yarrow.c - third_party/dropbear - Git at Google

 /* LibTomCrypt, modular cryptographic library -- Tom St Denis
  *
  * LibTomCrypt is a library that provides various cryptographic
  * algorithms in a highly modular and flexible manner.
  *
  * The library is free for all purposes without any express
  * guarantee it works.
  *
  * Tom St Denis, tomstdenis@iahu.ca, http://libtomcrypt.org
  */

 #include "mycrypt.h"

 #ifdef YARROW

 const struct _prng_descriptor yarrow_desc =
 {
     "yarrow",
     &yarrow_start,
     &yarrow_add_entropy,
     &yarrow_ready,
     &yarrow_read
 };

 int yarrow_start(prng_state *prng)
 {
    int err;

    _ARGCHK(prng != NULL);

    /* these are the default hash/cipher combo used */
 #ifdef RIJNDAEL
 #if    YARROW_AES==0
    prng->yarrow.cipher = register_cipher(&rijndael_enc_desc);
 #elif  YARROW_AES==1
    prng->yarrow.cipher = register_cipher(&aes_enc_desc);
 #elif  YARROW_AES==2
    prng->yarrow.cipher = register_cipher(&rijndael_desc);
 #elif  YARROW_AES==3
    prng->yarrow.cipher = register_cipher(&aes_desc);
 #endif
 #elif defined(BLOWFISH)
    prng->yarrow.cipher = register_cipher(&blowfish_desc);
 #elif defined(TWOFISH)
    prng->yarrow.cipher = register_cipher(&twofish_desc);
 #elif defined(RC6)
    prng->yarrow.cipher = register_cipher(&rc6_desc);
 #elif defined(RC5)
    prng->yarrow.cipher = register_cipher(&rc5_desc);
 #elif defined(SAFERP)
    prng->yarrow.cipher = register_cipher(&saferp_desc);
 #elif defined(RC2)
    prng->yarrow.cipher = register_cipher(&rc2_desc);
 #elif defined(NOEKEON)
    prng->yarrow.cipher = register_cipher(&noekeon_desc);
 #elif defined(CAST5)
    prng->yarrow.cipher = register_cipher(&cast5_desc);
 #elif defined(XTEA)
    prng->yarrow.cipher = register_cipher(&xtea_desc);
 #elif defined(SAFER)
    prng->yarrow.cipher = register_cipher(&safer_sk128_desc);
 #elif defined(DES)
    prng->yarrow.cipher = register_cipher(&des3_desc);
 #elif
    #error YARROW needs at least one CIPHER
 #endif
    if ((err = cipher_is_valid(prng->yarrow.cipher)) != CRYPT_OK) {
       return err;
    }

 #ifdef SHA256
    prng->yarrow.hash   = register_hash(&sha256_desc);
 #elif defined(SHA512)
    prng->yarrow.hash   = register_hash(&sha512_desc);
 #elif defined(TIGER)
    prng->yarrow.hash   = register_hash(&tiger_desc);
 #elif defined(SHA1)
    prng->yarrow.hash   = register_hash(&sha1_desc);
 #elif defined(RIPEMD160)
    prng->yarrow.hash   = register_hash(&rmd160_desc);
 #elif defined(RIPEMD128)
    prng->yarrow.hash   = register_hash(&rmd128_desc);
 #elif defined(MD5)
    prng->yarrow.hash   = register_hash(&md5_desc);
 #elif defined(MD4)
    prng->yarrow.hash   = register_hash(&md4_desc);
 #elif defined(MD2)
    prng->yarrow.hash   = register_hash(&md2_desc);
 #elif defined(WHIRLPOOL)
    prng->yarrow.hash   = register_hash(&whirlpool_desc);
 #else
    #error YARROW needs at least one HASH
 #endif
    if ((err = hash_is_valid(prng->yarrow.hash)) != CRYPT_OK) {
       return err;
    }

    /* zero the memory used */
    zeromem(prng->yarrow.pool, sizeof(prng->yarrow.pool));

    return CRYPT_OK;
 }

 int yarrow_add_entropy(const unsigned char *buf, unsigned long len, prng_state *prng)
 {
    hash_state md;
    int err;

    _ARGCHK(buf  != NULL);
    _ARGCHK(prng != NULL);

    if ((err = hash_is_valid(prng->yarrow.hash)) != CRYPT_OK) {
       return err;
    }

