA_MIN_PAD_SZ))
	return RSA_BUFFER_E;

	ret = wc_RsaPad(in, inLen, out, sz, RSA_BLOCK_TYPE_1, rng);
	if (ret != 0)
	return ret;

	if ((ret = wc_RsaFunction(out, sz, out, &outLen,
	RSA_PRIVATE_ENCRYPT,key)) < 0)
	sz = ret;

	return sz;
	}


	int wc_RsaEncryptSize(RsaKey* key)
	{
	#ifdef HAVE_CAVIUM
	if (key->magic == WOLFSSL_RSA_CAVIUM_MAGIC)
	return key->c_nSz;
	#endif
	return mp_unsigned_bin_size(&key->n);
	}

	/* flatten RsaKey structure into individual elements (e, n) */
	int wc_RsaFlattenPublicKey(RsaKey* key, byte* e, word32* eSz, byte* n,
	word32* nSz)
	{
	int sz, ret;

	if (key == NULL \|\| e == NULL \|\| eSz == NULL \|\| n == NULL \|\| nSz == NULL)
	return BAD_FUNC_ARG;

	sz = mp_unsigned_bin_size(&key->e);
	if ((word32)sz > *nSz)
	return RSA_BUFFER_E;
	ret = mp_to_unsigned_bin(&key->e, e);
	if (ret != MP_OKAY)
	return ret;
	*eSz = (word32)sz;

	sz = mp_unsigned_bin_size(&key->n);
	if ((word32)sz > *nSz)
	return RSA_BUFFER_E;
	ret = mp_to_unsigned_bin(&key->n, n);
	if (ret != MP_OKAY)
	return ret;
	*nSz = (word32)sz;

	return 0;
	}


	#ifdef WOLFSSL_KEY_GEN

	static const int USE_BBS = 1;

	static int rand_prime(mp_int* N, int len, RNG* rng, void* heap)
	{
	int err, res, type;
	byte* buf;

	(void)heap;
	if (N == NULL \|\| rng == NULL)
	return BAD_FUNC_ARG;

	/* get type */
	if (len < 0) {
	type = USE_BBS;
	len = -len;
	} else {
	type = 0;
	}

	/* allow sizes between 2 and 512 bytes for a prime size */
	if (len < 2 \|\| len > 512) {
	return BAD_FUNC_ARG;
	}

	/* allocate buffer to work with */
	buf = (byte*)XMALLOC(len, heap, DYNAMIC_TYPE_RSA);
	if (buf == NULL) {
	return MEMORY_E;
	}
	XMEMSET(buf, 0, len);

	do {
	#ifdef SHOW_GEN
	printf(".");
	fflush(stdout);
	#endif
	/* generate value */
	err = wc_RNG_GenerateBlock(rng, buf, len);
	if (err != 0) {
	XFREE(buf, heap, DYNAMIC_TYPE_RSA);
	return err;
	}

	/* munge bits */
	buf[0] \|= 0x80 \| 0x40;
	buf[len-1] \|= 0x01 \| ((type & USE_BBS) ? 0x02 : 0x00);

	/* load value */
	if ((err = mp_read_unsigned_bin(N, buf, len)) != MP_OKAY) {
	XFREE(buf, heap, DYNAMIC_TYPE_RSA);
	return err;
	}

	/* test */
	if ((err = mp_prime_is_prime(N, 8, &res)) != MP_OKAY) {
	XFREE(buf, heap, DYNAMIC_TYPE_RSA);
	return err;
	}
	} while (res == MP_NO);

	ForceZero(buf, len);
	XFREE(buf, heap, DYNAMIC_TYPE_RSA);

	return 0;
	}


	/* Make an RSA key for size bits, with e specified, 65537 is a good e */
	int wc_MakeRsaKey(RsaKey* key, int size, long e, RNG* rng)
	{
	mp_int p, q, tmp1, tmp2, tmp3;
	int err;

	if (key == NULL \|\| rng == NULL)
	return BAD_FUNC_ARG;

	if (size < RSA_MIN_SIZE \|\| size > RSA_MAX_SIZE)
	return BAD_FUNC_ARG;

	if (e < 3 \|\| (e & 1) == 0)
	return BAD_FUNC_ARG;

	if ((err = mp_init_multi(&p, &q, &tmp1, &tmp2, &tmp3, NULL)) != MP_OKAY)
	return err;

	err = mp_set_int(&tmp3, e);

