/* sha512.c
 *
 * Copyright (C) 2006-2017 wolfSSL Inc.
 *
 * This file is part of wolfSSL.
 *
 * 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 02110-1335, USA
 */


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

#include <wolfssl/wolfcrypt/settings.h>

#ifdef WOLFSSL_SHA512
#include <wolfssl/wolfcrypt/sha512.h>
#include <wolfssl/wolfcrypt/error-crypt.h>
#include <wolfssl/wolfcrypt/cpuid.h>

/* fips wrapper calls, user can call direct */
#ifdef HAVE_FIPS
    int wc_InitSha512(wc_Sha512* sha)
    {
        if (sha == NULL) {
            return BAD_FUNC_ARG;
        }

        return InitSha512_fips(sha);
    }
    int wc_InitSha512_ex(wc_Sha512* sha, void* heap, int devId)
    {
        (void)heap;
        (void)devId;
        if (sha == NULL) {
            return BAD_FUNC_ARG;
        }
        return InitSha512_fips(sha);
    }
    int wc_Sha512Update(wc_Sha512* sha, const byte* data, word32 len)
    {
        if (sha == NULL || (data == NULL && len > 0)) {
            return BAD_FUNC_ARG;
        }

        return Sha512Update_fips(sha, data, len);
    }
    int wc_Sha512Final(wc_Sha512* sha, byte* out)
    {
        if (sha == NULL || out == NULL) {
            return BAD_FUNC_ARG;
        }

        return Sha512Final_fips(sha, out);
    }
    void wc_Sha512Free(wc_Sha512* sha)
    {
        (void)sha;
        /* Not supported in FIPS */
    }

    #if defined(WOLFSSL_SHA384) || defined(HAVE_AESGCM)
        int wc_InitSha384(wc_Sha384* sha)
        {
            if (sha == NULL) {
                return BAD_FUNC_ARG;
            }
            return InitSha384_fips(sha);
        }
        int wc_InitSha384_ex(wc_Sha384* sha, void* heap, int devId)
        {
            (void)heap;
            (void)devId;
            if (sha == NULL) {
                return BAD_FUNC_ARG;
            }
            return InitSha384_fips(sha);
        }
        int wc_Sha384Update(wc_Sha384* sha, const byte* data, word32 len)
        {
            if (sha == NULL || (data == NULL && len > 0)) {
                return BAD_FUNC_ARG;
            }
            return Sha384Update_fips(sha, data, len);
        }
        int wc_Sha384Final(wc_Sha384* sha, byte* out)
        {
            if (sha == NULL || out == NULL) {
                return BAD_FUNC_ARG;
            }
            return Sha384Final_fips(sha, out);
        }
        void wc_Sha384Free(wc_Sha384* sha)
        {
            (void)sha;
            /* Not supported in FIPS */
        }
    #endif /* WOLFSSL_SHA384 || HAVE_AESGCM */

#else /* else build without using fips */

#include <wolfssl/wolfcrypt/logging.h>

#ifdef NO_INLINE
    #include <wolfssl/wolfcrypt/misc.h>
#else
    #define WOLFSSL_MISC_INCLUDED
    #include <wolfcrypt/src/misc.c>
#endif


#if defined(USE_INTEL_SPEEDUP)
    #define HAVE_INTEL_AVX1
    #define HAVE_INTEL_AVX2
#endif

#if defined(HAVE_INTEL_AVX1)
    /* #define DEBUG_XMM  */
#endif

#if defined(HAVE_INTEL_AVX2)
    #define HAVE_INTEL_RORX
    /* #define DEBUG_YMM  */
#endif


#if defined(HAVE_INTEL_RORX)
    #define ROTR(func, bits, x) \
    word64 func(word64 x) {  word64 ret ;\
        __asm__ ("rorx $"#bits", %1, %0\n\t":"=r"(ret):"r"(x)) ;\
        return ret ;\
    }

    static INLINE ROTR(rotrFixed64_28, 28, x);
    static INLINE ROTR(rotrFixed64_34, 34, x);
    static INLINE ROTR(rotrFixed64_39, 39, x);
    static INLINE ROTR(rotrFixed64_14, 14, x);
    static INLINE ROTR(rotrFixed64_18, 18, x);
    static INLINE ROTR(rotrFixed64_41, 41, x);

    #define S0_RORX(x) (rotrFixed64_28(x)^rotrFixed64_34(x)^rotrFixed64_39(x))
    #define S1_RORX(x) (rotrFixed64_14(x)^rotrFixed64_18(x)^rotrFixed64_41(x))
#endif /* HAVE_INTEL_RORX */

#if defined(HAVE_BYTEREVERSE64) && \
        !defined(HAVE_INTEL_AVX1) && !defined(HAVE_INTEL_AVX2)
    #define ByteReverseWords64(out, in, size) ByteReverseWords64_1(out, size)
    #define ByteReverseWords64_1(buf, size) \
        { unsigned int i ;\
            for(i=0; i< size/sizeof(word64); i++){\
                __asm__ volatile("bswapq %0":"+r"(buf[i])::) ;\
            }\
        }
#endif

static int InitSha512(wc_Sha512* sha512)
{
    if (sha512 == NULL)
        return BAD_FUNC_ARG;

    sha512->digest[0] = W64LIT(0x6a09e667f3bcc908);
    sha512->digest[1] = W64LIT(0xbb67ae8584caa73b);
    sha512->digest[2] = W64LIT(0x3c6ef372fe94f82b);
    sha512->digest[3] = W64LIT(0xa54ff53a5f1d36f1);
    sha512->digest[4] = W64LIT(0x510e527fade682d1);
    sha512->digest[5] = W64LIT(0x9b05688c2b3e6c1f);
    sha512->digest[6] = W64LIT(0x1f83d9abfb41bd6b);
    sha512->digest[7] = W64LIT(0x5be0cd19137e2179);

    sha512->buffLen = 0;
    sha512->loLen   = 0;
    sha512->hiLen   = 0;

    return 0;
}


/* Hardware Acceleration */
#if defined(HAVE_INTEL_AVX1) || defined(HAVE_INTEL_AVX2)

    /*****
    Intel AVX1/AVX2 Macro Control Structure

    #if defined(HAVE_INteL_SPEEDUP)
        #define HAVE_INTEL_AVX1
        #define HAVE_INTEL_AVX2
    #endif

    int InitSha512(wc_Sha512* sha512) {
         Save/Recover XMM, YMM
         ...

         Check Intel AVX cpuid flags
    }

    #if defined(HAVE_INTEL_AVX1)|| defined(HAVE_INTEL_AVX2)
      Transform_AVX1(); # Function prototype
      Transform_AVX2(); #
    #endif

      _Transform() {     # Native Transform Function body

      }

      int Sha512Update() {
         Save/Recover XMM, YMM
         ...
      }

      int Sha512Final() {
         Save/Recover XMM, YMM
         ...
      }


    #if defined(HAVE_INTEL_AVX1)

       XMM Instructions/INLINE asm Definitions

    #endif

    #if defined(HAVE_INTEL_AVX2)

       YMM Instructions/INLINE asm Definitions

    #endif

    #if defnied(HAVE_INTEL_AVX1)

      int Transform_AVX1() {
          Stitched Message Sched/Round
      }

    #endif

    #if defnied(HAVE_INTEL_AVX2)

      int Transform_AVX2() {
          Stitched Message Sched/Round
      }
    #endif

    */


    /* Each platform needs to query info type 1 from cpuid to see if aesni is
     * supported. Also, let's setup a macro for proper linkage w/o ABI conflicts
     */

    #if defined(HAVE_INTEL_AVX1)
        static int Transform_AVX1(wc_Sha512 *sha512);
    #endif
    #if defined(HAVE_INTEL_AVX2)
        static int Transform_AVX2(wc_Sha512 *sha512);
        #if defined(HAVE_INTEL_AVX1) && defined(HAVE_INTEL_AVX2) && defined(HAVE_INTEL_RORX)
            static int Transform_AVX1_RORX(wc_Sha512 *sha512);
        #endif
    #endif
    static int _Transform(wc_Sha512 *sha512);
    static int (*Transform_p)(wc_Sha512* sha512) = _Transform;
    static int transform_check = 0;
    static int intel_flags;
    #define Transform(sha512) (*Transform_p)(sha512)

    /* Dummy for saving MM_REGs on behalf of Transform */
    /* #if defined(HAVE_INTEL_AVX2)
     #define SAVE_XMM_YMM   __asm__ volatile("orq %%r8, %%r8":::\
       "%ymm0","%ymm1","%ymm2","%ymm3","%ymm4","%ymm5","%ymm6","%ymm7","%ymm8","%ymm9","%ymm10","%ymm11",\
       "%ymm12","%ymm13","%ymm14","%ymm15")
    */
    #if defined(HAVE_INTEL_AVX1)
        #define SAVE_XMM_YMM   __asm__ volatile("orq %%r8, %%r8":::\
            "xmm0","xmm1","xmm2","xmm3","xmm4","xmm5","xmm6","xmm7","xmm8","xmm9","xmm10","xmm11","xmm12","xmm13","xmm14","xmm15")
    #endif

    static void Sha512_SetTransform()
    {
        if (transform_check)
            return;

        intel_flags = cpuid_get_flags();