    /* start the hash */
    hash_descriptor[prng->yarrow.hash].init(&md);

    /* hash the current pool */
    if ((err = hash_descriptor[prng->yarrow.hash].process(&md, prng->yarrow.pool,
                                                         hash_descriptor[prng->yarrow.hash].hashsize)) != CRYPT_OK) {
       return err;
    }

    /* add the new entropy */
    if ((err = hash_descriptor[prng->yarrow.hash].process(&md, buf, len)) != CRYPT_OK) {
       return err;
    }

    /* store result */
    if ((err = hash_descriptor[prng->yarrow.hash].done(&md, prng->yarrow.pool)) != CRYPT_OK) {
       return err;
    }

    return CRYPT_OK;
 }

 int yarrow_ready(prng_state *prng)
 {
    int ks, err;

    _ARGCHK(prng != NULL);

    if ((err = hash_is_valid(prng->yarrow.hash)) != CRYPT_OK) {
       return err;
    }

    if ((err = cipher_is_valid(prng->yarrow.cipher)) != CRYPT_OK) {
       return err;
    }

    /* setup CTR mode using the "pool" as the key */
    ks = (int)hash_descriptor[prng->yarrow.hash].hashsize;
    if ((err = cipher_descriptor[prng->yarrow.cipher].keysize(&ks)) != CRYPT_OK) {
       return err;
    }

    if ((err = ctr_start(prng->yarrow.cipher,     /* what cipher to use */
                         prng->yarrow.pool,       /* IV */
                         prng->yarrow.pool, ks,   /* KEY and key size */
                         0,                       /* number of rounds */
                         &prng->yarrow.ctr)) != CRYPT_OK) {
       return err;
    }
    return CRYPT_OK;
 }

 unsigned long yarrow_read(unsigned char *buf, unsigned long len, prng_state *prng)
 {
    _ARGCHK(buf  != NULL);
    _ARGCHK(prng != NULL);

    /* put buf in predictable state first */
    zeromem(buf, len);

    /* now randomize it */
    if (ctr_encrypt(buf, buf, len, &prng->yarrow.ctr) != CRYPT_OK) {
       return 0;
    }
    return len;
 }

 #endif
	/* LibTomCrypt, modular cryptographic library -- Tom St Denis
	*
	* LibTomCrypt is a library that provides various cryptographic
	* algorithms in a highly modular and flexible manner.
	*
	* The library is free for all purposes without any express
	* guarantee it works.
	*
	* Tom St Denis, tomstdenis@iahu.ca, http://libtomcrypt.org
	*/

	#include "mycrypt.h"

	#ifdef YARROW

	const struct _prng_descriptor yarrow_desc =
	{
	"yarrow",
	&yarrow_start,
	&yarrow_add_entropy,
	&yarrow_ready,
	&yarrow_read
	};

	int yarrow_start(prng_state *prng)
	{
	int err;

	_ARGCHK(prng != NULL);

	/* these are the default hash/cipher combo used */
	#ifdef RIJNDAEL
	#if YARROW_AES==0
	prng->yarrow.cipher = register_cipher(&rijndael_enc_desc);
	#elif YARROW_AES==1
	prng->yarrow.cipher = register_cipher(&aes_enc_desc);
	#elif YARROW_AES==2
	prng->yarrow.cipher = register_cipher(&rijndael_desc);
	#elif YARROW_AES==3
	prng->yarrow.cipher = register_cipher(&aes_desc);
	#endif
	#elif defined(BLOWFISH)
	prng->yarrow.cipher = register_cipher(&blowfish_desc);
	#elif defined(TWOFISH)
	prng->yarrow.cipher = register_cipher(&twofish_desc);
	#elif defined(RC6)
	prng->yarrow.cipher = register_cipher(&rc6_desc);
	#elif defined(RC5)
	prng->yarrow.cipher = register_cipher(&rc5_desc);
	#elif defined(SAFERP)
	prng->yarrow.cipher = register_cipher(&saferp_desc);
	#elif defined(RC2)
	prng->yarrow.cipher = register_cipher(&rc2_desc);
	#elif defined(NOEKEON)
	prng->yarrow.cipher = register_cipher(&noekeon_desc);
	#elif defined(CAST5)
	prng->yarrow.cipher = register_cipher(&cast5_desc);
	#elif defined(XTEA)
	prng->yarrow.cipher = register_cipher(&xtea_desc);
	#elif defined(SAFER)
	prng->yarrow.cipher = register_cipher(&safer_sk128_desc);
	#elif defined(DES)
	prng->yarrow.cipher = register_cipher(&des3_desc);
	#elif
	#error YARROW needs at least one CIPHER
	#endif
	if ((err = cipher_is_valid(prng->yarrow.cipher)) != CRYPT_OK) {
	return err;
	}

