keepassx1/src/crypto/aescrypt.c

 /**************************************************************************
 *                                                                         *
 *   Copyright (C) 2007 by Tarek Saidi <tarek.saidi@arcor.de>              *
 *   Copyright (c) 2003 Dr Brian Gladman, Worcester, UK                    *
 *                                                                         *
 *   This program 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; version 2 of the License.               *
 *                                                                         *
 *   This program 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.,                                       *
 *   59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.             *
 ***************************************************************************/

#include "aesopt.h"
#include "aestab.h"

#if defined(__cplusplus)
extern "C"
{
#endif

#define si(y,x,k,c) (s(y,c) = word_in(x, c) ^ (k)[c])
#define so(y,x,c)   word_out(y, c, s(x,c))

#if defined(ARRAYS)
#define locals(y,x)     x[4],y[4]
#else
#define locals(y,x)     x##0,x##1,x##2,x##3,y##0,y##1,y##2,y##3
#endif

#define l_copy(y, x)    s(y,0) = s(x,0); s(y,1) = s(x,1); \
                        s(y,2) = s(x,2); s(y,3) = s(x,3);
#define state_in(y,x,k) si(y,x,k,0); si(y,x,k,1); si(y,x,k,2); si(y,x,k,3)
#define state_out(y,x)  so(y,x,0); so(y,x,1); so(y,x,2); so(y,x,3)
#define round(rm,y,x,k) rm(y,x,k,0); rm(y,x,k,1); rm(y,x,k,2); rm(y,x,k,3)

#if ( FUNCS_IN_C & ENCRYPTION_IN_C)

/* Visual C++ .Net v7.1 provides the fastest encryption code when using
   Pentium optimiation with small code but this is poor for decryption
   so we need to control this with the following VC++ pragmas
*/

#if defined( _MSC_VER ) && !defined( _WIN64 )
#pragma optimize( "s", on )
#endif

/* Given the column (c) of the output state variable, the following
   macros give the input state variables which are needed in its
   computation for each row (r) of the state. All the alternative
   macros give the same end values but expand into different ways
   of calculating these values.  In particular the complex macro
   used for dynamically variable block sizes is designed to expand
   to a compile time constant whenever possible but will expand to
   conditional clauses on some branches (I am grateful to Frank
   Yellin for this construction)
*/

#define fwd_var(x,r,c)\
 ( r == 0 ? ( c == 0 ? s(x,0) : c == 1 ? s(x,1) : c == 2 ? s(x,2) : s(x,3))\
 : r == 1 ? ( c == 0 ? s(x,1) : c == 1 ? s(x,2) : c == 2 ? s(x,3) : s(x,0))\
 : r == 2 ? ( c == 0 ? s(x,2) : c == 1 ? s(x,3) : c == 2 ? s(x,0) : s(x,1))\
 :          ( c == 0 ? s(x,3) : c == 1 ? s(x,0) : c == 2 ? s(x,1) : s(x,2)))

#if defined(FT4_SET)
#undef  dec_fmvars
#define fwd_rnd(y,x,k,c)    (s(y,c) = (k)[c] ^ four_tables(x,t_use(f,n),fwd_var,rf1,c))
#elif defined(FT1_SET)
#undef  dec_fmvars
#define fwd_rnd(y,x,k,c)    (s(y,c) = (k)[c] ^ one_table(x,upr,t_use(f,n),fwd_var,rf1,c))
#else
#define fwd_rnd(y,x,k,c)    (s(y,c) = (k)[c] ^ fwd_mcol(no_table(x,t_use(s,box),fwd_var,rf1,c)))
#endif

#if defined(FL4_SET)
#define fwd_lrnd(y,x,k,c)   (s(y,c) = (k)[c] ^ four_tables(x,t_use(f,l),fwd_var,rf1,c))
#elif defined(FL1_SET)
#define fwd_lrnd(y,x,k,c)   (s(y,c) = (k)[c] ^ one_table(x,ups,t_use(f,l),fwd_var,rf1,c))
#else
#define fwd_lrnd(y,x,k,c)   (s(y,c) = (k)[c] ^ no_table(x,t_use(s,box),fwd_var,rf1,c))
#endif

aes_rval aes_encrypt(const unsigned char *in, unsigned char *out, const aes_encrypt_ctx cx[1])
{   uint_32t         locals(b0, b1);
    const uint_32t   *kp;
#if defined( dec_fmvars )
    dec_fmvars; /* declare variables for fwd_mcol() if needed */
#endif