    #if defined(HAVE_INTEL_AVX2)
        if (IS_INTEL_AVX2(intel_flags) && IS_INTEL_BMI2(intel_flags)) {
            if (1)
                Transform_p = Transform_AVX1_RORX;
            else
                Transform_p = Transform_AVX2;
        }
        else
    #endif
    #if defined(HAVE_INTEL_AVX1)
        if (1) {
            Transform_p = ((IS_INTEL_AVX1(intel_flags)) ? Transform_AVX1 :
                                                                    _Transform);
        }
        else
    #endif
            Transform_p = _Transform;

        transform_check = 1;
    }

    int wc_InitSha512_ex(wc_Sha512* sha512, void* heap, int devId)
    {
        int ret = InitSha512(sha512);

        (void)heap;
        (void)devId;

        Sha512_SetTransform();

        return ret;
    }

#else
    #define Transform(sha512) _Transform(sha512)

    int wc_InitSha512_ex(wc_Sha512* sha512, void* heap, int devId)
    {
        int ret = 0;

        if (sha512 == NULL)
            return BAD_FUNC_ARG;

        sha512->heap = heap;

        ret = InitSha512(sha512);
        if (ret != 0)
            return ret;

    #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA512)
        ret = wolfAsync_DevCtxInit(&sha512->asyncDev,
                            WOLFSSL_ASYNC_MARKER_SHA512, sha512->heap, devId);
    #else
        (void)devId;
    #endif /* WOLFSSL_ASYNC_CRYPT */

        return ret;
    }

#endif /* Hardware Acceleration */

#ifndef SAVE_XMM_YMM
    #define SAVE_XMM_YMM
#endif

static const word64 K512[80] = {
    W64LIT(0x428a2f98d728ae22), W64LIT(0x7137449123ef65cd),
    W64LIT(0xb5c0fbcfec4d3b2f), W64LIT(0xe9b5dba58189dbbc),
    W64LIT(0x3956c25bf348b538), W64LIT(0x59f111f1b605d019),
    W64LIT(0x923f82a4af194f9b), W64LIT(0xab1c5ed5da6d8118),
    W64LIT(0xd807aa98a3030242), W64LIT(0x12835b0145706fbe),
    W64LIT(0x243185be4ee4b28c), W64LIT(0x550c7dc3d5ffb4e2),
    W64LIT(0x72be5d74f27b896f), W64LIT(0x80deb1fe3b1696b1),
    W64LIT(0x9bdc06a725c71235), W64LIT(0xc19bf174cf692694),
    W64LIT(0xe49b69c19ef14ad2), W64LIT(0xefbe4786384f25e3),
    W64LIT(0x0fc19dc68b8cd5b5), W64LIT(0x240ca1cc77ac9c65),
    W64LIT(0x2de92c6f592b0275), W64LIT(0x4a7484aa6ea6e483),
    W64LIT(0x5cb0a9dcbd41fbd4), W64LIT(0x76f988da831153b5),
    W64LIT(0x983e5152ee66dfab), W64LIT(0xa831c66d2db43210),
    W64LIT(0xb00327c898fb213f), W64LIT(0xbf597fc7beef0ee4),
    W64LIT(0xc6e00bf33da88fc2), W64LIT(0xd5a79147930aa725),
    W64LIT(0x06ca6351e003826f), W64LIT(0x142929670a0e6e70),
    W64LIT(0x27b70a8546d22ffc), W64LIT(0x2e1b21385c26c926),
    W64LIT(0x4d2c6dfc5ac42aed), W64LIT(0x53380d139d95b3df),
    W64LIT(0x650a73548baf63de), W64LIT(0x766a0abb3c77b2a8),
    W64LIT(0x81c2c92e47edaee6), W64LIT(0x92722c851482353b),
    W64LIT(0xa2bfe8a14cf10364), W64LIT(0xa81a664bbc423001),
    W64LIT(0xc24b8b70d0f89791), W64LIT(0xc76c51a30654be30),
    W64LIT(0xd192e819d6ef5218), W64LIT(0xd69906245565a910),
    W64LIT(0xf40e35855771202a), W64LIT(0x106aa07032bbd1b8),
    W64LIT(0x19a4c116b8d2d0c8), W64LIT(0x1e376c085141ab53),
    W64LIT(0x2748774cdf8eeb99), W64LIT(0x34b0bcb5e19b48a8),
    W64LIT(0x391c0cb3c5c95a63), W64LIT(0x4ed8aa4ae3418acb),
    W64LIT(0x5b9cca4f7763e373), W64LIT(0x682e6ff3d6b2b8a3),
    W64LIT(0x748f82ee5defb2fc), W64LIT(0x78a5636f43172f60),
    W64LIT(0x84c87814a1f0ab72), W64LIT(0x8cc702081a6439ec),
    W64LIT(0x90befffa23631e28), W64LIT(0xa4506cebde82bde9),
    W64LIT(0xbef9a3f7b2c67915), W64LIT(0xc67178f2e372532b),
    W64LIT(0xca273eceea26619c), W64LIT(0xd186b8c721c0c207),
    W64LIT(0xeada7dd6cde0eb1e), W64LIT(0xf57d4f7fee6ed178),
    W64LIT(0x06f067aa72176fba), W64LIT(0x0a637dc5a2c898a6),
    W64LIT(0x113f9804bef90dae), W64LIT(0x1b710b35131c471b),
    W64LIT(0x28db77f523047d84), W64LIT(0x32caab7b40c72493),
    W64LIT(0x3c9ebe0a15c9bebc), W64LIT(0x431d67c49c100d4c),
    W64LIT(0x4cc5d4becb3e42b6), W64LIT(0x597f299cfc657e2a),
    W64LIT(0x5fcb6fab3ad6faec), W64LIT(0x6c44198c4a475817)
};



#define blk0(i) (W[i] = sha512->buffer[i])

#define blk2(i) (W[i&15]+=s1(W[(i-2)&15])+W[(i-7)&15]+s0(W[(i-15)&15]))

#define Ch(x,y,z) (z^(x&(y^z)))
#define Maj(x,y,z) ((x&y)|(z&(x|y)))

#define a(i) T[(0-i)&7]
#define b(i) T[(1-i)&7]
#define c(i) T[(2-i)&7]
#define d(i) T[(3-i)&7]
#define e(i) T[(4-i)&7]
#define f(i) T[(5-i)&7]
#define g(i) T[(6-i)&7]
#define h(i) T[(7-i)&7]

#define S0(x) (rotrFixed64(x,28)^rotrFixed64(x,34)^rotrFixed64(x,39))
#define S1(x) (rotrFixed64(x,14)^rotrFixed64(x,18)^rotrFixed64(x,41))
#define s0(x) (rotrFixed64(x,1)^rotrFixed64(x,8)^(x>>7))
#define s1(x) (rotrFixed64(x,19)^rotrFixed64(x,61)^(x>>6))

#define R(i) h(i)+=S1(e(i))+Ch(e(i),f(i),g(i))+K[i+j]+(j?blk2(i):blk0(i));\
    d(i)+=h(i);h(i)+=S0(a(i))+Maj(a(i),b(i),c(i))

static int _Transform(wc_Sha512* sha512)
{
    const word64* K = K512;

    word32 j;
    word64 T[8];


#ifdef WOLFSSL_SMALL_STACK
    word64* W;
    W = (word64*) XMALLOC(sizeof(word64) * 16, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (W == NULL)
        return MEMORY_E;
#else
    word64 W[16];
#endif

    /* Copy digest to working vars */
    XMEMCPY(T, sha512->digest, sizeof(T));

#ifdef USE_SLOW_SHA2
    /* over twice as small, but 50% slower */
    /* 80 operations, not unrolled */
    for (j = 0; j < 80; j += 16) {
        int m;
        for (m = 0; m < 16; m++) { /* braces needed here for macros {} */
            R(m);
        }
    }
#else
    /* 80 operations, partially loop unrolled */
    for (j = 0; j < 80; j += 16) {
        R( 0); R( 1); R( 2); R( 3);
        R( 4); R( 5); R( 6); R( 7);
        R( 8); R( 9); R(10); R(11);
        R(12); R(13); R(14); R(15);
    }
#endif /* USE_SLOW_SHA2 */

    /* Add the working vars back into digest */

    sha512->digest[0] += a(0);
    sha512->digest[1] += b(0);
    sha512->digest[2] += c(0);
    sha512->digest[3] += d(0);
    sha512->digest[4] += e(0);
    sha512->digest[5] += f(0);
    sha512->digest[6] += g(0);
    sha512->digest[7] += h(0);

    /* Wipe variables */
    ForceZero(W, sizeof(word64) * 16);
    ForceZero(T, sizeof(T));

