source-engine/utils/smp/IceKey.cpp

//========= Public Domain Code ================================================
//
// Purpose: C++ implementation of the ICE encryption algorithm.
//			Taken from public domain code, as written by Matthew Kwan - July 1996
//			http://www.darkside.com.au/ice/
//=============================================================================

#include "IceKey.H"

#pragma warning(disable: 4244)


	/* Structure of a single round subkey */
class IceSubkey {
    public:
	unsigned long	val[3];
};


	/* The S-boxes */
static unsigned long	ice_sbox[4][1024];
static int		ice_sboxes_initialised = 0;


	/* Modulo values for the S-boxes */
static const int	ice_smod[4][4] = {
				{333, 313, 505, 369},
				{379, 375, 319, 391},
				{361, 445, 451, 397},
				{397, 425, 395, 505}};

	/* XOR values for the S-boxes */
static const int	ice_sxor[4][4] = {
				{0x83, 0x85, 0x9b, 0xcd},
				{0xcc, 0xa7, 0xad, 0x41},
				{0x4b, 0x2e, 0xd4, 0x33},
				{0xea, 0xcb, 0x2e, 0x04}};

	/* Permutation values for the P-box */
static const unsigned long	ice_pbox[32] = {
		0x00000001, 0x00000080, 0x00000400, 0x00002000,
		0x00080000, 0x00200000, 0x01000000, 0x40000000,
		0x00000008, 0x00000020, 0x00000100, 0x00004000,
		0x00010000, 0x00800000, 0x04000000, 0x20000000,
		0x00000004, 0x00000010, 0x00000200, 0x00008000,
		0x00020000, 0x00400000, 0x08000000, 0x10000000,
		0x00000002, 0x00000040, 0x00000800, 0x00001000,
		0x00040000, 0x00100000, 0x02000000, 0x80000000};

	/* The key rotation schedule */
static const int	ice_keyrot[16] = {
				0, 1, 2, 3, 2, 1, 3, 0,
				1, 3, 2, 0, 3, 1, 0, 2};


/*
 * 8-bit Galois Field multiplication of a by b, modulo m.
 * Just like arithmetic multiplication, except that additions and
 * subtractions are replaced by XOR.
 */

static unsigned int
gf_mult (
	register unsigned int	a,
	register unsigned int	b,
	register unsigned int	m
) {
	register unsigned int	res = 0;

	while (b) {
	    if (b & 1)
		res ^= a;

	    a <<= 1;
	    b >>= 1;

	    if (a >= 256)
		a ^= m;
	}

	return (res);
}


/*
 * Galois Field exponentiation.
 * Raise the base to the power of 7, modulo m.
 */

static unsigned long
gf_exp7 (
	register unsigned int	b,
	unsigned int		m
) {
	register unsigned int	x;

	if (b == 0)
	    return (0);

	x = gf_mult (b, b, m);
	x = gf_mult (b, x, m);
	x = gf_mult (x, x, m);
	return (gf_mult (b, x, m));
}


/*
 * Carry out the ICE 32-bit P-box permutation.
 */

static unsigned long
ice_perm32 (
	register unsigned long	x
) {
	register unsigned long		res = 0;
	register const unsigned long	*pbox = ice_pbox;

	while (x) {
	    if (x & 1)
		res |= *pbox;
	    pbox++;
	    x >>= 1;
	}

	return (res);
}


/*
 * Initialise the ICE S-boxes.
 * This only has to be done once.
 */

static void
ice_sboxes_init (void)
{
	register int	i;

	for (i=0; i<1024; i++) {
	    int			col = (i >> 1) & 0xff;
	    int			row = (i & 0x1) | ((i & 0x200) >> 8);
	    unsigned long	x;

	    x = gf_exp7 (col ^ ice_sxor[0][row], ice_smod[0][row]) << 24;
	    ice_sbox[0][i] = ice_perm32 (x);

	    x = gf_exp7 (col ^ ice_sxor[1][row], ice_smod[1][row]) << 16;
	    ice_sbox[1][i] = ice_perm32 (x);

	    x = gf_exp7 (col ^ ice_sxor[2][row], ice_smod[2][row]) << 8;
	    ice_sbox[2][i] = ice_perm32 (x);

	    x = gf_exp7 (col ^ ice_sxor[3][row], ice_smod[3][row]);
	    ice_sbox[3][i] = ice_perm32 (x);
	}
}