#if defined( AES_ERR_CHK )
    if( cx->inf.b[0] != 10 * 16 && cx->inf.b[0] != 12 * 16 && cx->inf.b[0] != 14 * 16 )
        return EXIT_FAILURE;
#endif

    kp = cx->ks;
    state_in(b0, in, kp);

#if (ENC_UNROLL == FULL)

    switch(cx->inf.b[0])
    {
    case 14 * 16:
        round(fwd_rnd,  b1, b0, kp + 1 * N_COLS);
        round(fwd_rnd,  b0, b1, kp + 2 * N_COLS);
        kp += 2 * N_COLS;
    case 12 * 16:
        round(fwd_rnd,  b1, b0, kp + 1 * N_COLS);
        round(fwd_rnd,  b0, b1, kp + 2 * N_COLS);
        kp += 2 * N_COLS;
    case 10 * 16:
        round(fwd_rnd,  b1, b0, kp + 1 * N_COLS);
        round(fwd_rnd,  b0, b1, kp + 2 * N_COLS);
        round(fwd_rnd,  b1, b0, kp + 3 * N_COLS);
        round(fwd_rnd,  b0, b1, kp + 4 * N_COLS);
        round(fwd_rnd,  b1, b0, kp + 5 * N_COLS);
        round(fwd_rnd,  b0, b1, kp + 6 * N_COLS);
        round(fwd_rnd,  b1, b0, kp + 7 * N_COLS);
        round(fwd_rnd,  b0, b1, kp + 8 * N_COLS);
        round(fwd_rnd,  b1, b0, kp + 9 * N_COLS);
        round(fwd_lrnd, b0, b1, kp +10 * N_COLS);
    }

#else

#if (ENC_UNROLL == PARTIAL)
    {   uint_32t    rnd;
        for(rnd = 0; rnd < (cx->inf.b[0] >> 5) - 1; ++rnd)
        {
            kp += N_COLS;
            round(fwd_rnd, b1, b0, kp);
            kp += N_COLS;
            round(fwd_rnd, b0, b1, kp);
        }
        kp += N_COLS;
        round(fwd_rnd,  b1, b0, kp);
#else
    {   uint_32t    rnd;
        for(rnd = 0; rnd < (cx->inf.b[0] >> 4) - 1; ++rnd)
        {
            kp += N_COLS;
            round(fwd_rnd, b1, b0, kp);
            l_copy(b0, b1);
        }
#endif
        kp += N_COLS;
        round(fwd_lrnd, b0, b1, kp);
    }
#endif

    state_out(out, b0);

#if defined( AES_ERR_CHK )
    return EXIT_SUCCESS;
#endif
}

#endif

#if ( FUNCS_IN_C & DECRYPTION_IN_C)

/* Visual C++ .Net v7.1 provides the fastest encryption code when using
   Pentium optimiation with small code but this is poor for decryption
   so we need to control this with the following VC++ pragmas
*/

#if defined( _MSC_VER ) && !defined( _WIN64 )
#pragma optimize( "t", on )
#endif

/* Given the column (c) of the output state variable, the following
   macros give the input state variables which are needed in its
   computation for each row (r) of the state. All the alternative
   macros give the same end values but expand into different ways
   of calculating these values.  In particular the complex macro
   used for dynamically variable block sizes is designed to expand
   to a compile time constant whenever possible but will expand to
   conditional clauses on some branches (I am grateful to Frank
   Yellin for this construction)
*/

