CryptoPkg/Library/BaseCryptLib/Pk/CryptRsaBasic.c - third_party/edk2 - Git at Google

 /** @file
   RSA Asymmetric Cipher Wrapper Implementation over OpenSSL.

   This file implements following APIs which provide basic capabilities for RSA:
   1) RsaNew
   2) RsaFree
   3) RsaSetKey
   4) RsaPkcs1Verify

 Copyright (c) 2009 - 2013, Intel Corporation. All rights reserved.<BR>
 This program and the accompanying materials
 are licensed and made available under the terms and conditions of the BSD License
 which accompanies this distribution.  The full text of the license may be found at
 http://opensource.org/licenses/bsd-license.php

 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
 WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.

 **/

 #include "InternalCryptLib.h"

 #include <openssl/rsa.h>
 #include <openssl/objects.h>

 /**
   Allocates and initializes one RSA context for subsequent use.

   @return  Pointer to the RSA context that has been initialized.
            If the allocations fails, RsaNew() returns NULL.

 **/
 VOID *
 EFIAPI
 RsaNew (
   VOID
   )
 {
   //
   // Allocates & Initializes RSA Context by OpenSSL RSA_new()
   //
   return (VOID *) RSA_new ();
 }

 /**
   Release the specified RSA context.

   @param[in]  RsaContext  Pointer to the RSA context to be released.

 **/
 VOID
 EFIAPI
 RsaFree (
   IN  VOID  *RsaContext
   )
 {
   //
   // Free OpenSSL RSA Context
   //
   RSA_free ((RSA *) RsaContext);
 }

 /**
   Sets the tag-designated key component into the established RSA context.

   This function sets the tag-designated RSA key component into the established
   RSA context from the user-specified non-negative integer (octet string format
   represented in RSA PKCS#1).
   If BigNumber is NULL, then the specified key componenet in RSA context is cleared.

   If RsaContext is NULL, then return FALSE.

   @param[in, out]  RsaContext  Pointer to RSA context being set.
   @param[in]       KeyTag      Tag of RSA key component being set.
   @param[in]       BigNumber   Pointer to octet integer buffer.
                                If NULL, then the specified key componenet in RSA
                                context is cleared.
   @param[in]       BnSize      Size of big number buffer in bytes.
                                If BigNumber is NULL, then it is ignored.

   @retval  TRUE   RSA key component was set successfully.
   @retval  FALSE  Invalid RSA key component tag.

 **/
 BOOLEAN
 EFIAPI
 RsaSetKey (
   IN OUT  VOID         *RsaContext,
   IN      RSA_KEY_TAG  KeyTag,
   IN      CONST UINT8  *BigNumber,
   IN      UINTN        BnSize
   )
 {
   RSA  *RsaKey;

   //
   // Check input parameters.
   //
   if (RsaContext == NULL || BnSize > INT_MAX) {
     return FALSE;
   }

   RsaKey = (RSA *) RsaContext;
   //
   // Set RSA Key Components by converting octet string to OpenSSL BN representation.
   // NOTE: For RSA public key (used in signature verification), only public components
   //       (N, e) are needed.
   //
   switch (KeyTag) {

   //
   // RSA Public Modulus (N)
   //
   case RsaKeyN:
     if (RsaKey->n != NULL) {
       BN_free (RsaKey->n);
     }
     RsaKey->n = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->n = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->n);
     if (RsaKey->n == NULL) {
       return FALSE;
     }

     break;

   //
   // RSA Public Exponent (e)
   //
   case RsaKeyE:
     if (RsaKey->e != NULL) {
       BN_free (RsaKey->e);
     }
     RsaKey->e = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->e = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->e);
     if (RsaKey->e == NULL) {
       return FALSE;
     }

     break;

   //
   // RSA Private Exponent (d)
   //
   case RsaKeyD:
     if (RsaKey->d != NULL) {
       BN_free (RsaKey->d);
     }
     RsaKey->d = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->d = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->d);
     if (RsaKey->d == NULL) {
       return FALSE;
     }

     break;