#ifdef WOLFSSL_SMALL_STACK
    XFREE(W, NULL, DYNAMIC_TYPE_TMP_BUFFER);
#endif

    return 0;
}


static INLINE void AddLength(wc_Sha512* sha512, word32 len)
{
    word64 tmp = sha512->loLen;
    if ( (sha512->loLen += len) < tmp)
        sha512->hiLen++;                       /* carry low to high */
}

static INLINE int Sha512Update(wc_Sha512* sha512, const byte* data, word32 len)
{
    int ret = 0;
    /* do block size increments */
    byte* local = (byte*)sha512->buffer;

    /* check that internal buffLen is valid */
    if (sha512->buffLen >= WC_SHA512_BLOCK_SIZE)
        return BUFFER_E;

    SAVE_XMM_YMM; /* for Intel AVX */

    while (len) {
        word32 add = min(len, WC_SHA512_BLOCK_SIZE - sha512->buffLen);
        XMEMCPY(&local[sha512->buffLen], data, add);

        sha512->buffLen += add;
        data            += add;
        len             -= add;

        if (sha512->buffLen == WC_SHA512_BLOCK_SIZE) {
    #if defined(LITTLE_ENDIAN_ORDER)
        #if defined(HAVE_INTEL_AVX1) || defined(HAVE_INTEL_AVX2)
            if (!IS_INTEL_AVX1(intel_flags) && !IS_INTEL_AVX2(intel_flags))
        #endif
            {
                ByteReverseWords64(sha512->buffer, sha512->buffer,
                                                             WC_SHA512_BLOCK_SIZE);
            }
    #endif
            ret = Transform(sha512);
            if (ret != 0)
                break;

            AddLength(sha512, WC_SHA512_BLOCK_SIZE);
            sha512->buffLen = 0;
        }
    }

    return ret;
}

int wc_Sha512Update(wc_Sha512* sha512, const byte* data, word32 len)
{
    if (sha512 == NULL || (data == NULL && len > 0)) {
        return BAD_FUNC_ARG;
    }

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA512)
    if (sha512->asyncDev.marker == WOLFSSL_ASYNC_MARKER_SHA512) {
    #if defined(HAVE_INTEL_QA)
        return IntelQaSymSha512(&sha512->asyncDev, NULL, data, len);
    #endif
    }
#endif /* WOLFSSL_ASYNC_CRYPT */

    return Sha512Update(sha512, data, len);
}


static INLINE int Sha512Final(wc_Sha512* sha512)
{
    byte* local = (byte*)sha512->buffer;
    int ret;

    if (sha512 == NULL) {
        return BAD_FUNC_ARG;
    }

    SAVE_XMM_YMM ; /* for Intel AVX */
    AddLength(sha512, sha512->buffLen);               /* before adding pads */

    local[sha512->buffLen++] = 0x80;  /* add 1 */

    /* pad with zeros */
    if (sha512->buffLen > WC_SHA512_PAD_SIZE) {
        XMEMSET(&local[sha512->buffLen], 0, WC_SHA512_BLOCK_SIZE - sha512->buffLen);
        sha512->buffLen += WC_SHA512_BLOCK_SIZE - sha512->buffLen;
#if defined(LITTLE_ENDIAN_ORDER)
    #if defined(HAVE_INTEL_AVX1) || defined(HAVE_INTEL_AVX2)
        if (!IS_INTEL_AVX1(intel_flags) && !IS_INTEL_AVX2(intel_flags))
    #endif
        {
            ByteReverseWords64(sha512->buffer,sha512->buffer,
                                                             WC_SHA512_BLOCK_SIZE);
        }
#endif /* LITTLE_ENDIAN_ORDER */
        ret = Transform(sha512);
        if (ret != 0)
            return ret;

        sha512->buffLen = 0;
    }
    XMEMSET(&local[sha512->buffLen], 0, WC_SHA512_PAD_SIZE - sha512->buffLen);

    /* put lengths in bits */
    sha512->hiLen = (sha512->loLen >> (8 * sizeof(sha512->loLen) - 3)) +
                                                         (sha512->hiLen << 3);
    sha512->loLen = sha512->loLen << 3;

    /* store lengths */
#if defined(LITTLE_ENDIAN_ORDER)
    #if defined(HAVE_INTEL_AVX1) || defined(HAVE_INTEL_AVX2)
        if (!IS_INTEL_AVX1(intel_flags) && !IS_INTEL_AVX2(intel_flags))
    #endif
            ByteReverseWords64(sha512->buffer, sha512->buffer, WC_SHA512_PAD_SIZE);
#endif
    /* ! length ordering dependent on digest endian type ! */

    sha512->buffer[WC_SHA512_BLOCK_SIZE / sizeof(word64) - 2] = sha512->hiLen;
    sha512->buffer[WC_SHA512_BLOCK_SIZE / sizeof(word64) - 1] = sha512->loLen;
#if defined(HAVE_INTEL_AVX1) || defined(HAVE_INTEL_AVX2)
    if (IS_INTEL_AVX1(intel_flags) || IS_INTEL_AVX2(intel_flags))
        ByteReverseWords64(&(sha512->buffer[WC_SHA512_BLOCK_SIZE / sizeof(word64) - 2]),
                           &(sha512->buffer[WC_SHA512_BLOCK_SIZE / sizeof(word64) - 2]),
                           WC_SHA512_BLOCK_SIZE - WC_SHA512_PAD_SIZE);
#endif
    ret = Transform(sha512);
    if (ret != 0)
        return ret;

    #ifdef LITTLE_ENDIAN_ORDER
        ByteReverseWords64(sha512->digest, sha512->digest, WC_SHA512_DIGEST_SIZE);
    #endif

    return 0;
}

int wc_Sha512Final(wc_Sha512* sha512, byte* hash)
{
    int ret;

    if (sha512 == NULL || hash == NULL) {
        return BAD_FUNC_ARG;
    }

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA512)
    if (sha512->asyncDev.marker == WOLFSSL_ASYNC_MARKER_SHA512) {
    #if defined(HAVE_INTEL_QA)
        return IntelQaSymSha512(&sha512->asyncDev, hash, NULL,
                                            WC_SHA512_DIGEST_SIZE);
    #endif
    }
#endif /* WOLFSSL_ASYNC_CRYPT */

    ret = Sha512Final(sha512);
    if (ret != 0)
        return ret;

    XMEMCPY(hash, sha512->digest, WC_SHA512_DIGEST_SIZE);

    return InitSha512(sha512);  /* reset state */
}


int wc_InitSha512(wc_Sha512* sha512)
{
    return wc_InitSha512_ex(sha512, NULL, INVALID_DEVID);
}

void wc_Sha512Free(wc_Sha512* sha512)
{
    if (sha512 == NULL)
        return;

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA512)
    wolfAsync_DevCtxFree(&sha512->asyncDev, WOLFSSL_ASYNC_MARKER_SHA512);
#endif /* WOLFSSL_ASYNC_CRYPT */
}


#if defined(HAVE_INTEL_AVX1)

#define Rx_1(i) h(i)+=S1(e(i))+Ch(e(i),f(i),g(i))+K[i+j] + W_X[i];
#define Rx_2(i) d(i)+=h(i);
#define Rx_3(i) h(i)+=S0(a(i))+Maj(a(i),b(i),c(i));

#if defined(HAVE_INTEL_RORX)

    #define Rx_RORX_1(i) h(i)+=S1_RORX(e(i))+Ch(e(i),f(i),g(i))+K[i+j] + W_X[i];
    #define Rx_RORX_2(i) d(i)+=h(i);
    #define Rx_RORX_3(i) h(i)+=S0_RORX(a(i))+Maj(a(i),b(i),c(i));
#endif /* HAVE_INTEL_RORX */

#endif /* HAVE_INTEL_AVX1 */

#if defined(HAVE_INTEL_AVX2)
#define Ry_1(i, w) h(i)+=S1(e(i))+Ch(e(i),f(i),g(i))+K[i+j] + w;
#define Ry_2(i, w) d(i)+=h(i);
#define Ry_3(i, w) h(i)+=S0(a(i))+Maj(a(i),b(i),c(i));
#endif /* HAVE_INTEL_AVX2 */

/* INLINE Assember for Intel AVX1 instructions */
#if defined(HAVE_INTEL_AVX1)
#if defined(DEBUG_XMM)
    #define SAVE_REG(i)     __asm__ volatile("vmovdqu %%xmm"#i", %0 \n\t":"=m"(reg[i][0]):);
    #define RECV_REG(i)     __asm__ volatile("vmovdqu %0, %%xmm"#i" \n\t"::"m"(reg[i][0]));

