CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c - edk2 - Git at Google

 /** @file  Big number API implementation based on OpenSSL

   Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
   SPDX-License-Identifier: BSD-2-Clause-Patent

 **/

 #include "InternalCryptLib.h"
 #include <openssl/bn.h>

 /**
   Allocate new Big Number.

   @retval New BigNum opaque structure or NULL on failure.
 **/
 VOID *
 EFIAPI
 BigNumInit (
   VOID
   )
 {
   return BN_new ();
 }

 /**
   Allocate new Big Number and assign the provided value to it.

   @param[in]   Buf    Big endian encoded buffer.
   @param[in]   Len    Buffer length.

   @retval New BigNum opaque structure or NULL on failure.
 **/
 VOID *
 EFIAPI
 BigNumFromBin (
   IN CONST UINT8  *Buf,
   IN UINTN        Len
   )
 {
   return BN_bin2bn (Buf, (INT32)Len, NULL);
 }

 /**
   Convert the absolute value of Bn into big-endian form and store it at Buf.
   The Buf array should have at least BigNumBytes() in it.

   @param[in]   Bn     Big number to convert.
   @param[out]  Buf    Output buffer.

   @retval The length of the big-endian number placed at Buf or -1 on error.
 **/
 INTN
 EFIAPI
 BigNumToBin (
   IN CONST VOID  *Bn,
   OUT UINT8      *Buf
   )
 {
   return BN_bn2bin (Bn, Buf);
 }

 /**
   Free the Big Number.

   @param[in]   Bn      Big number to free.
   @param[in]   Clear   TRUE if the buffer should be cleared.
 **/
 VOID
 EFIAPI
 BigNumFree (
   IN VOID     *Bn,
   IN BOOLEAN  Clear
   )
 {
   if (Clear) {
     BN_clear_free (Bn);
   } else {
     BN_free (Bn);
   }
 }

 /**
   Calculate the sum of two Big Numbers.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnB     Big number.
   @param[out]  BnRes   The result of BnA + BnB.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumAdd (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnB,
   OUT VOID       *BnRes
   )
 {
   return (BOOLEAN)BN_add (BnRes, BnA, BnB);
 }

 /**
   Subtract two Big Numbers.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnB     Big number.
   @param[out]  BnRes   The result of BnA - BnB.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumSub (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnB,
   OUT VOID       *BnRes
   )
 {
   return (BOOLEAN)BN_sub (BnRes, BnA, BnB);
 }

 /**
   Calculate remainder: BnRes = BnA % BnB.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnB     Big number.
   @param[out]  BnRes   The result of BnA % BnB.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumMod (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnB,
   OUT VOID       *BnRes
   )
 {
   BOOLEAN  RetVal;
   BN_CTX   *Ctx;

   Ctx = BN_CTX_new ();
   if (Ctx == NULL) {
     return FALSE;
   }

   RetVal = (BOOLEAN)BN_mod (BnRes, BnA, BnB, Ctx);
   BN_CTX_free (Ctx);

   return RetVal;
 }

 /**
   Compute BnA to the BnP-th power modulo BnM.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnP     Big number (power).
   @param[in]   BnM     Big number (modulo).
   @param[out]  BnRes   The result of (BnA ^ BnP) % BnM.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumExpMod (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnP,
   IN CONST VOID  *BnM,
   OUT VOID       *BnRes
   )
 {
   BOOLEAN  RetVal;
   BN_CTX   *Ctx;

   Ctx = BN_CTX_new ();
   if (Ctx == NULL) {
     return FALSE;
   }

   RetVal = (BOOLEAN)BN_mod_exp (BnRes, BnA, BnP, BnM, Ctx);

   BN_CTX_free (Ctx);
   return RetVal;
 }

 /**
   Compute BnA inverse modulo BnM.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnM     Big number (modulo).
   @param[out]  BnRes   The result, such that (BnA * BnRes) % BnM == 1.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumInverseMod (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnM,
   OUT VOID       *BnRes
   )
 {
   BOOLEAN  RetVal;
   BN_CTX   *Ctx;

   Ctx = BN_CTX_new ();
   if (Ctx == NULL) {
     return FALSE;
   }

   RetVal = FALSE;
   if (BN_mod_inverse (BnRes, BnA, BnM, Ctx) != NULL) {
     RetVal = TRUE;
   }

   BN_CTX_free (Ctx);
   return RetVal;
 }

 /**
   Divide two Big Numbers.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnB     Big number.
   @param[out]  BnRes   The result, such that BnA / BnB.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumDiv (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnB,
   OUT VOID       *BnRes
   )
 {
   BOOLEAN  RetVal;
   BN_CTX   *Ctx;