	/* make p */
	if (err == MP_OKAY) {
	do {
	err = rand_prime(&p, size/16, rng, key->heap); /* size in bytes/2 */

	if (err == MP_OKAY)
	err = mp_sub_d(&p, 1, &tmp1); /* tmp1 = p-1 */

	if (err == MP_OKAY)
	err = mp_gcd(&tmp1, &tmp3, &tmp2); /* tmp2 = gcd(p-1, e) */
	} while (err == MP_OKAY && mp_cmp_d(&tmp2, 1) != 0); /* e divdes p-1 */
	}

	/* make q */
	if (err == MP_OKAY) {
	do {
	err = rand_prime(&q, size/16, rng, key->heap); /* size in bytes/2 */

	if (err == MP_OKAY)
	err = mp_sub_d(&q, 1, &tmp1); /* tmp1 = q-1 */

	if (err == MP_OKAY)
	err = mp_gcd(&tmp1, &tmp3, &tmp2); /* tmp2 = gcd(q-1, e) */
	} while (err == MP_OKAY && mp_cmp_d(&tmp2, 1) != 0); /* e divdes q-1 */
	}

	if (err == MP_OKAY)
	err = mp_init_multi(&key->n, &key->e, &key->d, &key->p, &key->q, NULL);

	if (err == MP_OKAY)
	err = mp_init_multi(&key->dP, &key->dQ, &key->u, NULL, NULL, NULL);

	if (err == MP_OKAY)
	err = mp_sub_d(&p, 1, &tmp2); /* tmp2 = p-1 */

	if (err == MP_OKAY)
	err = mp_lcm(&tmp1, &tmp2, &tmp1); /* tmp1 = lcm(p-1, q-1),last loop */

	/* make key */
	if (err == MP_OKAY)
	err = mp_set_int(&key->e, e); /* key->e = e */

	if (err == MP_OKAY) /* key->d = 1/e mod lcm(p-1, q-1) */
	err = mp_invmod(&key->e, &tmp1, &key->d);

	if (err == MP_OKAY)
	err = mp_mul(&p, &q, &key->n); /* key->n = pq */

	if (err == MP_OKAY)
	err = mp_sub_d(&p, 1, &tmp1);

	if (err == MP_OKAY)
	err = mp_sub_d(&q, 1, &tmp2);

	if (err == MP_OKAY)
	err = mp_mod(&key->d, &tmp1, &key->dP);

	if (err == MP_OKAY)
	err = mp_mod(&key->d, &tmp2, &key->dQ);

	if (err == MP_OKAY)
	err = mp_invmod(&q, &p, &key->u);

	if (err == MP_OKAY)
	err = mp_copy(&p, &key->p);

	if (err == MP_OKAY)
	err = mp_copy(&q, &key->q);

	if (err == MP_OKAY)
	key->type = RSA_PRIVATE;

	mp_clear(&tmp3);
	mp_clear(&tmp2);
	mp_clear(&tmp1);
	mp_clear(&q);
	mp_clear(&p);

	if (err != MP_OKAY) {
	wc_FreeRsaKey(key);
	return err;
	}

	return 0;
	}


	#endif /* WOLFSSL_KEY_GEN */


	#ifdef HAVE_CAVIUM

	#include <cyassl/ctaocrypt/logging.h>
	#include "cavium_common.h"

	/* Initiliaze RSA for use with Nitrox device */
	int RsaInitCavium(RsaKey* rsa, int devId)
	{
	if (rsa == NULL)
	return -1;

	if (CspAllocContext(CONTEXT_SSL, &rsa->contextHandle, devId) != 0)
	return -1;

	rsa->devId = devId;
	rsa->magic = WOLFSSL_RSA_CAVIUM_MAGIC;

	return 0;
	}


	/* Free RSA from use with Nitrox device */
	void wc_RsaFreeCavium(RsaKey* rsa)
	{
	if (rsa == NULL)
	return;

