TPMCmd/tpm/src/crypt/BnConvert.c - platform/external/ms-tpm-20-ref - Git at Google

 /* Microsoft Reference Implementation for TPM 2.0
  *
  *  The copyright in this software is being made available under the BSD License,
  *  included below. This software may be subject to other third party and
  *  contributor rights, including patent rights, and no such rights are granted
  *  under this license.
  *
  *  Copyright (c) Microsoft Corporation
  *
  *  All rights reserved.
  *
  *  BSD License
  *
  *  Redistribution and use in source and binary forms, with or without modification,
  *  are permitted provided that the following conditions are met:
  *
  *  Redistributions of source code must retain the above copyright notice, this list
  *  of conditions and the following disclaimer.
  *
  *  Redistributions in binary form must reproduce the above copyright notice, this
  *  list of conditions and the following disclaimer in the documentation and/or
  *  other materials provided with the distribution.
  *
  *  THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ""AS IS""
  *  AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  *  IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
  *  DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR
  *  ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
  *  (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
  *  LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
  *  ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  *  (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
  *  SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */
 //** Introduction
 // This file contains the basic conversion functions that will convert TPM2B
 // to/from the internal format. The internal format is a bigNum,
 //

 //** Includes

 #include "Tpm.h"

 //** Functions

 //*** BnFromBytes()
 // This function will convert a big-endian byte array to the internal number
 // format. If bn is NULL, then the output is NULL. If bytes is null or the
 // required size is 0, then the output is set to zero
 LIB_EXPORT bigNum
 BnFromBytes(
     bigNum           bn,
     const BYTE      *bytes,
     NUMBYTES         nBytes
     )
 {
     const BYTE      *pFrom; // 'p' points to the least significant bytes of source
     BYTE            *pTo;   // points to least significant bytes of destination
     crypt_uword_t    size;
 //

     size = (bytes != NULL) ? BYTES_TO_CRYPT_WORDS(nBytes) : 0;

     // If nothing in, nothing out
     if(bn == NULL)
         return NULL;

     // make sure things fit
     pAssert(BnGetAllocated(bn) >= size);

     if(size > 0)
     {
         // Clear the topmost word in case it is not filled with data
         bn->d[size - 1] = 0;
         // Moving the input bytes from the end of the list (LSB) end
         pFrom = bytes + nBytes - 1;
         // To the LS0 of the LSW of the bigNum.
         pTo = (BYTE *)bn->d;
         for(; nBytes != 0; nBytes--)
             *pTo++ = *pFrom--;
         // For a little-endian machine, the conversion is a straight byte
         // reversal. For a big-endian machine, we have to put the words in
         // big-endian byte order
 #if BIG_ENDIAN_TPM
         {
             crypt_word_t   t;
             for(t = (crypt_word_t)size - 1; t >= 0; t--)
                 bn->d[t] = SWAP_CRYPT_WORD(bn->d[t]);
         }
 #endif
     }
     BnSetTop(bn, size);
     return bn;
 }

 //*** BnFrom2B()
 // Convert an TPM2B to a BIG_NUM.
 // If the input value does not exist, or the output does not exist, or the input
 // will not fit into the output the function returns NULL
 LIB_EXPORT bigNum
 BnFrom2B(
     bigNum           bn,         // OUT:
     const TPM2B     *a2B         // IN: number to convert
     )
 {
     if(a2B != NULL)
         return BnFromBytes(bn, a2B->buffer, a2B->size);
     // Make sure that the number has an initialized value rather than whatever
     // was there before
     BnSetTop(bn, 0);    // Function accepts NULL
     return NULL;
 }

