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view libtomcrypt/src/pk/rsa/rsa_verify_hash.c @ 994:5c5ade336926

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Prefer stronger algorithms in algorithm negotiation. Prefer diffie-hellman-group14-sha1 (2048 bit) over diffie-hellman-group1-sha1 (1024 bit). Due to meet-in-the-middle attacks the effective key length of three key 3DES is 112 bits. AES is stronger and faster then 3DES. Prefer to delay the start of compression until after authentication has completed. This avoids exposing compression code to attacks from unauthenticated users. (github pull request #9)
author Fedor Brunner <fedor.brunner@azet.sk>
date Fri, 23 Jan 2015 23:00:25 +0800
parents 0cbe8f6dbf9e
children f849a5ca2efc
line wrap: on
line source

/* 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, [email protected], http://libtomcrypt.com
 */
#include "tomcrypt.h"

/**
  @file rsa_verify_hash.c
  RSA PKCS #1 v1.5 or v2 PSS signature verification, Tom St Denis and Andreas Lange
*/

#ifdef MRSA

/**
  PKCS #1 de-sign then v1.5 or PSS depad
  @param sig              The signature data
  @param siglen           The length of the signature data (octets)
  @param hash             The hash of the message that was signed
  @param hashlen          The length of the hash of the message that was signed (octets)
  @param padding          Type of padding (LTC_PKCS_1_PSS or LTC_PKCS_1_V1_5)
  @param hash_idx         The index of the desired hash
  @param saltlen          The length of the salt used during signature
  @param stat             [out] The result of the signature comparison, 1==valid, 0==invalid
  @param key              The public RSA key corresponding to the key that performed the signature
  @return CRYPT_OK on success (even if the signature is invalid)
*/
int rsa_verify_hash_ex(const unsigned char *sig,      unsigned long siglen,
                       const unsigned char *hash,     unsigned long hashlen,
                             int            padding,
                             int            hash_idx, unsigned long saltlen,
                             int           *stat,     rsa_key      *key)
{
  unsigned long modulus_bitlen, modulus_bytelen, x;
  int           err;
  unsigned char *tmpbuf;

  LTC_ARGCHK(hash  != NULL);
  LTC_ARGCHK(sig   != NULL);
  LTC_ARGCHK(stat  != NULL);
  LTC_ARGCHK(key   != NULL);

  /* default to invalid */
  *stat = 0;

  /* valid padding? */

  if ((padding != LTC_PKCS_1_V1_5) &&
      (padding != LTC_PKCS_1_PSS)) {
    return CRYPT_PK_INVALID_PADDING;
  }

  if (padding == LTC_PKCS_1_PSS) {
    /* valid hash ? */
    if ((err = hash_is_valid(hash_idx)) != CRYPT_OK) {
       return err;
    }
  }

  /* get modulus len in bits */
  modulus_bitlen = mp_count_bits( (key->N));

  /* outlen must be at least the size of the modulus */
  modulus_bytelen = mp_unsigned_bin_size( (key->N));
  if (modulus_bytelen != siglen) {
     return CRYPT_INVALID_PACKET;
  }

  /* allocate temp buffer for decoded sig */
  tmpbuf = XMALLOC(siglen);
  if (tmpbuf == NULL) {
     return CRYPT_MEM;
  }

  /* RSA decode it  */
  x = siglen;
  if ((err = ltc_mp.rsa_me(sig, siglen, tmpbuf, &x, PK_PUBLIC, key)) != CRYPT_OK) {
     XFREE(tmpbuf);
     return err;
  }

  /* make sure the output is the right size */
  if (x != siglen) {
     XFREE(tmpbuf);
     return CRYPT_INVALID_PACKET;
  }

  if (padding == LTC_PKCS_1_PSS) {
    /* PSS decode and verify it */
    err = pkcs_1_pss_decode(hash, hashlen, tmpbuf, x, saltlen, hash_idx, modulus_bitlen, stat);
  } else {
    /* PKCS #1 v1.5 decode it */
    unsigned char *out;
    unsigned long outlen, loid[16];
    int           decoded;
    ltc_asn1_list digestinfo[2], siginfo[2];

    /* not all hashes have OIDs... so sad */
    if (hash_descriptor[hash_idx].OIDlen == 0) {
       err = CRYPT_INVALID_ARG;
       goto bail_2;
    }

    /* allocate temp buffer for decoded hash */
    outlen = ((modulus_bitlen >> 3) + (modulus_bitlen & 7 ? 1 : 0)) - 3;
    out    = XMALLOC(outlen);
    if (out == NULL) {
      err = CRYPT_MEM;
      goto bail_2;
    }

    if ((err = pkcs_1_v1_5_decode(tmpbuf, x, LTC_PKCS_1_EMSA, modulus_bitlen, out, &outlen, &decoded)) != CRYPT_OK) {
      XFREE(out);       
      goto bail_2;
    }

    /* now we must decode out[0...outlen-1] using ASN.1, test the OID and then test the hash */
    /* construct the SEQUENCE 
      SEQUENCE {
         SEQUENCE {hashoid OID
                   blah    NULL
         }
         hash    OCTET STRING 
      }
   */
    LTC_SET_ASN1(digestinfo, 0, LTC_ASN1_OBJECT_IDENTIFIER, loid, sizeof(loid)/sizeof(loid[0]));
    LTC_SET_ASN1(digestinfo, 1, LTC_ASN1_NULL,              NULL,                          0);
    LTC_SET_ASN1(siginfo,    0, LTC_ASN1_SEQUENCE,          digestinfo,                    2);
    LTC_SET_ASN1(siginfo,    1, LTC_ASN1_OCTET_STRING,      tmpbuf,                        siglen);
   
    if ((err = der_decode_sequence(out, outlen, siginfo, 2)) != CRYPT_OK) {
       XFREE(out);
       goto bail_2;
    }

    /* test OID */
    if ((digestinfo[0].size == hash_descriptor[hash_idx].OIDlen) &&
        (XMEMCMP(digestinfo[0].data, hash_descriptor[hash_idx].OID, sizeof(unsigned long) * hash_descriptor[hash_idx].OIDlen) == 0) &&
        (siginfo[1].size == hashlen) &&
        (XMEMCMP(siginfo[1].data, hash, hashlen) == 0)) {
       *stat = 1;
    }

#ifdef LTC_CLEAN_STACK
    zeromem(out, outlen);
#endif
    XFREE(out);
  }

bail_2:
#ifdef LTC_CLEAN_STACK
  zeromem(tmpbuf, siglen);
#endif
  XFREE(tmpbuf);
  return err;
}

#endif /* MRSA */

/* $Source: /cvs/libtom/libtomcrypt/src/pk/rsa/rsa_verify_hash.c,v $ */
/* $Revision: 1.11 $ */
/* $Date: 2006/12/04 03:09:28 $ */