#define inv_var(x,r,c)\
 ( r == 0 ? ( c == 0 ? s(x,0) : c == 1 ? s(x,1) : c == 2 ? s(x,2) : s(x,3))\
 : r == 1 ? ( c == 0 ? s(x,3) : c == 1 ? s(x,0) : c == 2 ? s(x,1) : s(x,2))\
 : r == 2 ? ( c == 0 ? s(x,2) : c == 1 ? s(x,3) : c == 2 ? s(x,0) : s(x,1))\
 :          ( c == 0 ? s(x,1) : c == 1 ? s(x,2) : c == 2 ? s(x,3) : s(x,0)))

#if defined(IT4_SET)
#undef  dec_imvars
#define inv_rnd(y,x,k,c)    (s(y,c) = (k)[c] ^ four_tables(x,t_use(i,n),inv_var,rf1,c))
#elif defined(IT1_SET)
#undef  dec_imvars
#define inv_rnd(y,x,k,c)    (s(y,c) = (k)[c] ^ one_table(x,upr,t_use(i,n),inv_var,rf1,c))
#else
#define inv_rnd(y,x,k,c)    (s(y,c) = inv_mcol((k)[c] ^ no_table(x,t_use(i,box),inv_var,rf1,c)))
#endif

#if defined(IL4_SET)
#define inv_lrnd(y,x,k,c)   (s(y,c) = (k)[c] ^ four_tables(x,t_use(i,l),inv_var,rf1,c))
#elif defined(IL1_SET)
#define inv_lrnd(y,x,k,c)   (s(y,c) = (k)[c] ^ one_table(x,ups,t_use(i,l),inv_var,rf1,c))
#else
#define inv_lrnd(y,x,k,c)   (s(y,c) = (k)[c] ^ no_table(x,t_use(i,box),inv_var,rf1,c))
#endif

/* This code can work with the decryption key schedule in the   */
/* order that is used for encrytpion (where the 1st decryption  */
/* round key is at the high end ot the schedule) or with a key  */
/* schedule that has been reversed to put the 1st decryption    */
/* round key at the low end of the schedule in memory (when     */
/* AES_REV_DKS is defined)                                      */

#ifdef AES_REV_DKS
#define key_ofs     0
#define rnd_key(n)  (kp + n * N_COLS)
#else
#define key_ofs     1
#define rnd_key(n)  (kp - n * N_COLS)
#endif

aes_rval aes_decrypt(const unsigned char *in, unsigned char *out, const aes_decrypt_ctx cx[1])
{   uint_32t        locals(b0, b1);
#if defined( dec_imvars )
    dec_imvars; /* declare variables for inv_mcol() if needed */
#endif
    const uint_32t *kp;

#if defined( AES_ERR_CHK )
    if( cx->inf.b[0] != 10 * 16 && cx->inf.b[0] != 12 * 16 && cx->inf.b[0] != 14 * 16 )
        return EXIT_FAILURE;
#endif

    kp = cx->ks + (key_ofs ? (cx->inf.b[0] >> 2) : 0);
    state_in(b0, in, kp);

#if (DEC_UNROLL == FULL)

    kp = cx->ks + (key_ofs ? 0 : (cx->inf.b[0] >> 2));
    switch(cx->inf.b[0])
    {
    case 14 * 16:
        round(inv_rnd,  b1, b0, rnd_key(-13));
        round(inv_rnd,  b0, b1, rnd_key(-12));
    case 12 * 16:
        round(inv_rnd,  b1, b0, rnd_key(-11));
        round(inv_rnd,  b0, b1, rnd_key(-10));
    case 10 * 16:
        round(inv_rnd,  b1, b0, rnd_key(-9));
        round(inv_rnd,  b0, b1, rnd_key(-8));
        round(inv_rnd,  b1, b0, rnd_key(-7));
        round(inv_rnd,  b0, b1, rnd_key(-6));
        round(inv_rnd,  b1, b0, rnd_key(-5));
        round(inv_rnd,  b0, b1, rnd_key(-4));
        round(inv_rnd,  b1, b0, rnd_key(-3));
        round(inv_rnd,  b0, b1, rnd_key(-2));
        round(inv_rnd,  b1, b0, rnd_key(-1));
        round(inv_lrnd, b0, b1, rnd_key( 0));
    }