 //*** BnFromHex()
 // Convert a hex string into a bigNum. This is primarily used in debugging.
 LIB_EXPORT bigNum
 BnFromHex(
     bigNum          bn,         // OUT:
     const char      *hex        // IN:
     )
 {
 #define FromHex(a)  ((a) - (((a) > 'a') ? ('a' + 10)                               \
                                        : ((a) > 'A') ? ('A' - 10) : '0'))
     unsigned             i;
     unsigned             wordCount;
     const char          *p;
     BYTE                *d = (BYTE *)&(bn->d[0]);
 //
     pAssert(bn && hex);
     i = (unsigned)strlen(hex);
     wordCount = BYTES_TO_CRYPT_WORDS((i + 1) / 2);
     if((i == 0) || (wordCount >= BnGetAllocated(bn)))
         BnSetWord(bn, 0);
     else
     {
         bn->d[wordCount - 1] = 0;
         p = hex + i - 1;
         for(;i > 1; i -= 2)
         {
             BYTE a;
             a = FromHex(*p);
             p--;
             *d++ = a + (FromHex(*p) << 4);
             p--;
         }
         if(i == 1)
             *d = FromHex(*p);
     }
 #if !BIG_ENDIAN_TPM
     for(i = 0; i < wordCount; i++)
         bn->d[i] = SWAP_CRYPT_WORD(bn->d[i]);
 #endif // BIG_ENDIAN_TPM
     BnSetTop(bn, wordCount);
     return bn;
 }

 //*** BnToBytes()
 // This function converts a BIG_NUM to a byte array. It converts the bigNum to a
 // big-endian byte string and sets 'size' to the normalized value. If  'size' is an
 // input 0, then the receiving buffer is guaranteed to be large enough for the result
 // and the size will be set to the size required for bigNum (leading zeros
 // suppressed).
 //
 // The conversion for a little-endian machine simply requires that all significant
 // bytes of the bigNum be reversed. For a big-endian machine, rather than
 // unpack each word individually, the bigNum is converted to little-endian words,
 // copied, and then converted back to big-endian.
 LIB_EXPORT BOOL
 BnToBytes(
     bigConst             bn,
     BYTE                *buffer,
     NUMBYTES            *size           // This the number of bytes that are
                                         // available in the buffer. The result
                                         // should be this big.
     )
 {
     crypt_uword_t        requiredSize;
     BYTE                *pFrom;
     BYTE                *pTo;
     crypt_uword_t        count;
 //
     // validate inputs
     pAssert(bn && buffer && size);

     requiredSize = (BnSizeInBits(bn) + 7) / 8;
     if(requiredSize == 0)
     {
         // If the input value is 0, return a byte of zero
         *size = 1;
         *buffer = 0;
     }
     else
     {
 #if BIG_ENDIAN_TPM
         // Copy the constant input value into a modifiable value
         BN_VAR(bnL, LARGEST_NUMBER_BITS * 2);
         BnCopy(bnL, bn);
         // byte swap the words in the local value to make them little-endian
         for(count = 0; count < bnL->size; count++)
             bnL->d[count] = SWAP_CRYPT_WORD(bnL->d[count]);
         bn = (bigConst)bnL;
 #endif
         if(*size == 0)
             *size = (NUMBYTES)requiredSize;
         pAssert(requiredSize <= *size);
         // Byte swap the number (not words but the whole value)
         count = *size;
         // Start from the least significant word and offset to the most significant
         // byte which is in some high word
         pFrom = (BYTE *)(&bn->d[0]) + requiredSize - 1;
         pTo = buffer;

         // If the number of output bytes is larger than the number bytes required
         // for the input number, pad with zeros
         for(count = *size; count > requiredSize; count--)
             *pTo++ = 0;
         // Move the most significant byte at the end of the BigNum to the next most
         // significant byte position of the 2B and repeat for all significant bytes.
         for(; requiredSize > 0; requiredSize--)
             *pTo++ = *pFrom--;
     }
     return TRUE;
 }

 //*** BnTo2B()
 // Function to convert a BIG_NUM to TPM2B.
 // The TPM2B size is set to the requested 'size' which may require padding.
 // If 'size' is non-zero and less than required by the value in 'bn' then an error
 // is returned. If 'size' is zero, then the TPM2B is assumed to be large enough
 // for the data and a2b->size will be adjusted accordingly.
 LIB_EXPORT BOOL
 BnTo2B(
     bigConst         bn,                // IN:
     TPM2B           *a2B,               // OUT:
     NUMBYTES         size               // IN: the desired size
     )
 {
     // Set the output size
     if(bn && a2B)
     {
         a2B->size = size;
         return BnToBytes(bn, a2B->buffer, &a2B->size);
     }
     return FALSE;
 }