	CspFreeContext(CONTEXT_SSL, rsa->contextHandle, rsa->devId);
	rsa->magic = 0;
	}


	/* Initialize cavium RSA key */
	static int InitCaviumRsaKey(RsaKey* key, void* heap)
	{
	if (key == NULL)
	return BAD_FUNC_ARG;

	key->heap = heap;
	key->type = -1; /* don't know yet */

	key->c_n = NULL;
	key->c_e = NULL;
	key->c_d = NULL;
	key->c_p = NULL;
	key->c_q = NULL;
	key->c_dP = NULL;
	key->c_dQ = NULL;
	key->c_u = NULL;

	key->c_nSz = 0;
	key->c_eSz = 0;
	key->c_dSz = 0;
	key->c_pSz = 0;
	key->c_qSz = 0;
	key->c_dP_Sz = 0;
	key->c_dQ_Sz = 0;
	key->c_uSz = 0;

	return 0;
	}


	/* Free cavium RSA key */
	static int FreeCaviumRsaKey(RsaKey* key)
	{
	if (key == NULL)
	return BAD_FUNC_ARG;

	XFREE(key->c_n, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
	XFREE(key->c_e, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
	XFREE(key->c_d, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
	XFREE(key->c_p, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
	XFREE(key->c_q, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
	XFREE(key->c_dP, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
	XFREE(key->c_dQ, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);
	XFREE(key->c_u, key->heap, DYNAMIC_TYPE_CAVIUM_TMP);

	return InitCaviumRsaKey(key, key->heap); /* reset pointers */
	}


	static int CaviumRsaPublicEncrypt(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key)
	{
	word32 requestId;
	word32 ret;

	if (key == NULL \|\| in == NULL \|\| out == NULL \|\| outLen < (word32)key->c_nSz)
	return -1;

	ret = CspPkcs1v15Enc(CAVIUM_BLOCKING, BT2, key->c_nSz, key->c_eSz,
	(word16)inLen, key->c_n, key->c_e, (byte*)in, out,
	&requestId, key->devId);
	if (ret != 0) {
	WOLFSSL_MSG("Cavium Enc BT2 failed");
	return -1;
	}
	return key->c_nSz;
	}


	static INLINE void ato16(const byte* c, word16* u16)
	{
	*u16 = (c[0] << 8) \| (c[1]);
	}


	static int CaviumRsaPrivateDecrypt(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key)
	{
	word32 requestId;
	word32 ret;
	word16 outSz = (word16)outLen;

	if (key == NULL \|\| in == NULL \|\| out == NULL \|\| inLen != (word32)key->c_nSz)
	return -1;

	ret = CspPkcs1v15CrtDec(CAVIUM_BLOCKING, BT2, key->c_nSz, key->c_q,
	key->c_dQ, key->c_p, key->c_dP, key->c_u,
	(byte*)in, &outSz, out, &requestId, key->devId);
	if (ret != 0) {
	WOLFSSL_MSG("Cavium CRT Dec BT2 failed");
	return -1;
	}
	ato16((const byte*)&outSz, &outSz);

	return outSz;
	}


	static int CaviumRsaSSL_Sign(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key)
	{
	word32 requestId;
	word32 ret;

	if (key == NULL \|\| in == NULL \|\| out == NULL \|\| inLen == 0 \|\| outLen <
	(word32)key->c_nSz)
	return -1;

	ret = CspPkcs1v15CrtEnc(CAVIUM_BLOCKING, BT1, key->c_nSz, (word16)inLen,
	key->c_q, key->c_dQ, key->c_p, key->c_dP, key->c_u,
	(byte*)in, out, &requestId, key->devId);
	if (ret != 0) {
	WOLFSSL_MSG("Cavium CRT Enc BT1 failed");
	return -1;
	}
	return key->c_nSz;
	}


	static int CaviumRsaSSL_Verify(const byte* in, word32 inLen, byte* out,
	word32 outLen, RsaKey* key)
	{
	word32 requestId;
	word32 ret;
	word16 outSz = (word16)outLen;

	if (key == NULL \|\| in == NULL \|\| out == NULL \|\| inLen != (word32)key->c_nSz)
	return -1;

	ret = CspPkcs1v15Dec(CAVIUM_BLOCKING, BT1, key->c_nSz, key->c_eSz,
	key->c_n, key->c_e, (byte*)in, &outSz, out,
	&requestId, key->devId);
	if (ret != 0) {
	WOLFSSL_MSG("Cavium Dec BT1 failed");
	return -1;
	}
	outSz = ntohs(outSz);

	return outSz;
	}


	#endif /* HAVE_CAVIUM */

	#endif /* HAVE_FIPS */
	#endif /* NO_RSA */