/*
 * Create a new ICE key.
 */

IceKey::IceKey (int n)
{
	if (!ice_sboxes_initialised) {
	    ice_sboxes_init ();
	    ice_sboxes_initialised = 1;
	}

	if (n < 1) {
	    _size = 1;
	    _rounds = 8;
	} else {
	    _size = n;
	    _rounds = n * 16;
	}

	_keysched = new IceSubkey[_rounds];
}


/*
 * Destroy an ICE key.
 */

IceKey::~IceKey ()
{
	int	i, j;

	for (i=0; i<_rounds; i++)
	    for (j=0; j<3; j++)
		_keysched[i].val[j] = 0;

	_rounds = _size = 0;

	delete[] _keysched;
}


/*
 * The single round ICE f function.
 */

static unsigned long
ice_f (
	register unsigned long	p,
	const IceSubkey		*sk
) {
	unsigned long	tl, tr;		/* Expanded 40-bit values */
	unsigned long	al, ar;		/* Salted expanded 40-bit values */

					/* Left half expansion */
	tl = ((p >> 16) & 0x3ff) | (((p >> 14) | (p << 18)) & 0xffc00);

					/* Right half expansion */
	tr = (p & 0x3ff) | ((p << 2) & 0xffc00);

					/* Perform the salt permutation */
			// al = (tr & sk->val[2]) | (tl & ~sk->val[2]);
			// ar = (tl & sk->val[2]) | (tr & ~sk->val[2]);
	al = sk->val[2] & (tl ^ tr);
	ar = al ^ tr;
	al ^= tl;

	al ^= sk->val[0];		/* XOR with the subkey */
	ar ^= sk->val[1];

					/* S-box lookup and permutation */
	return (ice_sbox[0][al >> 10] | ice_sbox[1][al & 0x3ff]
		| ice_sbox[2][ar >> 10] | ice_sbox[3][ar & 0x3ff]);
}


/*
 * Encrypt a block of 8 bytes of data with the given ICE key.
 */

void
IceKey::encrypt (
	const unsigned char	*ptext,
	unsigned char		*ctext
) const
{
	register int		i;
	register unsigned long	l, r;

	l = (((unsigned long) ptext[0]) << 24)
				| (((unsigned long) ptext[1]) << 16)
				| (((unsigned long) ptext[2]) << 8) | ptext[3];
	r = (((unsigned long) ptext[4]) << 24)
				| (((unsigned long) ptext[5]) << 16)
				| (((unsigned long) ptext[6]) << 8) | ptext[7];

	for (i = 0; i < _rounds; i += 2) {
	    l ^= ice_f (r, &_keysched[i]);
	    r ^= ice_f (l, &_keysched[i + 1]);
	}

	for (i = 0; i < 4; i++) {
	    ctext[3 - i] = r & 0xff;
	    ctext[7 - i] = l & 0xff;

	    r >>= 8;
	    l >>= 8;
	}
}


/*
 * Decrypt a block of 8 bytes of data with the given ICE key.
 */

void
IceKey::decrypt (
	const unsigned char	*ctext,
	unsigned char		*ptext
) const
{
	register int		i;
	register unsigned long	l, r;

	l = (((unsigned long) ctext[0]) << 24)
				| (((unsigned long) ctext[1]) << 16)
				| (((unsigned long) ctext[2]) << 8) | ctext[3];
	r = (((unsigned long) ctext[4]) << 24)
				| (((unsigned long) ctext[5]) << 16)
				| (((unsigned long) ctext[6]) << 8) | ctext[7];

	for (i = _rounds - 1; i > 0; i -= 2) {
	    l ^= ice_f (r, &_keysched[i]);
	    r ^= ice_f (l, &_keysched[i - 1]);
	}

	for (i = 0; i < 4; i++) {
	    ptext[3 - i] = r & 0xff;
	    ptext[7 - i] = l & 0xff;

	    r >>= 8;
	    l >>= 8;
	}
}


/*
 * Set 8 rounds [n, n+7] of the key schedule of an ICE key.
 */

void
IceKey::scheduleBuild (
	unsigned short	*kb,
	int		n,
	const int	*keyrot
) {
	int		i;

	for (i=0; i<8; i++) {
	    register int	j;
	    register int	kr = keyrot[i];
	    IceSubkey		*isk = &_keysched[n + i];

	    for (j=0; j<3; j++)
		isk->val[j] = 0;

	    for (j=0; j<15; j++) {
		register int	k;
		unsigned long	*curr_sk = &isk->val[j % 3];

		for (k=0; k<4; k++) {
		    unsigned short	*curr_kb = &kb[(kr + k) & 3];
		    register int	bit = *curr_kb & 1;