 #if ALG_ECC

 //*** BnPointFrom2B()
 // Function to create a BIG_POINT structure from a 2B point.
 // A point is going to be two ECC values in the same buffer. The values are going
 // to be the size of the modulus.  They are in modular form.
 LIB_EXPORT bn_point_t   *
 BnPointFrom2B(
     bigPoint             ecP,         // OUT: the preallocated point structure
     TPMS_ECC_POINT      *p            // IN: the number to convert
     )
 {
     if(p == NULL)
         return NULL;

     if(NULL != ecP)
     {
         BnFrom2B(ecP->x, &p->x.b);
         BnFrom2B(ecP->y, &p->y.b);
         BnSetWord(ecP->z, 1);
     }
     return ecP;
 }

 //*** BnPointTo2B()
 // This function converts a BIG_POINT into a TPMS_ECC_POINT. A TPMS_ECC_POINT
 // contains two TPM2B_ECC_PARAMETER values. The maximum size of the parameters
 // is dependent on the maximum EC key size used in an implementation.
 // The presumption is that the TPMS_ECC_POINT is large enough to hold 2 TPM2B
 // values, each as large as a MAX_ECC_PARAMETER_BYTES
 LIB_EXPORT BOOL
 BnPointTo2B(
     TPMS_ECC_POINT  *p,             // OUT: the converted 2B structure
     bigPoint         ecP,           // IN: the values to be converted
     bigCurve         E              // IN: curve descriptor for the point
     )
 {
     UINT16           size;
 //
     pAssert(p && ecP && E);
     pAssert(BnEqualWord(ecP->z, 1));
     // BnMsb is the bit number of the MSB. This is one less than the number of bits
     size = (UINT16)BITS_TO_BYTES(BnSizeInBits(CurveGetOrder(AccessCurveData(E))));
     BnTo2B(ecP->x, &p->x.b, size);
     BnTo2B(ecP->y, &p->y.b, size);
     return TRUE;
 }

 #endif // ALG_ECC
	/* Microsoft Reference Implementation for TPM 2.0
	*
	* The copyright in this software is being made available under the BSD License,
	* included below. This software may be subject to other third party and
	* contributor rights, including patent rights, and no such rights are granted
	* under this license.
	*
	* Copyright (c) Microsoft Corporation
	*
	* All rights reserved.
	*
	* BSD License
	*
	* Redistribution and use in source and binary forms, with or without modification,
	* are permitted provided that the following conditions are met:
	*
	* Redistributions of source code must retain the above copyright notice, this list
	* of conditions and the following disclaimer.
	*
	* Redistributions in binary form must reproduce the above copyright notice, this
	* list of conditions and the following disclaimer in the documentation and/or
	* other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ""AS IS""
	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
	* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR
	* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
	* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
	* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
	* ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
	* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/
	//** Introduction
	// This file contains the basic conversion functions that will convert TPM2B
	// to/from the internal format. The internal format is a bigNum,
	//

	//** Includes

	#include "Tpm.h"

	//** Functions

	//*** BnFromBytes()
	// This function will convert a big-endian byte array to the internal number
	// format. If bn is NULL, then the output is NULL. If bytes is null or the
	// required size is 0, then the output is set to zero
	LIB_EXPORT bigNum
	BnFromBytes(
	bigNum bn,
	const BYTE *bytes,
	NUMBYTES nBytes
	)
	{
	const BYTE *pFrom; // 'p' points to the least significant bytes of source
	BYTE *pTo; // points to least significant bytes of destination
	crypt_uword_t size;
	//

	size = (bytes != NULL) ? BYTES_TO_CRYPT_WORDS(nBytes) : 0;

	// If nothing in, nothing out
	if(bn == NULL)
	return NULL;

