stack/smp/p_256_ecc_pp.cc - platform/system/bt - Git at Google

 /******************************************************************************
  *
  *  Copyright (C) 2006-2015 Broadcom Corporation
  *
  *  Licensed under the Apache License, Version 2.0 (the "License");
  *  you may not use this file except in compliance with the License.
  *  You may obtain a copy of the License at:
  *
  *  http://www.apache.org/licenses/LICENSE-2.0
  *
  *  Unless required by applicable law or agreed to in writing, software
  *  distributed under the License is distributed on an "AS IS" BASIS,
  *  WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  *  See the License for the specific language governing permissions and
  *  limitations under the License.
  *
  ******************************************************************************/

 /*******************************************************************************
  *
  *  This file contains simple pairing algorithms using Elliptic Curve
  *  Cryptography for private public key
  *
  ******************************************************************************/
 #include "p_256_ecc_pp.h"
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include "p_256_multprecision.h"

 elliptic_curve_t curve;
 elliptic_curve_t curve_p256;

 static void p_256_init_point(Point* q) { memset(q, 0, sizeof(Point)); }

 static void p_256_copy_point(Point* q, Point* p) {
   memcpy(q, p, sizeof(Point));
 }

 // q=2q
 static void ECC_Double(Point* q, Point* p, uint32_t keyLength) {
   uint32_t t1[KEY_LENGTH_DWORDS_P256];
   uint32_t t2[KEY_LENGTH_DWORDS_P256];
   uint32_t t3[KEY_LENGTH_DWORDS_P256];
   uint32_t* x1;
   uint32_t* x3;
   uint32_t* y1;
   uint32_t* y3;
   uint32_t* z1;
   uint32_t* z3;

   if (multiprecision_iszero(p->z, keyLength)) {
     multiprecision_init(q->z, keyLength);
     return;  // return infinity
   }

   x1 = p->x;
   y1 = p->y;
   z1 = p->z;
   x3 = q->x;
   y3 = q->y;
   z3 = q->z;

   multiprecision_mersenns_squa_mod(t1, z1, keyLength);      // t1=z1^2
   multiprecision_sub_mod(t2, x1, t1, keyLength);            // t2=x1-t1
   multiprecision_add_mod(t1, x1, t1, keyLength);            // t1=x1+t1
   multiprecision_mersenns_mult_mod(t2, t1, t2, keyLength);  // t2=t2*t1
   multiprecision_lshift_mod(t3, t2, keyLength);
   multiprecision_add_mod(t2, t3, t2, keyLength);  // t2=3t2

   multiprecision_mersenns_mult_mod(z3, y1, z1, keyLength);  // z3=y1*z1
   multiprecision_lshift_mod(z3, z3, keyLength);

   multiprecision_mersenns_squa_mod(y3, y1, keyLength);  // y3=y1^2
   multiprecision_lshift_mod(y3, y3, keyLength);
   multiprecision_mersenns_mult_mod(t3, y3, x1, keyLength);  // t3=y3*x1=x1*y1^2
   multiprecision_lshift_mod(t3, t3, keyLength);
   multiprecision_mersenns_squa_mod(y3, y3, keyLength);  // y3=y3^2=y1^4
   multiprecision_lshift_mod(y3, y3, keyLength);

   multiprecision_mersenns_squa_mod(x3, t2, keyLength);      // x3=t2^2
   multiprecision_lshift_mod(t1, t3, keyLength);             // t1=2t3
   multiprecision_sub_mod(x3, x3, t1, keyLength);            // x3=x3-t1
   multiprecision_sub_mod(t1, t3, x3, keyLength);            // t1=t3-x3
   multiprecision_mersenns_mult_mod(t1, t1, t2, keyLength);  // t1=t1*t2
   multiprecision_sub_mod(y3, t1, y3, keyLength);            // y3=t1-y3
 }

 // q=q+p,     zp must be 1
 static void ECC_Add(Point* r, Point* p, Point* q, uint32_t keyLength) {
   uint32_t t1[KEY_LENGTH_DWORDS_P256];
   uint32_t t2[KEY_LENGTH_DWORDS_P256];
   uint32_t* x1;
   uint32_t* x2;
   uint32_t* x3;
   uint32_t* y1;
   uint32_t* y2;
   uint32_t* y3;
   uint32_t* z1;
   uint32_t* z2;
   uint32_t* z3;

   x1 = p->x;
   y1 = p->y;
   z1 = p->z;
   x2 = q->x;
   y2 = q->y;
   z2 = q->z;
   x3 = r->x;
   y3 = r->y;
   z3 = r->z;

   // if Q=infinity, return p
   if (multiprecision_iszero(z2, keyLength)) {
     p_256_copy_point(r, p);
     return;
   }