#else

#if (DEC_UNROLL == PARTIAL)
    {   uint_32t    rnd;
        for(rnd = 0; rnd < (cx->inf.b[0] >> 5) - 1; ++rnd)
        {
            kp = rnd_key(1);
            round(inv_rnd, b1, b0, kp);
            kp = rnd_key(1);
            round(inv_rnd, b0, b1, kp);
        }
        kp = rnd_key(1);
        round(inv_rnd, b1, b0, kp);
#else
    {   uint_32t    rnd;
        for(rnd = 0; rnd < (cx->inf.b[0] >> 4) - 1; ++rnd)
        {
            kp = rnd_key(1);
            round(inv_rnd, b1, b0, kp);
            l_copy(b0, b1);
        }
#endif
        kp = rnd_key(1);
        round(inv_lrnd, b0, b1, kp);
        }
#endif

    state_out(out, b0);

#if defined( AES_ERR_CHK )
    return EXIT_SUCCESS;
#endif
}

#endif

#if defined(__cplusplus)
}
#endif
changed some copyright headers, added copying file, extended main qmake projekt file, implemented all file dialogs for kde, new icons (bug #1730334), automatic file extension, fixed show/hide behavior of the simple password dlg (bug #1722682) git-svn-id: https://svn.code.sf.net/p/keepassx/code/trunk@145 b624d157-de02-0410-bad0-e51aec6abb33 17 years ago			`/**************************************************************************`
			`* *`
			`* Copyright (C) 2007 by Tarek Saidi <tarek.saidi@arcor.de> *`
			`* Copyright (c) 2003 Dr Brian Gladman, Worcester, UK *`
			`* *`
			`* This program 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; version 2 of the License. *`
			`* *`
			`* This program 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., *`
			`* 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *`
			`***************************************************************************/`
First commit for 0.2.3, some old functions still need to be ported to the new back-end api, i.e. import and export. git-svn-id: https://svn.code.sf.net/p/keepassx/code/trunk@104 b624d157-de02-0410-bad0-e51aec6abb33 18 years ago
			`#include "aesopt.h"`
			`#include "aestab.h"`

			`#if defined(__cplusplus)`
			`extern "C"`
			`{`
			`#endif`

			`#define si(y,x,k,c) (s(y,c) = word_in(x, c) ^ (k)[c])`
			`#define so(y,x,c) word_out(y, c, s(x,c))`

			`#if defined(ARRAYS)`
			`#define locals(y,x) x[4],y[4]`
			`#else`
			`#define locals(y,x) x##0,x##1,x##2,x##3,y##0,y##1,y##2,y##3`
			`#endif`

			`#define l_copy(y, x) s(y,0) = s(x,0); s(y,1) = s(x,1); \`
			`s(y,2) = s(x,2); s(y,3) = s(x,3);`
			`#define state_in(y,x,k) si(y,x,k,0); si(y,x,k,1); si(y,x,k,2); si(y,x,k,3)`
			`#define state_out(y,x) so(y,x,0); so(y,x,1); so(y,x,2); so(y,x,3)`
			`#define round(rm,y,x,k) rm(y,x,k,0); rm(y,x,k,1); rm(y,x,k,2); rm(y,x,k,3)`

			`#if ( FUNCS_IN_C & ENCRYPTION_IN_C)`

			`/* Visual C++ .Net v7.1 provides the fastest encryption code when using`
			`Pentium optimiation with small code but this is poor for decryption`
			`so we need to control this with the following VC++ pragmas`
			`*/`

			`#if defined( _MSC_VER ) && !defined( _WIN64 )`
			`#pragma optimize( "s", on )`
			`#endif`

			`/* Given the column (c) of the output state variable, the following`
			`macros give the input state variables which are needed in its`
			`computation for each row (r) of the state. All the alternative`
			`macros give the same end values but expand into different ways`
			`of calculating these values. In particular the complex macro`
			`used for dynamically variable block sizes is designed to expand`
			`to a compile time constant whenever possible but will expand to`
			`conditional clauses on some branches (I am grateful to Frank`
			`Yellin for this construction)`
			`*/`