		    *curr_sk = (*curr_sk << 1) | bit;
		    *curr_kb = (*curr_kb >> 1) | ((bit ^ 1) << 15);
		}
	    }
	}
}


/*
 * Set the key schedule of an ICE key.
 */

void
IceKey::set (
	const unsigned char	*key
) {
	int		i;

	if (_rounds == 8) {
	    unsigned short	kb[4];

	    for (i=0; i<4; i++)
		kb[3 - i] = (key[i*2] << 8) | key[i*2 + 1];

	    scheduleBuild (kb, 0, ice_keyrot);
	    return;
	}

	for (i=0; i<_size; i++) {
	    int			j;
	    unsigned short	kb[4];

	    for (j=0; j<4; j++)
		kb[3 - j] = (key[i*8 + j*2] << 8) | key[i*8 + j*2 + 1];

	    scheduleBuild (kb, i*8, ice_keyrot);
	    scheduleBuild (kb, _rounds - 8 - i*8, &ice_keyrot[8]);
	}
}


/*
 * Return the key size, in bytes.
 */

int
IceKey::keySize () const
{
	return (_size * 8);
}


/*
 * Return the block size, in bytes.
 */

int
IceKey::blockSize () const
{
	return (8);
}
1 5 years ago			`//========= Public Domain Code ================================================`
			`//`
			`// Purpose: C++ implementation of the ICE encryption algorithm.`
			`// Taken from public domain code, as written by Matthew Kwan - July 1996`
			`// http://www.darkside.com.au/ice/`
			`//=============================================================================`

			`#include "IceKey.H"`

			`#pragma warning(disable: 4244)`


			`/* Structure of a single round subkey */`
			`class IceSubkey {`
			`public:`
			`unsigned long val[3];`
			`};`


			`/* The S-boxes */`
			`static unsigned long ice_sbox[4][1024];`
			`static int ice_sboxes_initialised = 0;`


			`/* Modulo values for the S-boxes */`
			`static const int ice_smod[4][4] = {`
			`{333, 313, 505, 369},`
			`{379, 375, 319, 391},`
			`{361, 445, 451, 397},`
			`{397, 425, 395, 505}};`

			`/* XOR values for the S-boxes */`
			`static const int ice_sxor[4][4] = {`
			`{0x83, 0x85, 0x9b, 0xcd},`
			`{0xcc, 0xa7, 0xad, 0x41},`
			`{0x4b, 0x2e, 0xd4, 0x33},`
			`{0xea, 0xcb, 0x2e, 0x04}};`

			`/* Permutation values for the P-box */`
			`static const unsigned long ice_pbox[32] = {`
			`0x00000001, 0x00000080, 0x00000400, 0x00002000,`
			`0x00080000, 0x00200000, 0x01000000, 0x40000000,`
			`0x00000008, 0x00000020, 0x00000100, 0x00004000,`
			`0x00010000, 0x00800000, 0x04000000, 0x20000000,`
			`0x00000004, 0x00000010, 0x00000200, 0x00008000,`
			`0x00020000, 0x00400000, 0x08000000, 0x10000000,`
			`0x00000002, 0x00000040, 0x00000800, 0x00001000,`
			`0x00040000, 0x00100000, 0x02000000, 0x80000000};`

			`/* The key rotation schedule */`
			`static const int ice_keyrot[16] = {`
			`0, 1, 2, 3, 2, 1, 3, 0,`
			`1, 3, 2, 0, 3, 1, 0, 2};`


			`/*`
			`* 8-bit Galois Field multiplication of a by b, modulo m.`
			`* Just like arithmetic multiplication, except that additions and`
			`* subtractions are replaced by XOR.`
			`*/`

			`static unsigned int`
			`gf_mult (`
			`register unsigned int a,`
			`register unsigned int b,`
			`register unsigned int m`
			`) {`
			`register unsigned int res = 0;`

			`while (b) {`
			`if (b & 1)`
			`res ^= a;`

			`a <<= 1;`
			`b >>= 1;`

			`if (a >= 256)`
			`a ^= m;`
			`}`

			`return (res);`
			`}`


			`/*`
			`* Galois Field exponentiation.`
			`* Raise the base to the power of 7, modulo m.`
			`*/`