	// make sure things fit
	pAssert(BnGetAllocated(bn) >= size);

	if(size > 0)
	{
	// Clear the topmost word in case it is not filled with data
	bn->d[size - 1] = 0;
	// Moving the input bytes from the end of the list (LSB) end
	pFrom = bytes + nBytes - 1;
	// To the LS0 of the LSW of the bigNum.
	pTo = (BYTE *)bn->d;
	for(; nBytes != 0; nBytes--)
	pTo++ = pFrom--;
	// For a little-endian machine, the conversion is a straight byte
	// reversal. For a big-endian machine, we have to put the words in
	// big-endian byte order
	#if BIG_ENDIAN_TPM
	{
	crypt_word_t t;
	for(t = (crypt_word_t)size - 1; t >= 0; t--)
	bn->d[t] = SWAP_CRYPT_WORD(bn->d[t]);
	}
	#endif
	}
	BnSetTop(bn, size);
	return bn;
	}

	//*** BnFrom2B()
	// Convert an TPM2B to a BIG_NUM.
	// If the input value does not exist, or the output does not exist, or the input
	// will not fit into the output the function returns NULL
	LIB_EXPORT bigNum
	BnFrom2B(
	bigNum bn, // OUT:
	const TPM2B *a2B // IN: number to convert
	)
	{
	if(a2B != NULL)
	return BnFromBytes(bn, a2B->buffer, a2B->size);
	// Make sure that the number has an initialized value rather than whatever
	// was there before
	BnSetTop(bn, 0); // Function accepts NULL
	return NULL;
	}

	//*** BnFromHex()
	// Convert a hex string into a bigNum. This is primarily used in debugging.
	LIB_EXPORT bigNum
	BnFromHex(
	bigNum bn, // OUT:
	const char *hex // IN:
	)
	{
	#define FromHex(a) ((a) - (((a) > 'a') ? ('a' + 10) \
	: ((a) > 'A') ? ('A' - 10) : '0'))
	unsigned i;
	unsigned wordCount;
	const char *p;
	BYTE d = (BYTE )&(bn->d[0]);
	//
	pAssert(bn && hex);
	i = (unsigned)strlen(hex);
	wordCount = BYTES_TO_CRYPT_WORDS((i + 1) / 2);
	if((i == 0) \|\| (wordCount >= BnGetAllocated(bn)))
	BnSetWord(bn, 0);
	else
	{
	bn->d[wordCount - 1] = 0;
	p = hex + i - 1;
	for(;i > 1; i -= 2)
	{
	BYTE a;
	a = FromHex(*p);
	p--;
	d++ = a + (FromHex(p) << 4);
	p--;
	}
	if(i == 1)
	d = FromHex(p);
	}
	#if !BIG_ENDIAN_TPM
	for(i = 0; i < wordCount; i++)
	bn->d[i] = SWAP_CRYPT_WORD(bn->d[i]);
	#endif // BIG_ENDIAN_TPM
	BnSetTop(bn, wordCount);
	return bn;
	}

	//*** BnToBytes()
	// This function converts a BIG_NUM to a byte array. It converts the bigNum to a
	// big-endian byte string and sets 'size' to the normalized value. If 'size' is an
	// input 0, then the receiving buffer is guaranteed to be large enough for the result
	// and the size will be set to the size required for bigNum (leading zeros
	// suppressed).
	//
	// The conversion for a little-endian machine simply requires that all significant
	// bytes of the bigNum be reversed. For a big-endian machine, rather than
	// unpack each word individually, the bigNum is converted to little-endian words,
	// copied, and then converted back to big-endian.
	LIB_EXPORT BOOL
	BnToBytes(
	bigConst bn,
	BYTE *buffer,
	NUMBYTES *size // This the number of bytes that are
	// available in the buffer. The result
	// should be this big.
	)
	{
	crypt_uword_t requiredSize;
	BYTE *pFrom;
	BYTE *pTo;
	crypt_uword_t count;
	//
	// validate inputs
	pAssert(bn && buffer && size);