   Ctx = BN_CTX_new ();
   if (Ctx == NULL) {
     return FALSE;
   }

   RetVal = (BOOLEAN)BN_div (BnRes, NULL, BnA, BnB, Ctx);
   BN_CTX_free (Ctx);

   return RetVal;
 }

 /**
   Multiply two Big Numbers modulo BnM.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnB     Big number.
   @param[in]   BnM     Big number (modulo).
   @param[out]  BnRes   The result, such that (BnA * BnB) % BnM.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumMulMod (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnB,
   IN CONST VOID  *BnM,
   OUT VOID       *BnRes
   )
 {
   BOOLEAN  RetVal;
   BN_CTX   *Ctx;

   Ctx = BN_CTX_new ();
   if (Ctx == NULL) {
     return FALSE;
   }

   RetVal = (BOOLEAN)BN_mod_mul (BnRes, BnA, BnB, BnM, Ctx);
   BN_CTX_free (Ctx);

   return RetVal;
 }

 /**
   Compare two Big Numbers.

   @param[in]   BnA     Big number.
   @param[in]   BnB     Big number.

   @retval 0          BnA == BnB.
   @retval 1          BnA > BnB.
   @retval -1         BnA < BnB.
 **/
 INTN
 EFIAPI
 BigNumCmp (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnB
   )
 {
   return BN_cmp (BnA, BnB);
 }

 /**
   Get number of bits in Bn.

   @param[in]   Bn     Big number.

   @retval Number of bits.
 **/
 UINTN
 EFIAPI
 BigNumBits (
   IN CONST VOID  *Bn
   )
 {
   return BN_num_bits (Bn);
 }

 /**
   Get number of bytes in Bn.

   @param[in]   Bn     Big number.

   @retval Number of bytes.
 **/
 UINTN
 EFIAPI
 BigNumBytes (
   IN CONST VOID  *Bn
   )
 {
   return BN_num_bytes (Bn);
 }

 /**
   Checks if Big Number equals to the given Num.

   @param[in]   Bn     Big number.
   @param[in]   Num    Number.

   @retval TRUE   iff Bn == Num.
   @retval FALSE  otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumIsWord (
   IN CONST VOID  *Bn,
   IN UINTN       Num
   )
 {
   return (BOOLEAN)BN_is_word (Bn, Num);
 }

 /**
   Checks if Big Number is odd.

   @param[in]   Bn     Big number.

   @retval TRUE   Bn is odd (Bn % 2 == 1).
   @retval FALSE  otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumIsOdd (
   IN CONST VOID  *Bn
   )
 {
   return (BOOLEAN)BN_is_odd (Bn);
 }

 /**
   Copy Big number.

   @param[out]  BnDst     Destination.
   @param[in]   BnSrc     Source.

   @retval BnDst on success.
   @retval NULL otherwise.
 **/
 VOID *
 EFIAPI
 BigNumCopy (
   OUT VOID       *BnDst,
   IN CONST VOID  *BnSrc
   )
 {
   return BN_copy (BnDst, BnSrc);
 }

 /**
   Get constant Big number with value of "1".
   This may be used to save expensive allocations.

   @retval Big Number with value of 1.
 **/
 CONST VOID *
 EFIAPI
 BigNumValueOne (
   VOID
   )
 {
   return BN_value_one ();
 }

 /**
   Shift right Big Number.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   Bn      Big number.
   @param[in]   N       Number of bits to shift.
   @param[out]  BnRes   The result.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumRShift (
   IN CONST VOID  *Bn,
   IN UINTN       N,
   OUT VOID       *BnRes
   )
 {
   return (BOOLEAN)BN_rshift (BnRes, Bn, (INT32)N);
 }

 /**
   Mark Big Number for constant time computations.
   This function should be called before any constant time computations are
   performed on the given Big number.

   @param[in]   Bn     Big number
 **/
 VOID
 EFIAPI
 BigNumConstTime (
   IN VOID  *Bn
   )
 {
   BN_set_flags (Bn, BN_FLG_CONSTTIME);
 }

 /**
   Calculate square modulo.
   Please note, all "out" Big number arguments should be properly initialized
   by calling to BigNumInit() or BigNumFromBin() functions.