			`static unsigned long`
			`gf_exp7 (`
			`register unsigned int b,`
			`unsigned int m`
			`) {`
			`register unsigned int x;`

			`if (b == 0)`
			`return (0);`

			`x = gf_mult (b, b, m);`
			`x = gf_mult (b, x, m);`
			`x = gf_mult (x, x, m);`
			`return (gf_mult (b, x, m));`
			`}`


			`/*`
			`* Carry out the ICE 32-bit P-box permutation.`
			`*/`

			`static unsigned long`
			`ice_perm32 (`
			`register unsigned long x`
			`) {`
			`register unsigned long res = 0;`
			`register const unsigned long *pbox = ice_pbox;`

			`while (x) {`
			`if (x & 1)`
			`res \|= *pbox;`
			`pbox++;`
			`x >>= 1;`
			`}`

			`return (res);`
			`}`


			`/*`
			`* Initialise the ICE S-boxes.`
			`* This only has to be done once.`
			`*/`

			`static void`
			`ice_sboxes_init (void)`
			`{`
			`register int i;`

			`for (i=0; i<1024; i++) {`
			`int col = (i >> 1) & 0xff;`
			`int row = (i & 0x1) \| ((i & 0x200) >> 8);`
			`unsigned long x;`

			`x = gf_exp7 (col ^ ice_sxor[0][row], ice_smod[0][row]) << 24;`
			`ice_sbox[0][i] = ice_perm32 (x);`

			`x = gf_exp7 (col ^ ice_sxor[1][row], ice_smod[1][row]) << 16;`
			`ice_sbox[1][i] = ice_perm32 (x);`

			`x = gf_exp7 (col ^ ice_sxor[2][row], ice_smod[2][row]) << 8;`
			`ice_sbox[2][i] = ice_perm32 (x);`

			`x = gf_exp7 (col ^ ice_sxor[3][row], ice_smod[3][row]);`
			`ice_sbox[3][i] = ice_perm32 (x);`
			`}`
			`}`


			`/*`
			`* Create a new ICE key.`
			`*/`

			`IceKey::IceKey (int n)`
			`{`
			`if (!ice_sboxes_initialised) {`
			`ice_sboxes_init ();`
			`ice_sboxes_initialised = 1;`
			`}`

			`if (n < 1) {`
			`_size = 1;`
			`_rounds = 8;`
			`} else {`
			`_size = n;`
			`_rounds = n * 16;`
			`}`

			`_keysched = new IceSubkey[_rounds];`
			`}`


			`/*`
			`* Destroy an ICE key.`
			`*/`

			`IceKey::~IceKey ()`
			`{`
			`int i, j;`

			`for (i=0; i<_rounds; i++)`
			`for (j=0; j<3; j++)`
			`_keysched[i].val[j] = 0;`

			`_rounds = _size = 0;`

			`delete[] _keysched;`
			`}`


			`/*`
			`* The single round ICE f function.`
			`*/`

			`static unsigned long`
			`ice_f (`
			`register unsigned long p,`
			`const IceSubkey *sk`
			`) {`
			`unsigned long tl, tr; /* Expanded 40-bit values */`
			`unsigned long al, ar; /* Salted expanded 40-bit values */`

			`/* Left half expansion */`
			`tl = ((p >> 16) & 0x3ff) \| (((p >> 14) \| (p << 18)) & 0xffc00);`

			`/* Right half expansion */`
			`tr = (p & 0x3ff) \| ((p << 2) & 0xffc00);`

			`/* Perform the salt permutation */`
			`// al = (tr & sk->val[2]) \| (tl & ~sk->val[2]);`
			`// ar = (tl & sk->val[2]) \| (tr & ~sk->val[2]);`
			`al = sk->val[2] & (tl ^ tr);`
			`ar = al ^ tr;`
			`al ^= tl;`

			`al ^= sk->val[0]; /* XOR with the subkey */`
			`ar ^= sk->val[1];`

			`/* S-box lookup and permutation */`
			`return (ice_sbox[0][al >> 10] \| ice_sbox[1][al & 0x3ff]`
			`\| ice_sbox[2][ar >> 10] \| ice_sbox[3][ar & 0x3ff]);`
			`}`


			`/*`
			`* Encrypt a block of 8 bytes of data with the given ICE key.`
			`*/`

			`void`
			`IceKey::encrypt (`
			`const unsigned char *ptext,`
			`unsigned char *ctext`
			`) const`
			`{`
			`register int i;`
			`register unsigned long l, r;`