   //
   // RSA Secret Prime Factor of Modulus (p)
   //
   case RsaKeyP:
     if (RsaKey->p != NULL) {
       BN_free (RsaKey->p);
     }
     RsaKey->p = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->p = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->p);
     if (RsaKey->p == NULL) {
       return FALSE;
     }

     break;

   //
   // RSA Secret Prime Factor of Modules (q)
   //
   case RsaKeyQ:
     if (RsaKey->q != NULL) {
       BN_free (RsaKey->q);
     }
     RsaKey->q = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->q = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->q);
     if (RsaKey->q == NULL) {
       return FALSE;
     }

     break;

   //
   // p's CRT Exponent (== d mod (p - 1))
   //
   case RsaKeyDp:
     if (RsaKey->dmp1 != NULL) {
       BN_free (RsaKey->dmp1);
     }
     RsaKey->dmp1 = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->dmp1 = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->dmp1);
     if (RsaKey->dmp1 == NULL) {
       return FALSE;
     }

     break;

   //
   // q's CRT Exponent (== d mod (q - 1))
   //
   case RsaKeyDq:
     if (RsaKey->dmq1 != NULL) {
       BN_free (RsaKey->dmq1);
     }
     RsaKey->dmq1 = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->dmq1 = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->dmq1);
     if (RsaKey->dmq1 == NULL) {
       return FALSE;
     }

     break;

   //
   // The CRT Coefficient (== 1/q mod p)
   //
   case RsaKeyQInv:
     if (RsaKey->iqmp != NULL) {
       BN_free (RsaKey->iqmp);
     }
     RsaKey->iqmp = NULL;
     if (BigNumber == NULL) {
       break;
     }
     RsaKey->iqmp = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->iqmp);
     if (RsaKey->iqmp == NULL) {
       return FALSE;
     }

     break;

   default:
     return FALSE;
   }

   return TRUE;
 }

 /**
   Verifies the RSA-SSA signature with EMSA-PKCS1-v1_5 encoding scheme defined in
   RSA PKCS#1.

   If RsaContext is NULL, then return FALSE.
   If MessageHash is NULL, then return FALSE.
   If Signature is NULL, then return FALSE.
   If HashSize is not equal to the size of MD5, SHA-1 or SHA-256 digest, then return FALSE.

   @param[in]  RsaContext   Pointer to RSA context for signature verification.
   @param[in]  MessageHash  Pointer to octet message hash to be checked.
   @param[in]  HashSize     Size of the message hash in bytes.
   @param[in]  Signature    Pointer to RSA PKCS1-v1_5 signature to be verified.
   @param[in]  SigSize      Size of signature in bytes.

   @retval  TRUE   Valid signature encoded in PKCS1-v1_5.
   @retval  FALSE  Invalid signature or invalid RSA context.

 **/
 BOOLEAN
 EFIAPI
 RsaPkcs1Verify (
   IN  VOID         *RsaContext,
   IN  CONST UINT8  *MessageHash,
   IN  UINTN        HashSize,
   IN  CONST UINT8  *Signature,
   IN  UINTN        SigSize
   )
 {
   INT32    DigestType;
   UINT8    *SigBuf;

   //
   // Check input parameters.
   //
   if (RsaContext == NULL || MessageHash == NULL || Signature == NULL) {
     return FALSE;
   }

   if (SigSize > INT_MAX || SigSize == 0) {
     return FALSE;
   }

   //
   // Determine the message digest algorithm according to digest size.
   //   Only MD5, SHA-1 or SHA-256 algorithm is supported.
   //
   switch (HashSize) {
   case MD5_DIGEST_SIZE:
     DigestType = NID_md5;
     break;

   case SHA1_DIGEST_SIZE:
     DigestType = NID_sha1;
     break;

   case SHA256_DIGEST_SIZE:
     DigestType = NID_sha256;
     break;

   default:
     return FALSE;
   }

   SigBuf = (UINT8 *) Signature;
   return (BOOLEAN) RSA_verify (
                      DigestType,
                      MessageHash,
                      (UINT32) HashSize,
                      SigBuf,
                      (UINT32) SigSize,
                      (RSA *) RsaContext
                      );
 }
	/** @file
	RSA Asymmetric Cipher Wrapper Implementation over OpenSSL.