   // if P=infinity, return q
   if (multiprecision_iszero(z1, keyLength)) {
     p_256_copy_point(r, q);
     return;
   }

   multiprecision_mersenns_squa_mod(t1, z1, keyLength);      // t1=z1^2
   multiprecision_mersenns_mult_mod(t2, z1, t1, keyLength);  // t2=t1*z1
   multiprecision_mersenns_mult_mod(t1, x2, t1, keyLength);  // t1=t1*x2
   multiprecision_mersenns_mult_mod(t2, y2, t2, keyLength);  // t2=t2*y2

   multiprecision_sub_mod(t1, t1, x1, keyLength);  // t1=t1-x1
   multiprecision_sub_mod(t2, t2, y1, keyLength);  // t2=t2-y1

   if (multiprecision_iszero(t1, keyLength)) {
     if (multiprecision_iszero(t2, keyLength)) {
       ECC_Double(r, q, keyLength);
       return;
     } else {
       multiprecision_init(z3, keyLength);
       return;  // return infinity
     }
   }

   multiprecision_mersenns_mult_mod(z3, z1, t1, keyLength);  // z3=z1*t1
   multiprecision_mersenns_squa_mod(y3, t1, keyLength);      // t3=t1^2
   multiprecision_mersenns_mult_mod(z1, y3, t1, keyLength);  // t4=t3*t1
   multiprecision_mersenns_mult_mod(y3, y3, x1, keyLength);  // t3=t3*x1
   multiprecision_lshift_mod(t1, y3, keyLength);             // t1=2*t3
   multiprecision_mersenns_squa_mod(x3, t2, keyLength);      // x3=t2^2
   multiprecision_sub_mod(x3, x3, t1, keyLength);            // x3=x3-t1
   multiprecision_sub_mod(x3, x3, z1, keyLength);            // x3=x3-t4
   multiprecision_sub_mod(y3, y3, x3, keyLength);            // t3=t3-x3
   multiprecision_mersenns_mult_mod(y3, y3, t2, keyLength);  // t3=t3*t2
   multiprecision_mersenns_mult_mod(z1, z1, y1, keyLength);  // t4=t4*t1
   multiprecision_sub_mod(y3, y3, z1, keyLength);
 }

 // Computing the Non-Adjacent Form of a positive integer
 static void ECC_NAF(uint8_t* naf, uint32_t* NumNAF, uint32_t* k,
                     uint32_t keyLength) {
   uint32_t sign;
   int i = 0;
   int j;
   uint32_t var;

   while ((var = multiprecision_most_signbits(k, keyLength)) >= 1) {
     if (k[0] & 0x01)  // k is odd
     {
       sign = (k[0] & 0x03);  // 1 or 3

       // k = k-naf[i]
       if (sign == 1)
         k[0] = k[0] & 0xFFFFFFFE;
       else {
         k[0] = k[0] + 1;
         if (k[0] == 0)  // overflow
         {
           j = 1;
           do {
             k[j]++;
           } while (k[j++] == 0);  // overflow
         }
       }
     } else
       sign = 0;

     multiprecision_rshift(k, k, keyLength);
     naf[i / 4] |= (sign) << ((i % 4) * 2);
     i++;
   }

   *NumNAF = i;
 }

 // Binary Non-Adjacent Form for point multiplication
 void ECC_PointMult_Bin_NAF(Point* q, Point* p, uint32_t* n,
                            uint32_t keyLength) {
   uint32_t sign;
   uint8_t naf[256 / 4 + 1];
   uint32_t NumNaf;
   Point minus_p;
   Point r;
   uint32_t* modp;

   if (keyLength == KEY_LENGTH_DWORDS_P256) {
     modp = curve_p256.p;
   } else {
     modp = curve.p;
   }

   p_256_init_point(&r);
   multiprecision_init(p->z, keyLength);
   p->z[0] = 1;

   // initialization
   p_256_init_point(q);

   // -p
   multiprecision_copy(minus_p.x, p->x, keyLength);
   multiprecision_sub(minus_p.y, modp, p->y, keyLength);

   multiprecision_init(minus_p.z, keyLength);
   minus_p.z[0] = 1;

   // NAF
   memset(naf, 0, sizeof(naf));
   ECC_NAF(naf, &NumNaf, n, keyLength);

   for (int i = NumNaf - 1; i >= 0; i--) {
     p_256_copy_point(&r, q);
     ECC_Double(q, &r, keyLength);
     sign = (naf[i / 4] >> ((i % 4) * 2)) & 0x03;

     if (sign == 1) {
       p_256_copy_point(&r, q);
       ECC_Add(q, &r, p, keyLength);
     } else if (sign == 3) {
       p_256_copy_point(&r, q);
       ECC_Add(q, &r, &minus_p, keyLength);
     }
   }

   multiprecision_inv_mod(minus_p.x, q->z, keyLength);
   multiprecision_mersenns_squa_mod(q->z, minus_p.x, keyLength);
   multiprecision_mersenns_mult_mod(q->x, q->x, q->z, keyLength);
   multiprecision_mersenns_mult_mod(q->z, q->z, minus_p.x, keyLength);
   multiprecision_mersenns_mult_mod(q->y, q->y, q->z, keyLength);
 }
	/******************************************************************************
	*
	* Copyright (C) 2006-2015 Broadcom Corporation
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at:
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	******************************************************************************/