    #define _DUMP_REG(REG, name)\
        { word64 buf[16];word64 reg[16][2];int k;\
          SAVE_REG(0); SAVE_REG(1); SAVE_REG(2);  SAVE_REG(3);  SAVE_REG(4);  \
          SAVE_REG(5);   SAVE_REG(6); SAVE_REG(7);SAVE_REG(8); SAVE_REG(9); SAVE_REG(10);\
           SAVE_REG(11); SAVE_REG(12); SAVE_REG(13); SAVE_REG(14); SAVE_REG(15); \
          __asm__ volatile("vmovdqu %%"#REG", %0 \n\t":"=m"(buf[0]):);\
          printf(" "#name":\t"); for(k=0; k<2; k++) printf("%016lx.", (word64)(buf[k])); printf("\n"); \
          RECV_REG(0); RECV_REG(1); RECV_REG(2);  RECV_REG(3);  RECV_REG(4);\
          RECV_REG(5);   RECV_REG(6); RECV_REG(7); RECV_REG(8); RECV_REG(9);\
          RECV_REG(10); RECV_REG(11); RECV_REG(12); RECV_REG(13); RECV_REG(14); RECV_REG(15);\
        }

    #define DUMP_REG(REG) _DUMP_REG(REG, #REG)
    #define PRINTF(fmt, ...)
#else
    #define DUMP_REG(REG)
    #define PRINTF(fmt, ...)
#endif /* DEBUG_XMM */

#define _MOVE_to_REG(xymm, mem)       __asm__ volatile("vmovdqu %0, %%"#xymm" "\
        :: "m"(mem));
#define _MOVE_to_MEM(mem,i, xymm)     __asm__ volatile("vmovdqu %%"#xymm", %0" :\
         "=m"(mem[i]),"=m"(mem[i+1]),"=m"(mem[i+2]),"=m"(mem[i+3]):);
#define _MOVE(dest, src)              __asm__ volatile("vmovdqu %%"#src",  %%"\
        #dest" "::);

#define _S_TEMP(dest, src, bits, temp)  __asm__ volatile("vpsrlq  $"#bits", %%"\
        #src", %%"#dest"\n\tvpsllq  $64-"#bits", %%"#src", %%"#temp"\n\tvpor %%"\
        #temp",%%"#dest", %%"#dest" "::);
#define _AVX1_R(dest, src, bits)      __asm__ volatile("vpsrlq  $"#bits", %%"\
        #src", %%"#dest" "::);
#define _XOR(dest, src1, src2)        __asm__ volatile("vpxor   %%"#src1", %%"\
        #src2", %%"#dest" "::);
#define _OR(dest, src1, src2)         __asm__ volatile("vpor    %%"#src1", %%"\
        #src2", %%"#dest" "::);
#define _ADD(dest, src1, src2)        __asm__ volatile("vpaddq   %%"#src1", %%"\
        #src2", %%"#dest" "::);
#define _ADD_MEM(dest, src1, mem)     __asm__ volatile("vpaddq   %0, %%"#src1", %%"\
        #dest" "::"m"(mem));

#define MOVE_to_REG(xymm, mem)      _MOVE_to_REG(xymm, mem)
#define MOVE_to_MEM(mem, i, xymm)   _MOVE_to_MEM(mem, i, xymm)
#define MOVE(dest, src)             _MOVE(dest, src)

#define XOR(dest, src1, src2)      _XOR(dest, src1, src2)
#define OR(dest, src1, src2)       _OR(dest, src1, src2)
#define ADD(dest, src1, src2)      _ADD(dest, src1, src2)

#define S_TMP(dest, src, bits, temp) _S_TEMP(dest, src, bits, temp);
#define AVX1_S(dest, src, bits)      S_TMP(dest, src, bits, S_TEMP)
#define AVX1_R(dest, src, bits)      _AVX1_R(dest, src, bits)

#define Init_Mask(mask) \
     __asm__ volatile("vmovdqu %0, %%xmm1\n\t"::"m"(mask):"%xmm1");

#define _W_from_buff1(w, buff, xmm) \
    /* X0..3(xmm4..7), W[0..15] = sha512->buffer[0.15];  */\
     __asm__ volatile("vmovdqu %1, %%"#xmm"\n\t"\
                      "vpshufb %%xmm1, %%"#xmm", %%"#xmm"\n\t"\
                      "vmovdqu %%"#xmm", %0"\
                      :"=m"(w): "m"(buff):"%xmm0");

#define W_from_buff1(w, buff, xmm) _W_from_buff1(w, buff, xmm)

#define W_from_buff(w, buff)\
     Init_Mask(mBYTE_FLIP_MASK[0]);\
     W_from_buff1(w[0], buff[0], W_0);\
     W_from_buff1(w[2], buff[2], W_2);\
     W_from_buff1(w[4], buff[4], W_4);\
     W_from_buff1(w[6], buff[6], W_6);\
     W_from_buff1(w[8], buff[8], W_8);\
     W_from_buff1(w[10],buff[10],W_10);\
     W_from_buff1(w[12],buff[12],W_12);\
     W_from_buff1(w[14],buff[14],W_14);

static word64 mBYTE_FLIP_MASK[] =  { 0x0001020304050607, 0x08090a0b0c0d0e0f };

#define W_I_15  xmm14
#define W_I_7   xmm11
#define W_I_2   xmm13
#define W_I     xmm12
#define G_TEMP  xmm0
#define S_TEMP  xmm1
#define XMM_TEMP0  xmm2

#define W_0     xmm12
#define W_2     xmm3
#define W_4     xmm4
#define W_6     xmm5
#define W_8     xmm6
#define W_10    xmm7
#define W_12    xmm8
#define W_14    xmm9

#define s0_1(dest, src)      AVX1_S(dest, src, 1);
#define s0_2(dest, src)      AVX1_S(G_TEMP, src, 8); XOR(dest, G_TEMP, dest);
#define s0_3(dest, src)      AVX1_R(G_TEMP, src, 7);  XOR(dest, G_TEMP, dest);

#define s1_1(dest, src)      AVX1_S(dest, src, 19);
#define s1_2(dest, src)      AVX1_S(G_TEMP, src, 61); XOR(dest, G_TEMP, dest);
#define s1_3(dest, src)      AVX1_R(G_TEMP, src, 6); XOR(dest, G_TEMP, dest);

#define s0_(dest, src)       s0_1(dest, src); s0_2(dest, src); s0_3(dest, src)
#define s1_(dest, src)       s1_1(dest, src); s1_2(dest, src); s1_3(dest, src)

#define Block_xx_1(i) \
    MOVE_to_REG(W_I_15, W_X[(i-15)&15]);\
    MOVE_to_REG(W_I_7,  W_X[(i- 7)&15]);\

#define Block_xx_2(i) \
    MOVE_to_REG(W_I_2,  W_X[(i- 2)&15]);\
    MOVE_to_REG(W_I,    W_X[(i)]);\

#define Block_xx_3(i) \
    s0_ (XMM_TEMP0, W_I_15);\

#define Block_xx_4(i) \
    ADD(W_I, W_I, XMM_TEMP0);\
    ADD(W_I, W_I, W_I_7);\

#define Block_xx_5(i) \
    s1_ (XMM_TEMP0, W_I_2);\

#define Block_xx_6(i) \
    ADD(W_I, W_I, XMM_TEMP0);\
    MOVE_to_MEM(W_X,i, W_I);\
    if (i==0)\
        MOVE_to_MEM(W_X,16, W_I);\

#define Block_xx_7(i) \
    MOVE_to_REG(W_I_15, W_X[(i-15)&15]);\
    MOVE_to_REG(W_I_7,  W_X[(i- 7)&15]);\

#define Block_xx_8(i) \
    MOVE_to_REG(W_I_2,  W_X[(i- 2)&15]);\
    MOVE_to_REG(W_I,    W_X[(i)]);\

#define Block_xx_9(i) \
    s0_ (XMM_TEMP0, W_I_15);\

#define Block_xx_10(i) \
    ADD(W_I, W_I, XMM_TEMP0);\
    ADD(W_I, W_I, W_I_7);\