	This file implements following APIs which provide basic capabilities for RSA:
	1) RsaNew
	2) RsaFree
	3) RsaSetKey
	4) RsaPkcs1Verify

	Copyright (c) 2009 - 2013, Intel Corporation. All rights reserved.<BR>
	This program and the accompanying materials
	are licensed and made available under the terms and conditions of the BSD License
	which accompanies this distribution. The full text of the license may be found at
	http://opensource.org/licenses/bsd-license.php

	THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
	WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.

	**/

	#include "InternalCryptLib.h"

	#include <openssl/rsa.h>
	#include <openssl/objects.h>

	/**
	Allocates and initializes one RSA context for subsequent use.

	@return Pointer to the RSA context that has been initialized.
	If the allocations fails, RsaNew() returns NULL.

	**/
	VOID *
	EFIAPI
	RsaNew (
	VOID
	)
	{
	//
	// Allocates & Initializes RSA Context by OpenSSL RSA_new()
	//
	return (VOID *) RSA_new ();
	}

	/**
	Release the specified RSA context.

	@param[in] RsaContext Pointer to the RSA context to be released.

	**/
	VOID
	EFIAPI
	RsaFree (
	IN VOID *RsaContext
	)
	{
	//
	// Free OpenSSL RSA Context
	//
	RSA_free ((RSA *) RsaContext);
	}

	/**
	Sets the tag-designated key component into the established RSA context.

	This function sets the tag-designated RSA key component into the established
	RSA context from the user-specified non-negative integer (octet string format
	represented in RSA PKCS#1).
	If BigNumber is NULL, then the specified key componenet in RSA context is cleared.

	If RsaContext is NULL, then return FALSE.

	@param[in, out] RsaContext Pointer to RSA context being set.
	@param[in] KeyTag Tag of RSA key component being set.
	@param[in] BigNumber Pointer to octet integer buffer.
	If NULL, then the specified key componenet in RSA
	context is cleared.
	@param[in] BnSize Size of big number buffer in bytes.
	If BigNumber is NULL, then it is ignored.

	@retval TRUE RSA key component was set successfully.
	@retval FALSE Invalid RSA key component tag.

	**/
	BOOLEAN
	EFIAPI
	RsaSetKey (
	IN OUT VOID *RsaContext,
	IN RSA_KEY_TAG KeyTag,
	IN CONST UINT8 *BigNumber,
	IN UINTN BnSize
	)
	{
	RSA *RsaKey;

	//
	// Check input parameters.
	//
	if (RsaContext == NULL \|\| BnSize > INT_MAX) {
	return FALSE;
	}

	RsaKey = (RSA *) RsaContext;
	//
	// Set RSA Key Components by converting octet string to OpenSSL BN representation.
	// NOTE: For RSA public key (used in signature verification), only public components
	// (N, e) are needed.
	//
	switch (KeyTag) {

	//
	// RSA Public Modulus (N)
	//
	case RsaKeyN:
	if (RsaKey->n != NULL) {
	BN_free (RsaKey->n);
	}
	RsaKey->n = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->n = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->n);
	if (RsaKey->n == NULL) {
	return FALSE;
	}

	break;

	//
	// RSA Public Exponent (e)
	//
	case RsaKeyE:
	if (RsaKey->e != NULL) {
	BN_free (RsaKey->e);
	}
	RsaKey->e = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->e = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->e);
	if (RsaKey->e == NULL) {
	return FALSE;
	}

	break;

	//
	// RSA Private Exponent (d)
	//
	case RsaKeyD:
	if (RsaKey->d != NULL) {
	BN_free (RsaKey->d);
	}
	RsaKey->d = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->d = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->d);
	if (RsaKey->d == NULL) {
	return FALSE;
	}

	break;