   @param[in]   BnA     Big number.
   @param[in]   BnM     Big number (modulo).
   @param[out]  BnRes   The result, such that (BnA ^ 2) % BnM.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumSqrMod (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnM,
   OUT VOID       *BnRes
   )
 {
   BOOLEAN  RetVal;
   BN_CTX   *Ctx;

   Ctx = BN_CTX_new ();
   if (Ctx == NULL) {
     return FALSE;
   }

   RetVal = (BOOLEAN)BN_mod_sqr (BnRes, BnA, BnM, Ctx);
   BN_CTX_free (Ctx);

   return RetVal;
 }

 /**
   Create new Big Number computation context. This is an opaque structure
   which should be passed to any function that requires it. The BN context is
   needed to optimize calculations and expensive allocations.

   @retval Big Number context struct or NULL on failure.
 **/
 VOID *
 EFIAPI
 BigNumNewContext (
   VOID
   )
 {
   return BN_CTX_new ();
 }

 /**
   Free Big Number context that was allocated with BigNumNewContext().

   @param[in]   BnCtx     Big number context to free.
 **/
 VOID
 EFIAPI
 BigNumContextFree (
   IN VOID  *BnCtx
   )
 {
   BN_CTX_free (BnCtx);
 }

 /**
   Set Big Number to a given value.

   @param[in]   Bn     Big number to set.
   @param[in]   Val    Value to set.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumSetUint (
   IN VOID   *Bn,
   IN UINTN  Val
   )
 {
   return (BOOLEAN)BN_set_word (Bn, Val);
 }

 /**
   Add two Big Numbers modulo BnM.

   @param[in]   BnA       Big number.
   @param[in]   BnB       Big number.
   @param[in]   BnM       Big number (modulo).
   @param[out]  BnRes     The result, such that (BnA + BnB) % BnM.

   @retval TRUE          On success.
   @retval FALSE         Otherwise.
 **/
 BOOLEAN
 EFIAPI
 BigNumAddMod (
   IN CONST VOID  *BnA,
   IN CONST VOID  *BnB,
   IN CONST VOID  *BnM,
   OUT VOID       *BnRes
   )
 {
   BOOLEAN  RetVal;
   BN_CTX   *Ctx;

   Ctx = BN_CTX_new ();
   if (Ctx == NULL) {
     return FALSE;
   }

   RetVal = (BOOLEAN)BN_mod_add (BnRes, BnA, BnB, BnM, Ctx);
   BN_CTX_free (Ctx);

   return RetVal;
 }
	/** @file Big number API implementation based on OpenSSL

	Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
	SPDX-License-Identifier: BSD-2-Clause-Patent

	**/

	#include "InternalCryptLib.h"
	#include <openssl/bn.h>

	/**
	Allocate new Big Number.

	@retval New BigNum opaque structure or NULL on failure.
	**/
	VOID *
	EFIAPI
	BigNumInit (
	VOID
	)
	{
	return BN_new ();
	}

	/**
	Allocate new Big Number and assign the provided value to it.

	@param[in] Buf Big endian encoded buffer.
	@param[in] Len Buffer length.

	@retval New BigNum opaque structure or NULL on failure.
	**/
	VOID *
	EFIAPI
	BigNumFromBin (
	IN CONST UINT8 *Buf,
	IN UINTN Len
	)
	{
	return BN_bin2bn (Buf, (INT32)Len, NULL);
	}

	/**
	Convert the absolute value of Bn into big-endian form and store it at Buf.
	The Buf array should have at least BigNumBytes() in it.

	@param[in] Bn Big number to convert.
	@param[out] Buf Output buffer.

	@retval The length of the big-endian number placed at Buf or -1 on error.
	**/
	INTN
	EFIAPI
	BigNumToBin (
	IN CONST VOID *Bn,
	OUT UINT8 *Buf
	)
	{
	return BN_bn2bin (Bn, Buf);
	}

	/**
	Free the Big Number.

	@param[in] Bn Big number to free.
	@param[in] Clear TRUE if the buffer should be cleared.
	**/
	VOID
	EFIAPI
	BigNumFree (
	IN VOID *Bn,
	IN BOOLEAN Clear
	)
	{
	if (Clear) {
	BN_clear_free (Bn);
	} else {
	BN_free (Bn);
	}
	}

	/**
	Calculate the sum of two Big Numbers.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnB Big number.
	@param[out] BnRes The result of BnA + BnB.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumAdd (
	IN CONST VOID *BnA,
	IN CONST VOID *BnB,
	OUT VOID *BnRes
	)
	{
	return (BOOLEAN)BN_add (BnRes, BnA, BnB);
	}

	/**
	Subtract two Big Numbers.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnB Big number.
	@param[out] BnRes The result of BnA - BnB.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumSub (
	IN CONST VOID *BnA,
	IN CONST VOID *BnB,
	OUT VOID *BnRes
	)
	{
	return (BOOLEAN)BN_sub (BnRes, BnA, BnB);
	}