			`#define fwd_var(x,r,c)\`
			`( r == 0 ? ( c == 0 ? s(x,0) : c == 1 ? s(x,1) : c == 2 ? s(x,2) : s(x,3))\`
			`: r == 1 ? ( c == 0 ? s(x,1) : c == 1 ? s(x,2) : c == 2 ? s(x,3) : s(x,0))\`
			`: r == 2 ? ( c == 0 ? s(x,2) : c == 1 ? s(x,3) : c == 2 ? s(x,0) : s(x,1))\`
			`: ( c == 0 ? s(x,3) : c == 1 ? s(x,0) : c == 2 ? s(x,1) : s(x,2)))`

			`#if defined(FT4_SET)`
			`#undef dec_fmvars`
			`#define fwd_rnd(y,x,k,c) (s(y,c) = (k)[c] ^ four_tables(x,t_use(f,n),fwd_var,rf1,c))`
			`#elif defined(FT1_SET)`
			`#undef dec_fmvars`
			`#define fwd_rnd(y,x,k,c) (s(y,c) = (k)[c] ^ one_table(x,upr,t_use(f,n),fwd_var,rf1,c))`
			`#else`
			`#define fwd_rnd(y,x,k,c) (s(y,c) = (k)[c] ^ fwd_mcol(no_table(x,t_use(s,box),fwd_var,rf1,c)))`
			`#endif`

			`#if defined(FL4_SET)`
			`#define fwd_lrnd(y,x,k,c) (s(y,c) = (k)[c] ^ four_tables(x,t_use(f,l),fwd_var,rf1,c))`
			`#elif defined(FL1_SET)`
			`#define fwd_lrnd(y,x,k,c) (s(y,c) = (k)[c] ^ one_table(x,ups,t_use(f,l),fwd_var,rf1,c))`
			`#else`
			`#define fwd_lrnd(y,x,k,c) (s(y,c) = (k)[c] ^ no_table(x,t_use(s,box),fwd_var,rf1,c))`
			`#endif`

			`aes_rval aes_encrypt(const unsigned char in, unsigned char out, const aes_encrypt_ctx cx[1])`
			`{ uint_32t locals(b0, b1);`
			`const uint_32t *kp;`
			`#if defined( dec_fmvars )`
			`dec_fmvars; /* declare variables for fwd_mcol() if needed */`
			`#endif`

			`#if defined( AES_ERR_CHK )`
			`if( cx->inf.b[0] != 10 * 16 && cx->inf.b[0] != 12 * 16 && cx->inf.b[0] != 14 * 16 )`
			`return EXIT_FAILURE;`
			`#endif`

			`kp = cx->ks;`
			`state_in(b0, in, kp);`

			`#if (ENC_UNROLL == FULL)`

			`switch(cx->inf.b[0])`
			`{`
			`case 14 * 16:`
			`round(fwd_rnd, b1, b0, kp + 1 * N_COLS);`
			`round(fwd_rnd, b0, b1, kp + 2 * N_COLS);`
			`kp += 2 * N_COLS;`
			`case 12 * 16:`
			`round(fwd_rnd, b1, b0, kp + 1 * N_COLS);`
			`round(fwd_rnd, b0, b1, kp + 2 * N_COLS);`
			`kp += 2 * N_COLS;`
			`case 10 * 16:`
			`round(fwd_rnd, b1, b0, kp + 1 * N_COLS);`
			`round(fwd_rnd, b0, b1, kp + 2 * N_COLS);`
			`round(fwd_rnd, b1, b0, kp + 3 * N_COLS);`
			`round(fwd_rnd, b0, b1, kp + 4 * N_COLS);`
			`round(fwd_rnd, b1, b0, kp + 5 * N_COLS);`
			`round(fwd_rnd, b0, b1, kp + 6 * N_COLS);`
			`round(fwd_rnd, b1, b0, kp + 7 * N_COLS);`
			`round(fwd_rnd, b0, b1, kp + 8 * N_COLS);`
			`round(fwd_rnd, b1, b0, kp + 9 * N_COLS);`
			`round(fwd_lrnd, b0, b1, kp +10 * N_COLS);`
			`}`