#define Block_xx_11(i) \
    s1_ (XMM_TEMP0, W_I_2);\

#define Block_xx_12(i) \
    ADD(W_I, W_I, XMM_TEMP0);\
    MOVE_to_MEM(W_X,i, W_I);\
    if ((i)==0)\
        MOVE_to_MEM(W_X,16, W_I);\

static INLINE void Block_0_1(word64 *W_X) { Block_xx_1(0); }
static INLINE void Block_0_2(word64 *W_X) { Block_xx_2(0); }
static INLINE void Block_0_3(void) { Block_xx_3(0); }
static INLINE void Block_0_4(void) { Block_xx_4(0); }
static INLINE void Block_0_5(void) { Block_xx_5(0); }
static INLINE void Block_0_6(word64 *W_X) { Block_xx_6(0); }
static INLINE void Block_0_7(word64 *W_X) { Block_xx_7(2); }
static INLINE void Block_0_8(word64 *W_X) { Block_xx_8(2); }
static INLINE void Block_0_9(void) { Block_xx_9(2); }
static INLINE void Block_0_10(void){ Block_xx_10(2); }
static INLINE void Block_0_11(void){ Block_xx_11(2); }
static INLINE void Block_0_12(word64 *W_X){ Block_xx_12(2); }

static INLINE void Block_4_1(word64 *W_X) { Block_xx_1(4); }
static INLINE void Block_4_2(word64 *W_X) { Block_xx_2(4); }
static INLINE void Block_4_3(void) { Block_xx_3(4); }
static INLINE void Block_4_4(void) { Block_xx_4(4); }
static INLINE void Block_4_5(void) { Block_xx_5(4); }
static INLINE void Block_4_6(word64 *W_X) { Block_xx_6(4); }
static INLINE void Block_4_7(word64 *W_X) { Block_xx_7(6); }
static INLINE void Block_4_8(word64 *W_X) { Block_xx_8(6); }
static INLINE void Block_4_9(void) { Block_xx_9(6); }
static INLINE void Block_4_10(void){ Block_xx_10(6); }
static INLINE void Block_4_11(void){ Block_xx_11(6); }
static INLINE void Block_4_12(word64 *W_X){ Block_xx_12(6); }

static INLINE void Block_8_1(word64 *W_X) { Block_xx_1(8); }
static INLINE void Block_8_2(word64 *W_X) { Block_xx_2(8); }
static INLINE void Block_8_3(void) { Block_xx_3(8); }
static INLINE void Block_8_4(void) { Block_xx_4(8); }
static INLINE void Block_8_5(void) { Block_xx_5(8); }
static INLINE void Block_8_6(word64 *W_X) { Block_xx_6(8); }
static INLINE void Block_8_7(word64 *W_X) { Block_xx_7(10); }
static INLINE void Block_8_8(word64 *W_X) { Block_xx_8(10); }
static INLINE void Block_8_9(void) { Block_xx_9(10); }
static INLINE void Block_8_10(void){ Block_xx_10(10); }
static INLINE void Block_8_11(void){ Block_xx_11(10); }
static INLINE void Block_8_12(word64 *W_X){ Block_xx_12(10); }

static INLINE void Block_12_1(word64 *W_X) { Block_xx_1(12); }
static INLINE void Block_12_2(word64 *W_X) { Block_xx_2(12); }
static INLINE void Block_12_3(void) { Block_xx_3(12); }
static INLINE void Block_12_4(void) { Block_xx_4(12); }
static INLINE void Block_12_5(void) { Block_xx_5(12); }
static INLINE void Block_12_6(word64 *W_X) { Block_xx_6(12); }
static INLINE void Block_12_7(word64 *W_X) { Block_xx_7(14); }
static INLINE void Block_12_8(word64 *W_X) { Block_xx_8(14); }
static INLINE void Block_12_9(void) { Block_xx_9(14); }
static INLINE void Block_12_10(void){ Block_xx_10(14); }
static INLINE void Block_12_11(void){ Block_xx_11(14); }
static INLINE void Block_12_12(word64 *W_X){ Block_xx_12(14); }

#endif /* HAVE_INTEL_AVX1 */

#if defined(HAVE_INTEL_AVX2)
static const unsigned long mBYTE_FLIP_MASK_Y[] =
   { 0x0001020304050607, 0x08090a0b0c0d0e0f, 0x0001020304050607, 0x08090a0b0c0d0e0f };

#define W_from_buff_Y(buff)\
    { /* X0..3(ymm9..12), W_X[0..15] = sha512->buffer[0.15];  */\
     __asm__ volatile("vmovdqu %0, %%ymm8\n\t"::"m"(mBYTE_FLIP_MASK_Y[0]));\
     __asm__ volatile("vmovdqu %0, %%ymm12\n\t"\
                      "vmovdqu %1, %%ymm4\n\t"\
                      "vpshufb %%ymm8, %%ymm12, %%ymm12\n\t"\
                      "vpshufb %%ymm8, %%ymm4, %%ymm4\n\t"\
                      :: "m"(buff[0]),  "m"(buff[4]));\
     __asm__ volatile("vmovdqu %0, %%ymm5\n\t"\
                      "vmovdqu %1, %%ymm6\n\t"\
                      "vpshufb %%ymm8, %%ymm5, %%ymm5\n\t"\
                      "vpshufb %%ymm8, %%ymm6, %%ymm6\n\t"\
                      :: "m"(buff[8]),  "m"(buff[12]));\
    }

#if defined(DEBUG_YMM)
    #define SAVE_REG_Y(i) __asm__ volatile("vmovdqu %%ymm"#i", %0 \n\t":"=m"(reg[i-4][0]):);
    #define RECV_REG_Y(i) __asm__ volatile("vmovdqu %0, %%ymm"#i" \n\t"::"m"(reg[i-4][0]));

    #define _DUMP_REG_Y(REG, name)\
        { word64 buf[16];word64 reg[16][2];int k;\
          SAVE_REG_Y(4);  SAVE_REG_Y(5);   SAVE_REG_Y(6); SAVE_REG_Y(7); \
          SAVE_REG_Y(8); SAVE_REG_Y(9); SAVE_REG_Y(10); SAVE_REG_Y(11); SAVE_REG_Y(12);\
          SAVE_REG_Y(13); SAVE_REG_Y(14); SAVE_REG_Y(15); \
          __asm__ volatile("vmovdqu %%"#REG", %0 \n\t":"=m"(buf[0]):);\
          printf(" "#name":\t"); for(k=0; k<4; k++) printf("%016lx.", (word64)buf[k]); printf("\n"); \
          RECV_REG_Y(4);  RECV_REG_Y(5);   RECV_REG_Y(6); RECV_REG_Y(7); \
          RECV_REG_Y(8); RECV_REG_Y(9); RECV_REG_Y(10); RECV_REG_Y(11); RECV_REG_Y(12); \
          RECV_REG_Y(13); RECV_REG_Y(14); RECV_REG_Y(15);\
        }

    #define DUMP_REG_Y(REG) _DUMP_REG_Y(REG, #REG)
    #define DUMP_REG2_Y(REG) _DUMP_REG_Y(REG, #REG)
    #define PRINTF_Y(fmt, ...)
#else
    #define DUMP_REG_Y(REG)
    #define DUMP_REG2_Y(REG)
    #define PRINTF_Y(fmt, ...)
#endif /* DEBUG_YMM */

#define _MOVE_to_REGy(ymm, mem)         __asm__ volatile("vmovdqu %0, %%"#ymm" "\
                                        :: "m"(mem));
#define _MOVE_to_MEMy(mem,i, ymm)       __asm__ volatile("vmovdqu %%"#ymm", %0" \
        : "=m"(mem[i]),"=m"(mem[i+1]),"=m"(mem[i+2]),"=m"(mem[i+3]):);
#define _MOVE_128y(ymm0, ymm1, ymm2, map)  __asm__ volatile("vperm2i128  $"\
        #map", %%"#ymm2", %%"#ymm1", %%"#ymm0" "::);
#define _S_TEMPy(dest, src, bits, temp) \
         __asm__ volatile("vpsrlq  $"#bits", %%"#src", %%"#dest"\n\tvpsllq  $64-"#bits\
        ", %%"#src", %%"#temp"\n\tvpor %%"#temp",%%"#dest", %%"#dest" "::);
#define _AVX2_R(dest, src, bits)        __asm__ volatile("vpsrlq  $"#bits", %%"\
         #src", %%"#dest" "::);
#define _XORy(dest, src1, src2)         __asm__ volatile("vpxor   %%"#src1", %%"\
         #src2", %%"#dest" "::);
#define _ADDy(dest, src1, src2)         __asm__ volatile("vpaddq   %%"#src1", %%"\
         #src2", %%"#dest" "::);
#define _BLENDy(map, dest, src1, src2)  __asm__ volatile("vpblendd    $"#map", %%"\
         #src1",   %%"#src2", %%"#dest" "::);
#define _BLENDQy(map, dest, src1, src2) __asm__ volatile("vblendpd   $"#map", %%"\
         #src1",   %%"#src2", %%"#dest" "::);
#define _PERMQy(map, dest, src)         __asm__ volatile("vpermq  $"#map", %%"\
         #src", %%"#dest" "::);

#define MOVE_to_REGy(ymm, mem)      _MOVE_to_REGy(ymm, mem)
#define MOVE_to_MEMy(mem, i, ymm)   _MOVE_to_MEMy(mem, i, ymm)

#define MOVE_128y(ymm0, ymm1, ymm2, map) _MOVE_128y(ymm0, ymm1, ymm2, map)
#define XORy(dest, src1, src2)      _XORy(dest, src1, src2)
#define ADDy(dest, src1, src2)      _ADDy(dest, src1, src2)
#define BLENDy(map, dest, src1, src2) _BLENDy(map, dest, src1, src2)
#define BLENDQy(map, dest, src1, src2) _BLENDQy(map, dest, src1, src2)
#define PERMQy(map, dest, src)      _PERMQy(map, dest, src)


#define S_TMPy(dest, src, bits, temp) _S_TEMPy(dest, src, bits, temp);
#define AVX2_S(dest, src, bits)      S_TMPy(dest, src, bits, S_TEMPy)
#define AVX2_R(dest, src, bits)      _AVX2_R(dest, src, bits)