	/**
	Calculate remainder: BnRes = BnA % BnB.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnB Big number.
	@param[out] BnRes The result of BnA % BnB.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumMod (
	IN CONST VOID *BnA,
	IN CONST VOID *BnB,
	OUT VOID *BnRes
	)
	{
	BOOLEAN RetVal;
	BN_CTX *Ctx;

	Ctx = BN_CTX_new ();
	if (Ctx == NULL) {
	return FALSE;
	}

	RetVal = (BOOLEAN)BN_mod (BnRes, BnA, BnB, Ctx);
	BN_CTX_free (Ctx);

	return RetVal;
	}

	/**
	Compute BnA to the BnP-th power modulo BnM.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnP Big number (power).
	@param[in] BnM Big number (modulo).
	@param[out] BnRes The result of (BnA ^ BnP) % BnM.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumExpMod (
	IN CONST VOID *BnA,
	IN CONST VOID *BnP,
	IN CONST VOID *BnM,
	OUT VOID *BnRes
	)
	{
	BOOLEAN RetVal;
	BN_CTX *Ctx;

	Ctx = BN_CTX_new ();
	if (Ctx == NULL) {
	return FALSE;
	}

	RetVal = (BOOLEAN)BN_mod_exp (BnRes, BnA, BnP, BnM, Ctx);

	BN_CTX_free (Ctx);
	return RetVal;
	}

	/**
	Compute BnA inverse modulo BnM.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnM Big number (modulo).
	@param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumInverseMod (
	IN CONST VOID *BnA,
	IN CONST VOID *BnM,
	OUT VOID *BnRes
	)
	{
	BOOLEAN RetVal;
	BN_CTX *Ctx;

	Ctx = BN_CTX_new ();
	if (Ctx == NULL) {
	return FALSE;
	}

	RetVal = FALSE;
	if (BN_mod_inverse (BnRes, BnA, BnM, Ctx) != NULL) {
	RetVal = TRUE;
	}

	BN_CTX_free (Ctx);
	return RetVal;
	}

	/**
	Divide two Big Numbers.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnB Big number.
	@param[out] BnRes The result, such that BnA / BnB.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumDiv (
	IN CONST VOID *BnA,
	IN CONST VOID *BnB,
	OUT VOID *BnRes
	)
	{
	BOOLEAN RetVal;
	BN_CTX *Ctx;

	Ctx = BN_CTX_new ();
	if (Ctx == NULL) {
	return FALSE;
	}

	RetVal = (BOOLEAN)BN_div (BnRes, NULL, BnA, BnB, Ctx);
	BN_CTX_free (Ctx);

	return RetVal;
	}

	/**
	Multiply two Big Numbers modulo BnM.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnB Big number.
	@param[in] BnM Big number (modulo).
	@param[out] BnRes The result, such that (BnA * BnB) % BnM.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumMulMod (
	IN CONST VOID *BnA,
	IN CONST VOID *BnB,
	IN CONST VOID *BnM,
	OUT VOID *BnRes
	)
	{
	BOOLEAN RetVal;
	BN_CTX *Ctx;

	Ctx = BN_CTX_new ();
	if (Ctx == NULL) {
	return FALSE;
	}

	RetVal = (BOOLEAN)BN_mod_mul (BnRes, BnA, BnB, BnM, Ctx);
	BN_CTX_free (Ctx);

	return RetVal;
	}

	/**
	Compare two Big Numbers.

	@param[in] BnA Big number.
	@param[in] BnB Big number.

	@retval 0 BnA == BnB.
	@retval 1 BnA > BnB.
	@retval -1 BnA < BnB.
	**/
	INTN
	EFIAPI
	BigNumCmp (
	IN CONST VOID *BnA,
	IN CONST VOID *BnB
	)
	{
	return BN_cmp (BnA, BnB);
	}

	/**
	Get number of bits in Bn.

	@param[in] Bn Big number.

	@retval Number of bits.
	**/
	UINTN
	EFIAPI
	BigNumBits (
	IN CONST VOID *Bn
	)
	{
	return BN_num_bits (Bn);
	}

	/**
	Get number of bytes in Bn.

	@param[in] Bn Big number.

	@retval Number of bytes.
	**/
	UINTN
	EFIAPI
	BigNumBytes (
	IN CONST VOID *Bn
	)
	{
	return BN_num_bytes (Bn);
	}

	/**
	Checks if Big Number equals to the given Num.

	@param[in] Bn Big number.
	@param[in] Num Number.

