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/*
// Intel(R) Integrated Performance Primitives. Cryptography Primitives.
// GF(p) methods
//
*/
#include "owndefs.h"
#include "owncp.h"
#include "pcpbnumisc.h"
#include "pcpgfpstuff.h"
#include "pcpgfpmethod.h"
#include "pcpecprime.h"
#if !defined(_PCP_GFPMETHOD_256_H_)
#define _PCP_GFPMETHOD_256_H_
#if(_IPP32E >= _IPP32E_M7)
/* arithmetic over arbitrary 256r-bit modulus */
#define gf256_add OWNAPI(gf256_add)
#define gf256_sub OWNAPI(gf256_sub)
#define gf256_neg OWNAPI(gf256_neg)
#define gf256_mulm OWNAPI(gf256_mulm)
#define gf256_sqrm OWNAPI(gf256_sqrm)
#define gf256_div2 OWNAPI(gf256_div2)
BNU_CHUNK_T* gf256_add(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pB, const BNU_CHUNK_T* pModulus);
BNU_CHUNK_T* gf256_sub(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pB, const BNU_CHUNK_T* pModulus);
BNU_CHUNK_T* gf256_neg(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pModulus);
BNU_CHUNK_T* gf256_mulm(BNU_CHUNK_T* pR,const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pB, const BNU_CHUNK_T* pModulus, BNU_CHUNK_T m0);
BNU_CHUNK_T* gf256_sqrm(BNU_CHUNK_T* pR,const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pModulus, BNU_CHUNK_T m0);
BNU_CHUNK_T* gf256_div2(BNU_CHUNK_T* pR,const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pModulus);
#define OPERAND_BITSIZE (256)
#define LEN_P256 (BITS_BNU_CHUNK(OPERAND_BITSIZE))
static BNU_CHUNK_T* p256_add(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pB, gsEngine* pGFE)
{
return gf256_add(pR, pA, pB, GFP_MODULUS(pGFE));
}
static BNU_CHUNK_T* p256_sub(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pB, gsEngine* pGFE)
{
return gf256_sub(pR, pA, pB, GFP_MODULUS(pGFE));
}
static BNU_CHUNK_T* p256_neg(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, gsEngine* pGFE)
{
return gf256_neg(pR, pA, GFP_MODULUS(pGFE));
}
static BNU_CHUNK_T* p256_div_by_2(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, gsEngine* pGFE)
{
return gf256_div2(pR, pA, GFP_MODULUS(pGFE));
}
static BNU_CHUNK_T* p256_mul_by_2(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, gsEngine* pGFE)
{
return gf256_add(pR, pA, pA, GFP_MODULUS(pGFE));
}
static BNU_CHUNK_T* p256_mul_by_3(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, gsEngine* pGFE)
{
BNU_CHUNK_T tmp[LEN_P256];
gf256_add(tmp, pA, pA, GFP_MODULUS(pGFE));
return gf256_add(pR, tmp, pA, GFP_MODULUS(pGFE));
}
static BNU_CHUNK_T* p256_mul_montl(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, const BNU_CHUNK_T* pB, gsEngine* pGFE)
{
return gf256_mulm(pR, pA, pB, GFP_MODULUS(pGFE), GFP_MNT_FACTOR(pGFE));
}
static BNU_CHUNK_T* p256_sqr_montl(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, gsEngine* pGFE)
{
return gf256_sqrm(pR, pA, GFP_MODULUS(pGFE), GFP_MNT_FACTOR(pGFE));
}
static BNU_CHUNK_T* p256_to_mont(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, gsEngine* pGFE)
{
return gf256_mulm(pR, pA, GFP_MNT_RR(pGFE), GFP_MODULUS(pGFE), GFP_MNT_FACTOR(pGFE));
}
static BNU_CHUNK_T one[] = {1,0,0,0};
static BNU_CHUNK_T* p256_mont_back(BNU_CHUNK_T* pR, const BNU_CHUNK_T* pA, gsEngine* pGFE)
{
return gf256_mulm(pR, pA, one, GFP_MODULUS(pGFE), GFP_MNT_FACTOR(pGFE));
}
/* return specific gf p256 arith methods */
static gsModMethod* gsArithGF_p256(void)
{
static gsModMethod m = {
p256_to_mont,
p256_mont_back,
p256_mul_montl,
p256_sqr_montl,
NULL,
p256_add,
p256_sub,
p256_neg,
p256_div_by_2,
p256_mul_by_2,
p256_mul_by_3,
};
return &m;
}
#endif /* _IPP32E >= _IPP32E_M7 */
#undef LEN_P256
#undef OPERAND_BITSIZE
#endif /* #if !defined(_PCP_GFPMETHOD_256_H_) */