	//
	// RSA Secret Prime Factor of Modulus (p)
	//
	case RsaKeyP:
	if (RsaKey->p != NULL) {
	BN_free (RsaKey->p);
	}
	RsaKey->p = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->p = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->p);
	if (RsaKey->p == NULL) {
	return FALSE;
	}

	break;

	//
	// RSA Secret Prime Factor of Modules (q)
	//
	case RsaKeyQ:
	if (RsaKey->q != NULL) {
	BN_free (RsaKey->q);
	}
	RsaKey->q = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->q = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->q);
	if (RsaKey->q == NULL) {
	return FALSE;
	}

	break;

	//
	// p's CRT Exponent (== d mod (p - 1))
	//
	case RsaKeyDp:
	if (RsaKey->dmp1 != NULL) {
	BN_free (RsaKey->dmp1);
	}
	RsaKey->dmp1 = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->dmp1 = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->dmp1);
	if (RsaKey->dmp1 == NULL) {
	return FALSE;
	}

	break;

	//
	// q's CRT Exponent (== d mod (q - 1))
	//
	case RsaKeyDq:
	if (RsaKey->dmq1 != NULL) {
	BN_free (RsaKey->dmq1);
	}
	RsaKey->dmq1 = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->dmq1 = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->dmq1);
	if (RsaKey->dmq1 == NULL) {
	return FALSE;
	}

	break;

	//
	// The CRT Coefficient (== 1/q mod p)
	//
	case RsaKeyQInv:
	if (RsaKey->iqmp != NULL) {
	BN_free (RsaKey->iqmp);
	}
	RsaKey->iqmp = NULL;
	if (BigNumber == NULL) {
	break;
	}
	RsaKey->iqmp = BN_bin2bn (BigNumber, (UINT32) BnSize, RsaKey->iqmp);
	if (RsaKey->iqmp == NULL) {
	return FALSE;
	}

	break;

	default:
	return FALSE;
	}

	return TRUE;
	}

	/**
	Verifies the RSA-SSA signature with EMSA-PKCS1-v1_5 encoding scheme defined in
	RSA PKCS#1.

	If RsaContext is NULL, then return FALSE.
	If MessageHash is NULL, then return FALSE.
	If Signature is NULL, then return FALSE.
	If HashSize is not equal to the size of MD5, SHA-1 or SHA-256 digest, then return FALSE.

	@param[in] RsaContext Pointer to RSA context for signature verification.
	@param[in] MessageHash Pointer to octet message hash to be checked.
	@param[in] HashSize Size of the message hash in bytes.
	@param[in] Signature Pointer to RSA PKCS1-v1_5 signature to be verified.
	@param[in] SigSize Size of signature in bytes.

	@retval TRUE Valid signature encoded in PKCS1-v1_5.
	@retval FALSE Invalid signature or invalid RSA context.

	**/
	BOOLEAN
	EFIAPI
	RsaPkcs1Verify (
	IN VOID *RsaContext,
	IN CONST UINT8 *MessageHash,
	IN UINTN HashSize,
	IN CONST UINT8 *Signature,
	IN UINTN SigSize
	)
	{
	INT32 DigestType;
	UINT8 *SigBuf;

	//
	// Check input parameters.
	//
	if (RsaContext == NULL \|\| MessageHash == NULL \|\| Signature == NULL) {
	return FALSE;
	}

	if (SigSize > INT_MAX \|\| SigSize == 0) {
	return FALSE;
	}

	//
	// Determine the message digest algorithm according to digest size.
	// Only MD5, SHA-1 or SHA-256 algorithm is supported.
	//
	switch (HashSize) {
	case MD5_DIGEST_SIZE:
	DigestType = NID_md5;
	break;

	case SHA1_DIGEST_SIZE:
	DigestType = NID_sha1;
	break;

	case SHA256_DIGEST_SIZE:
	DigestType = NID_sha256;
	break;

	default:
	return FALSE;
	}

	SigBuf = (UINT8 *) Signature;
	return (BOOLEAN) RSA_verify (
	DigestType,
	MessageHash,
	(UINT32) HashSize,
	SigBuf,
	(UINT32) SigSize,
	(RSA *) RsaContext
	);
	}