#define    FEEDBACK1_to_W_I_2(w_i_2, w_i)    MOVE_128y(YMM_TEMP0, w_i, w_i, 0x08);\
                                       BLENDy(0xf0, w_i_2, YMM_TEMP0, w_i_2);

#define    MOVE_W_to_W_I_15(w_i_15, w_0, w_4)  BLENDQy(0x1, w_i_15, w_4, w_0);\
                                       PERMQy(0x39, w_i_15, w_i_15);
#define    MOVE_W_to_W_I_7(w_i_7,  w_8, w_12)  BLENDQy(0x1, w_i_7, w_12, w_8);\
                                       PERMQy(0x39, w_i_7, w_i_7);
#define    MOVE_W_to_W_I_2(w_i_2,  w_12)       BLENDQy(0xc, w_i_2, w_12, w_i_2);\
                                       PERMQy(0x0e, w_i_2, w_i_2);


#define W_I_16y  ymm8
#define W_I_15y  ymm9
#define W_I_7y  ymm10
#define W_I_2y  ymm11
#define W_Iy    ymm12
#define G_TEMPy     ymm13
#define S_TEMPy     ymm14
#define YMM_TEMP0  ymm15
#define YMM_TEMP0x xmm15
#define W_I_TEMPy   ymm7
#define W_K_TEMPy   ymm15
#define W_K_TEMPx  xmm15
#define W_0y     ymm12
#define W_4y     ymm4
#define W_8y     ymm5
#define W_12y    ymm6


#define MOVE_15_to_16(w_i_16, w_i_15, w_i_7)\
    __asm__ volatile("vperm2i128  $0x01, %%"#w_i_15", %%"#w_i_15", %%"#w_i_15" "::);\
    __asm__ volatile("vpblendd    $0x08, %%"#w_i_15", %%"#w_i_7", %%"#w_i_16" "::);\
    __asm__ volatile("vperm2i128 $0x01,  %%"#w_i_7",  %%"#w_i_7", %%"#w_i_15" "::);\
    __asm__ volatile("vpblendd    $0x80, %%"#w_i_15", %%"#w_i_16", %%"#w_i_16" "::);\
    __asm__ volatile("vpshufd    $0x93,  %%"#w_i_16", %%"#w_i_16" "::);\

#define MOVE_7_to_15(w_i_15, w_i_7)\
    __asm__ volatile("vmovdqu                 %%"#w_i_7",  %%"#w_i_15" "::);\

#define MOVE_I_to_7(w_i_7, w_i)\
    __asm__ volatile("vperm2i128 $0x01,       %%"#w_i",   %%"#w_i",   %%"#w_i_7" "::);\
    __asm__ volatile("vpblendd    $0x01,       %%"#w_i_7",   %%"#w_i", %%"#w_i_7" "::);\
    __asm__ volatile("vpshufd    $0x39, %%"#w_i_7", %%"#w_i_7" "::);\

#define MOVE_I_to_2(w_i_2, w_i)\
    __asm__ volatile("vperm2i128 $0x01,       %%"#w_i", %%"#w_i", %%"#w_i_2" "::);\
    __asm__ volatile("vpshufd    $0x0e, %%"#w_i_2", %%"#w_i_2" "::);\

#endif /* HAVE_INTEL_AVX2 */


/***  Transform Body ***/
#if defined(HAVE_INTEL_AVX1)
static int Transform_AVX1(wc_Sha512* sha512)
{
    const word64* K = K512;
    word64 W_X[16+4] = {0};
    word32 j;
    word64 T[8];

    /* Copy digest to working vars */
    XMEMCPY(T, sha512->digest, sizeof(T));

    W_from_buff(W_X, sha512->buffer);
    for (j = 0; j < 80; j += 16) {
        Rx_1( 0); Block_0_1(W_X); Rx_2( 0); Block_0_2(W_X); Rx_3( 0); Block_0_3();
        Rx_1( 1); Block_0_4(); Rx_2( 1); Block_0_5(); Rx_3( 1); Block_0_6(W_X);
        Rx_1( 2); Block_0_7(W_X); Rx_2( 2); Block_0_8(W_X); Rx_3( 2); Block_0_9();
        Rx_1( 3); Block_0_10();Rx_2( 3); Block_0_11();Rx_3( 3); Block_0_12(W_X);

        Rx_1( 4); Block_4_1(W_X); Rx_2( 4); Block_4_2(W_X); Rx_3( 4); Block_4_3();
        Rx_1( 5); Block_4_4(); Rx_2( 5); Block_4_5(); Rx_3( 5); Block_4_6(W_X);
        Rx_1( 6); Block_4_7(W_X); Rx_2( 6); Block_4_8(W_X); Rx_3( 6); Block_4_9();
        Rx_1( 7); Block_4_10();Rx_2( 7); Block_4_11();Rx_3( 7); Block_4_12(W_X);

        Rx_1( 8); Block_8_1(W_X); Rx_2( 8); Block_8_2(W_X); Rx_3( 8); Block_8_3();
        Rx_1( 9); Block_8_4(); Rx_2( 9); Block_8_5(); Rx_3( 9); Block_8_6(W_X);
        Rx_1(10); Block_8_7(W_X); Rx_2(10); Block_8_8(W_X); Rx_3(10); Block_8_9();
        Rx_1(11); Block_8_10();Rx_2(11); Block_8_11();Rx_3(11); Block_8_12(W_X);

        Rx_1(12); Block_12_1(W_X); Rx_2(12); Block_12_2(W_X); Rx_3(12); Block_12_3();
        Rx_1(13); Block_12_4(); Rx_2(13); Block_12_5(); Rx_3(13); Block_12_6(W_X);
        Rx_1(14); Block_12_7(W_X); Rx_2(14); Block_12_8(W_X); Rx_3(14); Block_12_9();
        Rx_1(15); Block_12_10();Rx_2(15); Block_12_11();Rx_3(15); Block_12_12(W_X);
    }

    /* Add the working vars back into digest */
    sha512->digest[0] += a(0);
    sha512->digest[1] += b(0);
    sha512->digest[2] += c(0);
    sha512->digest[3] += d(0);
    sha512->digest[4] += e(0);
    sha512->digest[5] += f(0);
    sha512->digest[6] += g(0);
    sha512->digest[7] += h(0);

    /* Wipe variables */
#if !defined(HAVE_INTEL_AVX1) && !defined(HAVE_INTEL_AVX2)
    XMEMSET(W_X, 0, sizeof(word64) * 16);
#endif
    XMEMSET(T, 0, sizeof(T));

    return 0;
}
#endif /* HAVE_INTEL_AVX1 */

#if defined(HAVE_INTEL_AVX2) && defined(HAVE_INTEL_AVX1) && defined(HAVE_INTEL_RORX)
static int Transform_AVX1_RORX(wc_Sha512* sha512)
{
    const word64* K = K512;
    word64 W_X[16+4] = {0};
    word32 j;
    word64 T[8];

    /* Copy digest to working vars */
    XMEMCPY(T, sha512->digest, sizeof(T));

    W_from_buff(W_X, sha512->buffer);
    for (j = 0; j < 80; j += 16) {
        Rx_RORX_1( 0); Block_0_1(W_X); Rx_RORX_2( 0); Block_0_2(W_X);
                                    Rx_RORX_3( 0); Block_0_3();
        Rx_RORX_1( 1); Block_0_4(); Rx_RORX_2( 1); Block_0_5();
                                    Rx_RORX_3( 1); Block_0_6(W_X);
        Rx_RORX_1( 2); Block_0_7(W_X); Rx_RORX_2( 2); Block_0_8(W_X);
                                    Rx_RORX_3( 2); Block_0_9();
        Rx_RORX_1( 3); Block_0_10();Rx_RORX_2( 3); Block_0_11();
                                    Rx_RORX_3( 3); Block_0_12(W_X);

        Rx_RORX_1( 4); Block_4_1(W_X); Rx_RORX_2( 4); Block_4_2(W_X);
                                    Rx_RORX_3( 4); Block_4_3();
        Rx_RORX_1( 5); Block_4_4(); Rx_RORX_2( 5); Block_4_5();
                                    Rx_RORX_3( 5); Block_4_6(W_X);
        Rx_RORX_1( 6); Block_4_7(W_X); Rx_RORX_2( 6); Block_4_8(W_X);
                                    Rx_RORX_3( 6); Block_4_9();
        Rx_RORX_1( 7); Block_4_10();Rx_RORX_2( 7); Block_4_11();
                                    Rx_RORX_3( 7); Block_4_12(W_X);

        Rx_RORX_1( 8); Block_8_1(W_X); Rx_RORX_2( 8); Block_8_2(W_X);
                                    Rx_RORX_3( 8); Block_8_3();
        Rx_RORX_1( 9); Block_8_4(); Rx_RORX_2( 9); Block_8_5();
                                    Rx_RORX_3( 9); Block_8_6(W_X);
        Rx_RORX_1(10); Block_8_7(W_X); Rx_RORX_2(10); Block_8_8(W_X);
                                    Rx_RORX_3(10); Block_8_9();
        Rx_RORX_1(11); Block_8_10();Rx_RORX_2(11); Block_8_11();
                                    Rx_RORX_3(11); Block_8_12(W_X);