	requiredSize = (BnSizeInBits(bn) + 7) / 8;
	if(requiredSize == 0)
	{
	// If the input value is 0, return a byte of zero
	*size = 1;
	*buffer = 0;
	}
	else
	{
	#if BIG_ENDIAN_TPM
	// Copy the constant input value into a modifiable value
	BN_VAR(bnL, LARGEST_NUMBER_BITS * 2);
	BnCopy(bnL, bn);
	// byte swap the words in the local value to make them little-endian
	for(count = 0; count < bnL->size; count++)
	bnL->d[count] = SWAP_CRYPT_WORD(bnL->d[count]);
	bn = (bigConst)bnL;
	#endif
	if(*size == 0)
	*size = (NUMBYTES)requiredSize;
	pAssert(requiredSize <= *size);
	// Byte swap the number (not words but the whole value)
	count = *size;
	// Start from the least significant word and offset to the most significant
	// byte which is in some high word
	pFrom = (BYTE *)(&bn->d[0]) + requiredSize - 1;
	pTo = buffer;

	// If the number of output bytes is larger than the number bytes required
	// for the input number, pad with zeros
	for(count = *size; count > requiredSize; count--)
	*pTo++ = 0;
	// Move the most significant byte at the end of the BigNum to the next most
	// significant byte position of the 2B and repeat for all significant bytes.
	for(; requiredSize > 0; requiredSize--)
	pTo++ = pFrom--;
	}
	return TRUE;
	}

	//*** BnTo2B()
	// Function to convert a BIG_NUM to TPM2B.
	// The TPM2B size is set to the requested 'size' which may require padding.
	// If 'size' is non-zero and less than required by the value in 'bn' then an error
	// is returned. If 'size' is zero, then the TPM2B is assumed to be large enough
	// for the data and a2b->size will be adjusted accordingly.
	LIB_EXPORT BOOL
	BnTo2B(
	bigConst bn, // IN:
	TPM2B *a2B, // OUT:
	NUMBYTES size // IN: the desired size
	)
	{
	// Set the output size
	if(bn && a2B)
	{
	a2B->size = size;
	return BnToBytes(bn, a2B->buffer, &a2B->size);
	}
	return FALSE;
	}

	#if ALG_ECC

	//*** BnPointFrom2B()
	// Function to create a BIG_POINT structure from a 2B point.
	// A point is going to be two ECC values in the same buffer. The values are going
	// to be the size of the modulus. They are in modular form.
	LIB_EXPORT bn_point_t *
	BnPointFrom2B(
	bigPoint ecP, // OUT: the preallocated point structure
	TPMS_ECC_POINT *p // IN: the number to convert
	)
	{
	if(p == NULL)
	return NULL;

	if(NULL != ecP)
	{
	BnFrom2B(ecP->x, &p->x.b);
	BnFrom2B(ecP->y, &p->y.b);
	BnSetWord(ecP->z, 1);
	}
	return ecP;
	}

	//*** BnPointTo2B()
	// This function converts a BIG_POINT into a TPMS_ECC_POINT. A TPMS_ECC_POINT
	// contains two TPM2B_ECC_PARAMETER values. The maximum size of the parameters
	// is dependent on the maximum EC key size used in an implementation.
	// The presumption is that the TPMS_ECC_POINT is large enough to hold 2 TPM2B
	// values, each as large as a MAX_ECC_PARAMETER_BYTES
	LIB_EXPORT BOOL
	BnPointTo2B(
	TPMS_ECC_POINT *p, // OUT: the converted 2B structure
	bigPoint ecP, // IN: the values to be converted
	bigCurve E // IN: curve descriptor for the point
	)
	{
	UINT16 size;
	//
	pAssert(p && ecP && E);
	pAssert(BnEqualWord(ecP->z, 1));
	// BnMsb is the bit number of the MSB. This is one less than the number of bits
	size = (UINT16)BITS_TO_BYTES(BnSizeInBits(CurveGetOrder(AccessCurveData(E))));
	BnTo2B(ecP->x, &p->x.b, size);
	BnTo2B(ecP->y, &p->y.b, size);
	return TRUE;
	}

	#endif // ALG_ECC