	/*******************************************************************************
	*
	* This file contains simple pairing algorithms using Elliptic Curve
	* Cryptography for private public key
	*
	******************************************************************************/
	#include "p_256_ecc_pp.h"
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#include "p_256_multprecision.h"

	elliptic_curve_t curve;
	elliptic_curve_t curve_p256;

	static void p_256_init_point(Point* q) { memset(q, 0, sizeof(Point)); }

	static void p_256_copy_point(Point* q, Point* p) {
	memcpy(q, p, sizeof(Point));
	}

	// q=2q
	static void ECC_Double(Point* q, Point* p, uint32_t keyLength) {
	uint32_t t1[KEY_LENGTH_DWORDS_P256];
	uint32_t t2[KEY_LENGTH_DWORDS_P256];
	uint32_t t3[KEY_LENGTH_DWORDS_P256];
	uint32_t* x1;
	uint32_t* x3;
	uint32_t* y1;
	uint32_t* y3;
	uint32_t* z1;
	uint32_t* z3;

	if (multiprecision_iszero(p->z, keyLength)) {
	multiprecision_init(q->z, keyLength);
	return; // return infinity
	}

	x1 = p->x;
	y1 = p->y;
	z1 = p->z;
	x3 = q->x;
	y3 = q->y;
	z3 = q->z;

	multiprecision_mersenns_squa_mod(t1, z1, keyLength); // t1=z1^2
	multiprecision_sub_mod(t2, x1, t1, keyLength); // t2=x1-t1
	multiprecision_add_mod(t1, x1, t1, keyLength); // t1=x1+t1
	multiprecision_mersenns_mult_mod(t2, t1, t2, keyLength); // t2=t2*t1
	multiprecision_lshift_mod(t3, t2, keyLength);
	multiprecision_add_mod(t2, t3, t2, keyLength); // t2=3t2

	multiprecision_mersenns_mult_mod(z3, y1, z1, keyLength); // z3=y1*z1
	multiprecision_lshift_mod(z3, z3, keyLength);

	multiprecision_mersenns_squa_mod(y3, y1, keyLength); // y3=y1^2
	multiprecision_lshift_mod(y3, y3, keyLength);
	multiprecision_mersenns_mult_mod(t3, y3, x1, keyLength); // t3=y3x1=x1y1^2
	multiprecision_lshift_mod(t3, t3, keyLength);
	multiprecision_mersenns_squa_mod(y3, y3, keyLength); // y3=y3^2=y1^4
	multiprecision_lshift_mod(y3, y3, keyLength);

	multiprecision_mersenns_squa_mod(x3, t2, keyLength); // x3=t2^2
	multiprecision_lshift_mod(t1, t3, keyLength); // t1=2t3
	multiprecision_sub_mod(x3, x3, t1, keyLength); // x3=x3-t1
	multiprecision_sub_mod(t1, t3, x3, keyLength); // t1=t3-x3
	multiprecision_mersenns_mult_mod(t1, t1, t2, keyLength); // t1=t1*t2
	multiprecision_sub_mod(y3, t1, y3, keyLength); // y3=t1-y3
	}

	// q=q+p, zp must be 1
	static void ECC_Add(Point* r, Point* p, Point* q, uint32_t keyLength) {
	uint32_t t1[KEY_LENGTH_DWORDS_P256];
	uint32_t t2[KEY_LENGTH_DWORDS_P256];
	uint32_t* x1;
	uint32_t* x2;
	uint32_t* x3;
	uint32_t* y1;
	uint32_t* y2;
	uint32_t* y3;
	uint32_t* z1;
	uint32_t* z2;
	uint32_t* z3;

	x1 = p->x;
	y1 = p->y;
	z1 = p->z;
	x2 = q->x;
	y2 = q->y;
	z2 = q->z;
	x3 = r->x;
	y3 = r->y;
	z3 = r->z;

	// if Q=infinity, return p
	if (multiprecision_iszero(z2, keyLength)) {
	p_256_copy_point(r, p);
	return;
	}