        Rx_RORX_1(12); Block_12_1(W_X); Rx_RORX_2(12); Block_12_2(W_X);
                                     Rx_RORX_3(12); Block_12_3();
        Rx_RORX_1(13); Block_12_4(); Rx_RORX_2(13); Block_12_5();
                                     Rx_RORX_3(13); Block_12_6(W_X);
        Rx_RORX_1(14); Block_12_7(W_X); Rx_RORX_2(14); Block_12_8(W_X);
                                     Rx_RORX_3(14); Block_12_9();
        Rx_RORX_1(15); Block_12_10();Rx_RORX_2(15); Block_12_11();
                                     Rx_RORX_3(15); Block_12_12(W_X);
    }

    /* Add the working vars back into digest */
    sha512->digest[0] += a(0);
    sha512->digest[1] += b(0);
    sha512->digest[2] += c(0);
    sha512->digest[3] += d(0);
    sha512->digest[4] += e(0);
    sha512->digest[5] += f(0);
    sha512->digest[6] += g(0);
    sha512->digest[7] += h(0);

    /* Wipe variables */
#if !defined(HAVE_INTEL_AVX1)&&!defined(HAVE_INTEL_AVX2)
    XMEMSET(W_X, 0, sizeof(word64) * 16);
#endif
    XMEMSET(T, 0, sizeof(T));

    return 0;
}
#endif /* HAVE_INTEL_AVX2 && HAVE_INTEL_AVX1 && HAVE_INTEL_RORX */

#if defined(HAVE_INTEL_AVX2)

#define s0_1y(dest, src)      AVX2_S(dest, src, 1);
#define s0_2y(dest, src)      AVX2_S(G_TEMPy, src, 8); XORy(dest, G_TEMPy, dest);
#define s0_3y(dest, src)      AVX2_R(G_TEMPy, src, 7);  XORy(dest, G_TEMPy, dest);

#define s1_1y(dest, src)      AVX2_S(dest, src, 19);
#define s1_2y(dest, src)      AVX2_S(G_TEMPy, src, 61); XORy(dest, G_TEMPy, dest);
#define s1_3y(dest, src)      AVX2_R(G_TEMPy, src, 6); XORy(dest, G_TEMPy, dest);

#define s0_y(dest, src)       s0_1y(dest, src); s0_2y(dest, src); s0_3y(dest, src)
#define s1_y(dest, src)       s1_1y(dest, src); s1_2y(dest, src); s1_3y(dest, src)


#define Block_Y_xx_1(i, w_0, w_4, w_8, w_12)\
    MOVE_W_to_W_I_15(W_I_15y, w_0, w_4);\
    MOVE_W_to_W_I_7 (W_I_7y,  w_8, w_12);\
    MOVE_W_to_W_I_2 (W_I_2y,  w_12);\

#define Block_Y_xx_2(i, w_0, w_4, w_8, w_12)\
    s0_1y (YMM_TEMP0, W_I_15y);\

#define Block_Y_xx_3(i, w_0, w_4, w_8, w_12)\
    s0_2y (YMM_TEMP0, W_I_15y);\

#define Block_Y_xx_4(i, w_0, w_4, w_8, w_12)\
    s0_3y (YMM_TEMP0, W_I_15y);\

#define Block_Y_xx_5(i, w_0, w_4, w_8, w_12)\
    ADDy(W_I_TEMPy, w_0, YMM_TEMP0);\

#define Block_Y_xx_6(i, w_0, w_4, w_8, w_12)\
    ADDy(W_I_TEMPy, W_I_TEMPy, W_I_7y);\
    s1_1y (YMM_TEMP0, W_I_2y);\

#define Block_Y_xx_7(i, w_0, w_4, w_8, w_12)\
    s1_2y (YMM_TEMP0, W_I_2y);\

#define Block_Y_xx_8(i, w_0, w_4, w_8, w_12)\
    s1_3y (YMM_TEMP0, W_I_2y);\
    ADDy(w_0, W_I_TEMPy, YMM_TEMP0);\

#define Block_Y_xx_9(i, w_0, w_4, w_8, w_12)\
    FEEDBACK1_to_W_I_2(W_I_2y, w_0);\

#define Block_Y_xx_10(i, w_0, w_4, w_8, w_12) \
    s1_1y (YMM_TEMP0, W_I_2y);\

#define Block_Y_xx_11(i, w_0, w_4, w_8, w_12) \
    s1_2y (YMM_TEMP0, W_I_2y);\

#define Block_Y_xx_12(i, w_0, w_4, w_8, w_12)\
    s1_3y (YMM_TEMP0, W_I_2y);\
    ADDy(w_0, W_I_TEMPy, YMM_TEMP0);\
    MOVE_to_MEMy(w,0, w_4);\


static INLINE void Block_Y_0_1(void) { Block_Y_xx_1(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_2(void) { Block_Y_xx_2(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_3(void) { Block_Y_xx_3(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_4(void) { Block_Y_xx_4(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_5(void) { Block_Y_xx_5(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_6(void) { Block_Y_xx_6(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_7(void) { Block_Y_xx_7(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_8(void) { Block_Y_xx_8(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_9(void) { Block_Y_xx_9(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_10(void){ Block_Y_xx_10(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_11(void){ Block_Y_xx_11(0, W_0y, W_4y, W_8y, W_12y); }
static INLINE void Block_Y_0_12(word64 *w){ Block_Y_xx_12(0, W_0y, W_4y, W_8y, W_12y); }

static INLINE void Block_Y_4_1(void) { Block_Y_xx_1(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_2(void) { Block_Y_xx_2(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_3(void) { Block_Y_xx_3(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_4(void) { Block_Y_xx_4(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_5(void) { Block_Y_xx_5(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_6(void) { Block_Y_xx_6(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_7(void) { Block_Y_xx_7(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_8(void) { Block_Y_xx_8(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_9(void) { Block_Y_xx_9(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_10(void) { Block_Y_xx_10(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_11(void) { Block_Y_xx_11(4, W_4y, W_8y, W_12y, W_0y); }
static INLINE void Block_Y_4_12(word64 *w) { Block_Y_xx_12(4, W_4y, W_8y, W_12y, W_0y); }

static INLINE void Block_Y_8_1(void) { Block_Y_xx_1(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_2(void) { Block_Y_xx_2(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_3(void) { Block_Y_xx_3(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_4(void) { Block_Y_xx_4(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_5(void) { Block_Y_xx_5(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_6(void) { Block_Y_xx_6(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_7(void) { Block_Y_xx_7(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_8(void) { Block_Y_xx_8(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_9(void) { Block_Y_xx_9(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_10(void) { Block_Y_xx_10(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_11(void) { Block_Y_xx_11(8, W_8y, W_12y, W_0y, W_4y); }
static INLINE void Block_Y_8_12(word64 *w) { Block_Y_xx_12(8, W_8y, W_12y, W_0y, W_4y); }

static INLINE void Block_Y_12_1(void) { Block_Y_xx_1(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_2(void) { Block_Y_xx_2(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_3(void) { Block_Y_xx_3(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_4(void) { Block_Y_xx_4(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_5(void) { Block_Y_xx_5(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_6(void) { Block_Y_xx_6(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_7(void) { Block_Y_xx_7(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_8(void) { Block_Y_xx_8(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_9(void) { Block_Y_xx_9(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_10(void) { Block_Y_xx_10(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_11(void) { Block_Y_xx_11(12, W_12y, W_0y, W_4y, W_8y); }
static INLINE void Block_Y_12_12(word64 *w) { Block_Y_xx_12(12, W_12y, W_0y, W_4y, W_8y); }


static int Transform_AVX2(wc_Sha512* sha512)
{
    const word64* K = K512;
    word64 w[4];
    word32 j;
    word64 T[8];

    /* Copy digest to working vars */
    XMEMCPY(T, sha512->digest, sizeof(T));

    W_from_buff_Y(sha512->buffer);
    MOVE_to_MEMy(w,0, W_0y);
    for (j = 0; j < 80; j += 16) {
        Ry_1( 0, w[0]); Block_Y_0_1(); Ry_2( 0, w[0]); Block_Y_0_2();
                                       Ry_3( 0, w[0]); Block_Y_0_3();
        Ry_1( 1, w[1]); Block_Y_0_4(); Ry_2( 1, w[1]); Block_Y_0_5();
                                       Ry_3( 1, w[1]); Block_Y_0_6();
        Ry_1( 2, w[2]); Block_Y_0_7(); Ry_2( 2, w[2]); Block_Y_0_8();
                                       Ry_3( 2, w[2]); Block_Y_0_9();
        Ry_1( 3, w[3]); Block_Y_0_10();Ry_2( 3, w[3]); Block_Y_0_11();
                                       Ry_3( 3, w[3]); Block_Y_0_12(w);