			`l = (((unsigned long) ptext[0]) << 24)`
			`\| (((unsigned long) ptext[1]) << 16)`
			`\| (((unsigned long) ptext[2]) << 8) \| ptext[3];`
			`r = (((unsigned long) ptext[4]) << 24)`
			`\| (((unsigned long) ptext[5]) << 16)`
			`\| (((unsigned long) ptext[6]) << 8) \| ptext[7];`

			`for (i = 0; i < _rounds; i += 2) {`
			`l ^= ice_f (r, &_keysched[i]);`
			`r ^= ice_f (l, &_keysched[i + 1]);`
			`}`

			`for (i = 0; i < 4; i++) {`
			`ctext[3 - i] = r & 0xff;`
			`ctext[7 - i] = l & 0xff;`

			`r >>= 8;`
			`l >>= 8;`
			`}`
			`}`


			`/*`
			`* Decrypt a block of 8 bytes of data with the given ICE key.`
			`*/`

			`void`
			`IceKey::decrypt (`
			`const unsigned char *ctext,`
			`unsigned char *ptext`
			`) const`
			`{`
			`register int i;`
			`register unsigned long l, r;`

			`l = (((unsigned long) ctext[0]) << 24)`
			`\| (((unsigned long) ctext[1]) << 16)`
			`\| (((unsigned long) ctext[2]) << 8) \| ctext[3];`
			`r = (((unsigned long) ctext[4]) << 24)`
			`\| (((unsigned long) ctext[5]) << 16)`
			`\| (((unsigned long) ctext[6]) << 8) \| ctext[7];`

			`for (i = _rounds - 1; i > 0; i -= 2) {`
			`l ^= ice_f (r, &_keysched[i]);`
			`r ^= ice_f (l, &_keysched[i - 1]);`
			`}`

			`for (i = 0; i < 4; i++) {`
			`ptext[3 - i] = r & 0xff;`
			`ptext[7 - i] = l & 0xff;`

			`r >>= 8;`
			`l >>= 8;`
			`}`
			`}`


			`/*`
			`* Set 8 rounds [n, n+7] of the key schedule of an ICE key.`
			`*/`

			`void`
			`IceKey::scheduleBuild (`
			`unsigned short *kb,`
			`int n,`
			`const int *keyrot`
			`) {`
			`int i;`

			`for (i=0; i<8; i++) {`
			`register int j;`
			`register int kr = keyrot[i];`
			`IceSubkey *isk = &_keysched[n + i];`

			`for (j=0; j<3; j++)`
			`isk->val[j] = 0;`

			`for (j=0; j<15; j++) {`
			`register int k;`
			`unsigned long *curr_sk = &isk->val[j % 3];`

			`for (k=0; k<4; k++) {`
			`unsigned short *curr_kb = &kb[(kr + k) & 3];`
			`register int bit = *curr_kb & 1;`

			`curr_sk = (curr_sk << 1) \| bit;`
			`curr_kb = (curr_kb >> 1) \| ((bit ^ 1) << 15);`
			`}`
			`}`
			`}`
			`}`


			`/*`
			`* Set the key schedule of an ICE key.`
			`*/`

			`void`
			`IceKey::set (`
			`const unsigned char *key`
			`) {`
			`int i;`

			`if (_rounds == 8) {`
			`unsigned short kb[4];`

			`for (i=0; i<4; i++)`
			`kb[3 - i] = (key[i2] << 8) \| key[i2 + 1];`

			`scheduleBuild (kb, 0, ice_keyrot);`
			`return;`
			`}`

			`for (i=0; i<_size; i++) {`
			`int j;`
			`unsigned short kb[4];`

			`for (j=0; j<4; j++)`
			`kb[3 - j] = (key[i8 + j2] << 8) \| key[i8 + j2 + 1];`

			`scheduleBuild (kb, i*8, ice_keyrot);`
			`scheduleBuild (kb, _rounds - 8 - i*8, &ice_keyrot[8]);`
			`}`
			`}`


			`/*`
			`* Return the key size, in bytes.`
			`*/`

			`int`
			`IceKey::keySize () const`
			`{`
			`return (_size * 8);`
			`}`


			`/*`
			`* Return the block size, in bytes.`
			`*/`

			`int`
			`IceKey::blockSize () const`
			`{`
			`return (8);`
			`}`