	// if P=infinity, return q
	if (multiprecision_iszero(z1, keyLength)) {
	p_256_copy_point(r, q);
	return;
	}

	multiprecision_mersenns_squa_mod(t1, z1, keyLength); // t1=z1^2
	multiprecision_mersenns_mult_mod(t2, z1, t1, keyLength); // t2=t1*z1
	multiprecision_mersenns_mult_mod(t1, x2, t1, keyLength); // t1=t1*x2
	multiprecision_mersenns_mult_mod(t2, y2, t2, keyLength); // t2=t2*y2

	multiprecision_sub_mod(t1, t1, x1, keyLength); // t1=t1-x1
	multiprecision_sub_mod(t2, t2, y1, keyLength); // t2=t2-y1

	if (multiprecision_iszero(t1, keyLength)) {
	if (multiprecision_iszero(t2, keyLength)) {
	ECC_Double(r, q, keyLength);
	return;
	} else {
	multiprecision_init(z3, keyLength);
	return; // return infinity
	}
	}

	multiprecision_mersenns_mult_mod(z3, z1, t1, keyLength); // z3=z1*t1
	multiprecision_mersenns_squa_mod(y3, t1, keyLength); // t3=t1^2
	multiprecision_mersenns_mult_mod(z1, y3, t1, keyLength); // t4=t3*t1
	multiprecision_mersenns_mult_mod(y3, y3, x1, keyLength); // t3=t3*x1
	multiprecision_lshift_mod(t1, y3, keyLength); // t1=2*t3
	multiprecision_mersenns_squa_mod(x3, t2, keyLength); // x3=t2^2
	multiprecision_sub_mod(x3, x3, t1, keyLength); // x3=x3-t1
	multiprecision_sub_mod(x3, x3, z1, keyLength); // x3=x3-t4
	multiprecision_sub_mod(y3, y3, x3, keyLength); // t3=t3-x3
	multiprecision_mersenns_mult_mod(y3, y3, t2, keyLength); // t3=t3*t2
	multiprecision_mersenns_mult_mod(z1, z1, y1, keyLength); // t4=t4*t1
	multiprecision_sub_mod(y3, y3, z1, keyLength);
	}

	// Computing the Non-Adjacent Form of a positive integer
	static void ECC_NAF(uint8_t* naf, uint32_t* NumNAF, uint32_t* k,
	uint32_t keyLength) {
	uint32_t sign;
	int i = 0;
	int j;
	uint32_t var;

	while ((var = multiprecision_most_signbits(k, keyLength)) >= 1) {
	if (k[0] & 0x01) // k is odd
	{
	sign = (k[0] & 0x03); // 1 or 3

	// k = k-naf[i]
	if (sign == 1)
	k[0] = k[0] & 0xFFFFFFFE;
	else {
	k[0] = k[0] + 1;
	if (k[0] == 0) // overflow
	{
	j = 1;
	do {
	k[j]++;
	} while (k[j++] == 0); // overflow
	}
	}
	} else
	sign = 0;

	multiprecision_rshift(k, k, keyLength);
	naf[i / 4] \|= (sign) << ((i % 4) * 2);
	i++;
	}

	*NumNAF = i;
	}

	// Binary Non-Adjacent Form for point multiplication
	void ECC_PointMult_Bin_NAF(Point* q, Point* p, uint32_t* n,
	uint32_t keyLength) {
	uint32_t sign;
	uint8_t naf[256 / 4 + 1];
	uint32_t NumNaf;
	Point minus_p;
	Point r;
	uint32_t* modp;

	if (keyLength == KEY_LENGTH_DWORDS_P256) {
	modp = curve_p256.p;
	} else {
	modp = curve.p;
	}

	p_256_init_point(&r);
	multiprecision_init(p->z, keyLength);
	p->z[0] = 1;

	// initialization
	p_256_init_point(q);

	// -p
	multiprecision_copy(minus_p.x, p->x, keyLength);
	multiprecision_sub(minus_p.y, modp, p->y, keyLength);

	multiprecision_init(minus_p.z, keyLength);
	minus_p.z[0] = 1;

	// NAF
	memset(naf, 0, sizeof(naf));
	ECC_NAF(naf, &NumNaf, n, keyLength);

	for (int i = NumNaf - 1; i >= 0; i--) {
	p_256_copy_point(&r, q);
	ECC_Double(q, &r, keyLength);
	sign = (naf[i / 4] >> ((i % 4) * 2)) & 0x03;

	if (sign == 1) {
	p_256_copy_point(&r, q);
	ECC_Add(q, &r, p, keyLength);
	} else if (sign == 3) {
	p_256_copy_point(&r, q);
	ECC_Add(q, &r, &minus_p, keyLength);
	}
	}

	multiprecision_inv_mod(minus_p.x, q->z, keyLength);
	multiprecision_mersenns_squa_mod(q->z, minus_p.x, keyLength);
	multiprecision_mersenns_mult_mod(q->x, q->x, q->z, keyLength);
	multiprecision_mersenns_mult_mod(q->z, q->z, minus_p.x, keyLength);
	multiprecision_mersenns_mult_mod(q->y, q->y, q->z, keyLength);
	}