	@retval TRUE iff Bn == Num.
	@retval FALSE otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumIsWord (
	IN CONST VOID *Bn,
	IN UINTN Num
	)
	{
	return (BOOLEAN)BN_is_word (Bn, Num);
	}

	/**
	Checks if Big Number is odd.

	@param[in] Bn Big number.

	@retval TRUE Bn is odd (Bn % 2 == 1).
	@retval FALSE otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumIsOdd (
	IN CONST VOID *Bn
	)
	{
	return (BOOLEAN)BN_is_odd (Bn);
	}

	/**
	Copy Big number.

	@param[out] BnDst Destination.
	@param[in] BnSrc Source.

	@retval BnDst on success.
	@retval NULL otherwise.
	**/
	VOID *
	EFIAPI
	BigNumCopy (
	OUT VOID *BnDst,
	IN CONST VOID *BnSrc
	)
	{
	return BN_copy (BnDst, BnSrc);
	}

	/**
	Get constant Big number with value of "1".
	This may be used to save expensive allocations.

	@retval Big Number with value of 1.
	**/
	CONST VOID *
	EFIAPI
	BigNumValueOne (
	VOID
	)
	{
	return BN_value_one ();
	}

	/**
	Shift right Big Number.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] Bn Big number.
	@param[in] N Number of bits to shift.
	@param[out] BnRes The result.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumRShift (
	IN CONST VOID *Bn,
	IN UINTN N,
	OUT VOID *BnRes
	)
	{
	return (BOOLEAN)BN_rshift (BnRes, Bn, (INT32)N);
	}

	/**
	Mark Big Number for constant time computations.
	This function should be called before any constant time computations are
	performed on the given Big number.

	@param[in] Bn Big number
	**/
	VOID
	EFIAPI
	BigNumConstTime (
	IN VOID *Bn
	)
	{
	BN_set_flags (Bn, BN_FLG_CONSTTIME);
	}

	/**
	Calculate square modulo.
	Please note, all "out" Big number arguments should be properly initialized
	by calling to BigNumInit() or BigNumFromBin() functions.

	@param[in] BnA Big number.
	@param[in] BnM Big number (modulo).
	@param[out] BnRes The result, such that (BnA ^ 2) % BnM.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumSqrMod (
	IN CONST VOID *BnA,
	IN CONST VOID *BnM,
	OUT VOID *BnRes
	)
	{
	BOOLEAN RetVal;
	BN_CTX *Ctx;

	Ctx = BN_CTX_new ();
	if (Ctx == NULL) {
	return FALSE;
	}

	RetVal = (BOOLEAN)BN_mod_sqr (BnRes, BnA, BnM, Ctx);
	BN_CTX_free (Ctx);

	return RetVal;
	}

	/**
	Create new Big Number computation context. This is an opaque structure
	which should be passed to any function that requires it. The BN context is
	needed to optimize calculations and expensive allocations.

	@retval Big Number context struct or NULL on failure.
	**/
	VOID *
	EFIAPI
	BigNumNewContext (
	VOID
	)
	{
	return BN_CTX_new ();
	}

	/**
	Free Big Number context that was allocated with BigNumNewContext().

	@param[in] BnCtx Big number context to free.
	**/
	VOID
	EFIAPI
	BigNumContextFree (
	IN VOID *BnCtx
	)
	{
	BN_CTX_free (BnCtx);
	}

	/**
	Set Big Number to a given value.

	@param[in] Bn Big number to set.
	@param[in] Val Value to set.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumSetUint (
	IN VOID *Bn,
	IN UINTN Val
	)
	{
	return (BOOLEAN)BN_set_word (Bn, Val);
	}

	/**
	Add two Big Numbers modulo BnM.

	@param[in] BnA Big number.
	@param[in] BnB Big number.
	@param[in] BnM Big number (modulo).
	@param[out] BnRes The result, such that (BnA + BnB) % BnM.

	@retval TRUE On success.
	@retval FALSE Otherwise.
	**/
	BOOLEAN
	EFIAPI
	BigNumAddMod (
	IN CONST VOID *BnA,
	IN CONST VOID *BnB,
	IN CONST VOID *BnM,
	OUT VOID *BnRes
	)
	{
	BOOLEAN RetVal;
	BN_CTX *Ctx;

	Ctx = BN_CTX_new ();
	if (Ctx == NULL) {
	return FALSE;
	}

	RetVal = (BOOLEAN)BN_mod_add (BnRes, BnA, BnB, BnM, Ctx);
	BN_CTX_free (Ctx);

	return RetVal;
	}