			`#else`

			`#if (ENC_UNROLL == PARTIAL)`
			`{ uint_32t rnd;`
			`for(rnd = 0; rnd < (cx->inf.b[0] >> 5) - 1; ++rnd)`
			`{`
			`kp += N_COLS;`
			`round(fwd_rnd, b1, b0, kp);`
			`kp += N_COLS;`
			`round(fwd_rnd, b0, b1, kp);`
			`}`
			`kp += N_COLS;`
			`round(fwd_rnd, b1, b0, kp);`
			`#else`
			`{ uint_32t rnd;`
			`for(rnd = 0; rnd < (cx->inf.b[0] >> 4) - 1; ++rnd)`
			`{`
			`kp += N_COLS;`
			`round(fwd_rnd, b1, b0, kp);`
			`l_copy(b0, b1);`
			`}`
			`#endif`
			`kp += N_COLS;`
			`round(fwd_lrnd, b0, b1, kp);`
			`}`
			`#endif`

			`state_out(out, b0);`

			`#if defined( AES_ERR_CHK )`
			`return EXIT_SUCCESS;`
			`#endif`
			`}`

			`#endif`

			`#if ( FUNCS_IN_C & DECRYPTION_IN_C)`

			`/* Visual C++ .Net v7.1 provides the fastest encryption code when using`
			`Pentium optimiation with small code but this is poor for decryption`
			`so we need to control this with the following VC++ pragmas`
			`*/`

			`#if defined( _MSC_VER ) && !defined( _WIN64 )`
			`#pragma optimize( "t", on )`
			`#endif`

			`/* Given the column (c) of the output state variable, the following`
			`macros give the input state variables which are needed in its`
			`computation for each row (r) of the state. All the alternative`
			`macros give the same end values but expand into different ways`
			`of calculating these values. In particular the complex macro`
			`used for dynamically variable block sizes is designed to expand`
			`to a compile time constant whenever possible but will expand to`
			`conditional clauses on some branches (I am grateful to Frank`
			`Yellin for this construction)`
			`*/`

			`#define inv_var(x,r,c)\`
			`( r == 0 ? ( c == 0 ? s(x,0) : c == 1 ? s(x,1) : c == 2 ? s(x,2) : s(x,3))\`
			`: r == 1 ? ( c == 0 ? s(x,3) : c == 1 ? s(x,0) : c == 2 ? s(x,1) : s(x,2))\`
			`: r == 2 ? ( c == 0 ? s(x,2) : c == 1 ? s(x,3) : c == 2 ? s(x,0) : s(x,1))\`
			`: ( c == 0 ? s(x,1) : c == 1 ? s(x,2) : c == 2 ? s(x,3) : s(x,0)))`

			`#if defined(IT4_SET)`
			`#undef dec_imvars`
			`#define inv_rnd(y,x,k,c) (s(y,c) = (k)[c] ^ four_tables(x,t_use(i,n),inv_var,rf1,c))`
			`#elif defined(IT1_SET)`
			`#undef dec_imvars`
			`#define inv_rnd(y,x,k,c) (s(y,c) = (k)[c] ^ one_table(x,upr,t_use(i,n),inv_var,rf1,c))`
			`#else`
			`#define inv_rnd(y,x,k,c) (s(y,c) = inv_mcol((k)[c] ^ no_table(x,t_use(i,box),inv_var,rf1,c)))`
			`#endif`

			`#if defined(IL4_SET)`
			`#define inv_lrnd(y,x,k,c) (s(y,c) = (k)[c] ^ four_tables(x,t_use(i,l),inv_var,rf1,c))`
			`#elif defined(IL1_SET)`
			`#define inv_lrnd(y,x,k,c) (s(y,c) = (k)[c] ^ one_table(x,ups,t_use(i,l),inv_var,rf1,c))`
			`#else`
			`#define inv_lrnd(y,x,k,c) (s(y,c) = (k)[c] ^ no_table(x,t_use(i,box),inv_var,rf1,c))`
			`#endif`