        Ry_1( 4, w[0]); Block_Y_4_1(); Ry_2( 4, w[0]); Block_Y_4_2();
                                       Ry_3( 4, w[0]); Block_Y_4_3();
        Ry_1( 5, w[1]); Block_Y_4_4(); Ry_2( 5, w[1]); Block_Y_4_5();
                                       Ry_3( 5, w[1]); Block_Y_4_6();
        Ry_1( 6, w[2]); Block_Y_4_7(); Ry_2( 6, w[2]); Block_Y_4_8();
                                       Ry_3( 6, w[2]); Block_Y_4_9();
        Ry_1( 7, w[3]); Block_Y_4_10(); Ry_2( 7, w[3]);Block_Y_4_11();
                                        Ry_3( 7, w[3]);Block_Y_4_12(w);

        Ry_1( 8, w[0]); Block_Y_8_1(); Ry_2( 8, w[0]); Block_Y_8_2();
                                       Ry_3( 8, w[0]); Block_Y_8_3();
        Ry_1( 9, w[1]); Block_Y_8_4(); Ry_2( 9, w[1]); Block_Y_8_5();
                                       Ry_3( 9, w[1]); Block_Y_8_6();
        Ry_1(10, w[2]); Block_Y_8_7(); Ry_2(10, w[2]); Block_Y_8_8();
                                       Ry_3(10, w[2]); Block_Y_8_9();
        Ry_1(11, w[3]); Block_Y_8_10();Ry_2(11, w[3]); Block_Y_8_11();
                                       Ry_3(11, w[3]); Block_Y_8_12(w);

        Ry_1(12, w[0]); Block_Y_12_1(); Ry_2(12, w[0]); Block_Y_12_2();
                                        Ry_3(12, w[0]); Block_Y_12_3();
        Ry_1(13, w[1]); Block_Y_12_4(); Ry_2(13, w[1]); Block_Y_12_5();
                                        Ry_3(13, w[1]); Block_Y_12_6();
        Ry_1(14, w[2]); Block_Y_12_7(); Ry_2(14, w[2]); Block_Y_12_8();
                                        Ry_3(14, w[2]); Block_Y_12_9();
        Ry_1(15, w[3]); Block_Y_12_10();Ry_2(15, w[3]); Block_Y_12_11();
                                        Ry_3(15, w[3]);Block_Y_12_12(w);
    }

    /* Add the working vars back into digest */
    sha512->digest[0] += a(0);
    sha512->digest[1] += b(0);
    sha512->digest[2] += c(0);
    sha512->digest[3] += d(0);
    sha512->digest[4] += e(0);
    sha512->digest[5] += f(0);
    sha512->digest[6] += g(0);
    sha512->digest[7] += h(0);

    /* Wipe variables */
#if !defined(HAVE_INTEL_AVX1) && !defined(HAVE_INTEL_AVX2)
    XMEMSET(W, 0, sizeof(word64) * 16);
#endif
    XMEMSET(T, 0, sizeof(T));

    return 0;
}
#endif /* HAVE_INTEL_AVX2 */



/* -------------------------------------------------------------------------- */
/* SHA384 */
/* -------------------------------------------------------------------------- */
#ifdef WOLFSSL_SHA384
static int InitSha384(wc_Sha384* sha384)
{
    if (sha384 == NULL) {
        return BAD_FUNC_ARG;
    }

    sha384->digest[0] = W64LIT(0xcbbb9d5dc1059ed8);
    sha384->digest[1] = W64LIT(0x629a292a367cd507);
    sha384->digest[2] = W64LIT(0x9159015a3070dd17);
    sha384->digest[3] = W64LIT(0x152fecd8f70e5939);
    sha384->digest[4] = W64LIT(0x67332667ffc00b31);
    sha384->digest[5] = W64LIT(0x8eb44a8768581511);
    sha384->digest[6] = W64LIT(0xdb0c2e0d64f98fa7);
    sha384->digest[7] = W64LIT(0x47b5481dbefa4fa4);

    sha384->buffLen = 0;
    sha384->loLen   = 0;
    sha384->hiLen   = 0;

    return 0;
}

int wc_Sha384Update(wc_Sha384* sha384, const byte* data, word32 len)
{
    if (sha384 == NULL || (data == NULL && len > 0)) {
        return BAD_FUNC_ARG;
    }

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA384)
    if (sha384->asyncDev.marker == WOLFSSL_ASYNC_MARKER_SHA384) {
    #if defined(HAVE_INTEL_QA)
        return IntelQaSymSha384(&sha384->asyncDev, NULL, data, len);
    #endif
    }
#endif /* WOLFSSL_ASYNC_CRYPT */

    return Sha512Update((wc_Sha512*)sha384, data, len);
}


int wc_Sha384Final(wc_Sha384* sha384, byte* hash)
{
    int ret;

    if (sha384 == NULL || hash == NULL) {
        return BAD_FUNC_ARG;
    }

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA384)
    if (sha384->asyncDev.marker == WOLFSSL_ASYNC_MARKER_SHA384) {
    #if defined(HAVE_INTEL_QA)
        return IntelQaSymSha384(&sha384->asyncDev, hash, NULL,
                                            WC_SHA384_DIGEST_SIZE);
    #endif
    }
#endif /* WOLFSSL_ASYNC_CRYPT */

    ret = Sha512Final((wc_Sha512*)sha384);
    if (ret != 0)
        return ret;

    XMEMCPY(hash, sha384->digest, WC_SHA384_DIGEST_SIZE);

    return InitSha384(sha384);  /* reset state */
}


/* Hardware Acceleration */
#if defined(HAVE_INTEL_AVX1) || defined(HAVE_INTEL_AVX2)
    int wc_InitSha384_ex(wc_Sha384* sha384, void* heap, int devId)
    {
        int ret = InitSha384(sha384);

        (void)heap;
        (void)devId;

        Sha512_SetTransform();

        return ret;
    }
#else
int wc_InitSha384_ex(wc_Sha384* sha384, void* heap, int devId)
{
    int ret;

    if (sha384 == NULL) {
        return BAD_FUNC_ARG;
    }

    sha384->heap = heap;
    ret = InitSha384(sha384);
    if (ret != 0)
        return ret;

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA384)
    ret = wolfAsync_DevCtxInit(&sha384->asyncDev, WOLFSSL_ASYNC_MARKER_SHA384,
                                                           sha384->heap, devId);
#else
    (void)devId;
#endif /* WOLFSSL_ASYNC_CRYPT */

    return ret;
}
#endif

int wc_InitSha384(wc_Sha384* sha384)
{
    return wc_InitSha384_ex(sha384, NULL, INVALID_DEVID);
}

void wc_Sha384Free(wc_Sha384* sha384)
{
    if (sha384 == NULL)
        return;

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA384)
    wolfAsync_DevCtxFree(&sha384->asyncDev, WOLFSSL_ASYNC_MARKER_SHA384);
#endif /* WOLFSSL_ASYNC_CRYPT */
}

#endif /* WOLFSSL_SHA384 */

#endif /* HAVE_FIPS */


int wc_Sha512GetHash(wc_Sha512* sha512, byte* hash)
{
    int ret;
    wc_Sha512 tmpSha512;

    if (sha512 == NULL || hash == NULL)
        return BAD_FUNC_ARG;

    ret = wc_Sha512Copy(sha512, &tmpSha512);
    if (ret == 0) {
        ret = wc_Sha512Final(&tmpSha512, hash);
    }
    return ret;
}

int wc_Sha512Copy(wc_Sha512* src, wc_Sha512* dst)
{
    int ret = 0;

    if (src == NULL || dst == NULL)
        return BAD_FUNC_ARG;

    XMEMCPY(dst, src, sizeof(wc_Sha512));

#ifdef WOLFSSL_ASYNC_CRYPT
    ret = wolfAsync_DevCopy(&src->asyncDev, &dst->asyncDev);
#endif

    return ret;
}

#ifdef WOLFSSL_SHA384
int wc_Sha384GetHash(wc_Sha384* sha384, byte* hash)
{
    int ret;
    wc_Sha384 tmpSha384;

    if (sha384 == NULL || hash == NULL)
        return BAD_FUNC_ARG;

    ret = wc_Sha384Copy(sha384, &tmpSha384);
    if (ret == 0) {
        ret = wc_Sha384Final(&tmpSha384, hash);
    }
    return ret;
}
int wc_Sha384Copy(wc_Sha384* src, wc_Sha384* dst)
{
    int ret = 0;

    if (src == NULL || dst == NULL)
        return BAD_FUNC_ARG;

    XMEMCPY(dst, src, sizeof(wc_Sha384));

#ifdef WOLFSSL_ASYNC_CRYPT
    ret = wolfAsync_DevCopy(&src->asyncDev, &dst->asyncDev);
#endif

    return ret;
}
#endif /* WOLFSSL_SHA384 */

#endif /* WOLFSSL_SHA512 */