	#ifdef SHA256
	prng->yarrow.hash = register_hash(&sha256_desc);
	#elif defined(SHA512)
	prng->yarrow.hash = register_hash(&sha512_desc);
	#elif defined(TIGER)
	prng->yarrow.hash = register_hash(&tiger_desc);
	#elif defined(SHA1)
	prng->yarrow.hash = register_hash(&sha1_desc);
	#elif defined(RIPEMD160)
	prng->yarrow.hash = register_hash(&rmd160_desc);
	#elif defined(RIPEMD128)
	prng->yarrow.hash = register_hash(&rmd128_desc);
	#elif defined(MD5)
	prng->yarrow.hash = register_hash(&md5_desc);
	#elif defined(MD4)
	prng->yarrow.hash = register_hash(&md4_desc);
	#elif defined(MD2)
	prng->yarrow.hash = register_hash(&md2_desc);
	#elif defined(WHIRLPOOL)
	prng->yarrow.hash = register_hash(&whirlpool_desc);
	#else
	#error YARROW needs at least one HASH
	#endif
	if ((err = hash_is_valid(prng->yarrow.hash)) != CRYPT_OK) {
	return err;
	}

	/* zero the memory used */
	zeromem(prng->yarrow.pool, sizeof(prng->yarrow.pool));

	return CRYPT_OK;
	}

	int yarrow_add_entropy(const unsigned char buf, unsigned long len, prng_state prng)
	{
	hash_state md;
	int err;

	_ARGCHK(buf != NULL);
	_ARGCHK(prng != NULL);

	if ((err = hash_is_valid(prng->yarrow.hash)) != CRYPT_OK) {
	return err;
	}

	/* start the hash */
	hash_descriptor[prng->yarrow.hash].init(&md);

	/* hash the current pool */
	if ((err = hash_descriptor[prng->yarrow.hash].process(&md, prng->yarrow.pool,
	hash_descriptor[prng->yarrow.hash].hashsize)) != CRYPT_OK) {
	return err;
	}

	/* add the new entropy */
	if ((err = hash_descriptor[prng->yarrow.hash].process(&md, buf, len)) != CRYPT_OK) {
	return err;
	}

	/* store result */
	if ((err = hash_descriptor[prng->yarrow.hash].done(&md, prng->yarrow.pool)) != CRYPT_OK) {
	return err;
	}

	return CRYPT_OK;
	}

	int yarrow_ready(prng_state *prng)
	{
	int ks, err;

	_ARGCHK(prng != NULL);

	if ((err = hash_is_valid(prng->yarrow.hash)) != CRYPT_OK) {
	return err;
	}

	if ((err = cipher_is_valid(prng->yarrow.cipher)) != CRYPT_OK) {
	return err;
	}

	/* setup CTR mode using the "pool" as the key */
	ks = (int)hash_descriptor[prng->yarrow.hash].hashsize;
	if ((err = cipher_descriptor[prng->yarrow.cipher].keysize(&ks)) != CRYPT_OK) {
	return err;
	}

	if ((err = ctr_start(prng->yarrow.cipher, /* what cipher to use */
	prng->yarrow.pool, /* IV */
	prng->yarrow.pool, ks, /* KEY and key size */
	0, /* number of rounds */
	&prng->yarrow.ctr)) != CRYPT_OK) {
	return err;
	}
	return CRYPT_OK;
	}

	unsigned long yarrow_read(unsigned char buf, unsigned long len, prng_state prng)
	{
	_ARGCHK(buf != NULL);
	_ARGCHK(prng != NULL);

	/* put buf in predictable state first */
	zeromem(buf, len);

	/* now randomize it */
	if (ctr_encrypt(buf, buf, len, &prng->yarrow.ctr) != CRYPT_OK) {
	return 0;
	}
	return len;
	}

	#endif