			`/* This code can work with the decryption key schedule in the */`
			`/* order that is used for encrytpion (where the 1st decryption */`
			`/* round key is at the high end ot the schedule) or with a key */`
			`/* schedule that has been reversed to put the 1st decryption */`
			`/* round key at the low end of the schedule in memory (when */`
			`/* AES_REV_DKS is defined) */`

			`#ifdef AES_REV_DKS`
			`#define key_ofs 0`
			`#define rnd_key(n) (kp + n * N_COLS)`
			`#else`
			`#define key_ofs 1`
			`#define rnd_key(n) (kp - n * N_COLS)`
			`#endif`

			`aes_rval aes_decrypt(const unsigned char in, unsigned char out, const aes_decrypt_ctx cx[1])`
			`{ uint_32t locals(b0, b1);`
			`#if defined( dec_imvars )`
			`dec_imvars; /* declare variables for inv_mcol() if needed */`
			`#endif`
			`const uint_32t *kp;`

			`#if defined( AES_ERR_CHK )`
			`if( cx->inf.b[0] != 10 * 16 && cx->inf.b[0] != 12 * 16 && cx->inf.b[0] != 14 * 16 )`
			`return EXIT_FAILURE;`
			`#endif`

			`kp = cx->ks + (key_ofs ? (cx->inf.b[0] >> 2) : 0);`
			`state_in(b0, in, kp);`

			`#if (DEC_UNROLL == FULL)`

			`kp = cx->ks + (key_ofs ? 0 : (cx->inf.b[0] >> 2));`
			`switch(cx->inf.b[0])`
			`{`
			`case 14 * 16:`
			`round(inv_rnd, b1, b0, rnd_key(-13));`
			`round(inv_rnd, b0, b1, rnd_key(-12));`
			`case 12 * 16:`
			`round(inv_rnd, b1, b0, rnd_key(-11));`
			`round(inv_rnd, b0, b1, rnd_key(-10));`
			`case 10 * 16:`
			`round(inv_rnd, b1, b0, rnd_key(-9));`
			`round(inv_rnd, b0, b1, rnd_key(-8));`
			`round(inv_rnd, b1, b0, rnd_key(-7));`
			`round(inv_rnd, b0, b1, rnd_key(-6));`
			`round(inv_rnd, b1, b0, rnd_key(-5));`
			`round(inv_rnd, b0, b1, rnd_key(-4));`
			`round(inv_rnd, b1, b0, rnd_key(-3));`
			`round(inv_rnd, b0, b1, rnd_key(-2));`
			`round(inv_rnd, b1, b0, rnd_key(-1));`
			`round(inv_lrnd, b0, b1, rnd_key( 0));`
			`}`

			`#else`

			`#if (DEC_UNROLL == PARTIAL)`
			`{ uint_32t rnd;`
			`for(rnd = 0; rnd < (cx->inf.b[0] >> 5) - 1; ++rnd)`
			`{`
			`kp = rnd_key(1);`
			`round(inv_rnd, b1, b0, kp);`
			`kp = rnd_key(1);`
			`round(inv_rnd, b0, b1, kp);`
			`}`
			`kp = rnd_key(1);`
			`round(inv_rnd, b1, b0, kp);`
			`#else`
			`{ uint_32t rnd;`
			`for(rnd = 0; rnd < (cx->inf.b[0] >> 4) - 1; ++rnd)`
			`{`
			`kp = rnd_key(1);`
			`round(inv_rnd, b1, b0, kp);`
			`l_copy(b0, b1);`
			`}`
			`#endif`
			`kp = rnd_key(1);`
			`round(inv_lrnd, b0, b1, kp);`
			`}`
			`#endif`

			`state_out(out, b0);`

			`#if defined( AES_ERR_CHK )`
			`return EXIT_SUCCESS;`
			`#endif`
			`}`

			`#endif`

			`#if defined(__cplusplus)`
			`}`
			`#endif`