mirror of
https://github.com/klzgrad/naiveproxy.git
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748 lines
22 KiB
C++
748 lines
22 KiB
C++
// Copyright (c) 2012 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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// This is an implementation of the P224 elliptic curve group. It's written to
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// be short and simple rather than fast, although it's still constant-time.
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//
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// See http://www.imperialviolet.org/2010/12/04/ecc.html ([1]) for background.
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#include "crypto/p224.h"
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#include <stddef.h>
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#include <stdint.h>
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#include <string.h>
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#include "base/sys_byteorder.h"
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namespace {
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using base::HostToNet32;
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using base::NetToHost32;
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// Field element functions.
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//
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// The field that we're dealing with is ℤ/pℤ where p = 2**224 - 2**96 + 1.
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//
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// Field elements are represented by a FieldElement, which is a typedef to an
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// array of 8 uint32_t's. The value of a FieldElement, a, is:
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// a[0] + 2**28·a[1] + 2**56·a[1] + ... + 2**196·a[7]
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//
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// Using 28-bit limbs means that there's only 4 bits of headroom, which is less
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// than we would really like. But it has the useful feature that we hit 2**224
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// exactly, making the reflections during a reduce much nicer.
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using crypto::p224::FieldElement;
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// kP is the P224 prime.
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const FieldElement kP = {
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1, 0, 0, 268431360,
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268435455, 268435455, 268435455, 268435455,
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};
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void Contract(FieldElement* inout);
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// IsZero returns 0xffffffff if a == 0 mod p and 0 otherwise.
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uint32_t IsZero(const FieldElement& a) {
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FieldElement minimal;
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memcpy(&minimal, &a, sizeof(minimal));
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Contract(&minimal);
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uint32_t is_zero = 0, is_p = 0;
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for (unsigned i = 0; i < 8; i++) {
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is_zero |= minimal[i];
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is_p |= minimal[i] - kP[i];
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}
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// If either is_zero or is_p is 0, then we should return 1.
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is_zero |= is_zero >> 16;
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is_zero |= is_zero >> 8;
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is_zero |= is_zero >> 4;
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is_zero |= is_zero >> 2;
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is_zero |= is_zero >> 1;
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is_p |= is_p >> 16;
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is_p |= is_p >> 8;
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is_p |= is_p >> 4;
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is_p |= is_p >> 2;
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is_p |= is_p >> 1;
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// For is_zero and is_p, the LSB is 0 iff all the bits are zero.
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is_zero &= is_p & 1;
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is_zero = (~is_zero) << 31;
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is_zero = static_cast<int32_t>(is_zero) >> 31;
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return is_zero;
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}
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// Add computes *out = a+b
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//
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// a[i] + b[i] < 2**32
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void Add(FieldElement* out, const FieldElement& a, const FieldElement& b) {
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for (int i = 0; i < 8; i++) {
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(*out)[i] = a[i] + b[i];
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}
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}
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static const uint32_t kTwo31p3 = (1u << 31) + (1u << 3);
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static const uint32_t kTwo31m3 = (1u << 31) - (1u << 3);
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static const uint32_t kTwo31m15m3 = (1u << 31) - (1u << 15) - (1u << 3);
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// kZero31ModP is 0 mod p where bit 31 is set in all limbs so that we can
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// subtract smaller amounts without underflow. See the section "Subtraction" in
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// [1] for why.
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static const FieldElement kZero31ModP = {
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kTwo31p3, kTwo31m3, kTwo31m3, kTwo31m15m3,
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kTwo31m3, kTwo31m3, kTwo31m3, kTwo31m3
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};
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// Subtract computes *out = a-b
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//
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// a[i], b[i] < 2**30
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// out[i] < 2**32
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void Subtract(FieldElement* out, const FieldElement& a, const FieldElement& b) {
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for (int i = 0; i < 8; i++) {
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// See the section on "Subtraction" in [1] for details.
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(*out)[i] = a[i] + kZero31ModP[i] - b[i];
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}
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}
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static const uint64_t kTwo63p35 = (1ull << 63) + (1ull << 35);
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static const uint64_t kTwo63m35 = (1ull << 63) - (1ull << 35);
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static const uint64_t kTwo63m35m19 = (1ull << 63) - (1ull << 35) - (1ull << 19);
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// kZero63ModP is 0 mod p where bit 63 is set in all limbs. See the section
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// "Subtraction" in [1] for why.
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static const uint64_t kZero63ModP[8] = {
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kTwo63p35, kTwo63m35, kTwo63m35, kTwo63m35,
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kTwo63m35m19, kTwo63m35, kTwo63m35, kTwo63m35,
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};
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static const uint32_t kBottom28Bits = 0xfffffff;
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// LargeFieldElement also represents an element of the field. The limbs are
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// still spaced 28-bits apart and in little-endian order. So the limbs are at
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// 0, 28, 56, ..., 392 bits, each 64-bits wide.
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typedef uint64_t LargeFieldElement[15];
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// ReduceLarge converts a LargeFieldElement to a FieldElement.
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//
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// in[i] < 2**62
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void ReduceLarge(FieldElement* out, LargeFieldElement* inptr) {
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LargeFieldElement& in(*inptr);
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for (int i = 0; i < 8; i++) {
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in[i] += kZero63ModP[i];
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}
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// Eliminate the coefficients at 2**224 and greater while maintaining the
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// same value mod p.
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for (int i = 14; i >= 8; i--) {
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in[i-8] -= in[i]; // reflection off the "+1" term of p.
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in[i-5] += (in[i] & 0xffff) << 12; // part of the "-2**96" reflection.
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in[i-4] += in[i] >> 16; // the rest of the "-2**96" reflection.
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}
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in[8] = 0;
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// in[0..8] < 2**64
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// As the values become small enough, we start to store them in |out| and use
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// 32-bit operations.
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for (int i = 1; i < 8; i++) {
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in[i+1] += in[i] >> 28;
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(*out)[i] = static_cast<uint32_t>(in[i] & kBottom28Bits);
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}
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// Eliminate the term at 2*224 that we introduced while keeping the same
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// value mod p.
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in[0] -= in[8]; // reflection off the "+1" term of p.
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(*out)[3] += static_cast<uint32_t>(in[8] & 0xffff) << 12; // "-2**96" term
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(*out)[4] += static_cast<uint32_t>(in[8] >> 16); // rest of "-2**96" term
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// in[0] < 2**64
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// out[3] < 2**29
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// out[4] < 2**29
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// out[1,2,5..7] < 2**28
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(*out)[0] = static_cast<uint32_t>(in[0] & kBottom28Bits);
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(*out)[1] += static_cast<uint32_t>((in[0] >> 28) & kBottom28Bits);
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(*out)[2] += static_cast<uint32_t>(in[0] >> 56);
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// out[0] < 2**28
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// out[1..4] < 2**29
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// out[5..7] < 2**28
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}
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// Mul computes *out = a*b
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//
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// a[i] < 2**29, b[i] < 2**30 (or vice versa)
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// out[i] < 2**29
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void Mul(FieldElement* out, const FieldElement& a, const FieldElement& b) {
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LargeFieldElement tmp;
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memset(&tmp, 0, sizeof(tmp));
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for (int i = 0; i < 8; i++) {
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for (int j = 0; j < 8; j++) {
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tmp[i + j] += static_cast<uint64_t>(a[i]) * static_cast<uint64_t>(b[j]);
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}
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}
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ReduceLarge(out, &tmp);
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}
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// Square computes *out = a*a
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//
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// a[i] < 2**29
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// out[i] < 2**29
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void Square(FieldElement* out, const FieldElement& a) {
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LargeFieldElement tmp;
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memset(&tmp, 0, sizeof(tmp));
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for (int i = 0; i < 8; i++) {
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for (int j = 0; j <= i; j++) {
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uint64_t r = static_cast<uint64_t>(a[i]) * static_cast<uint64_t>(a[j]);
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if (i == j) {
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tmp[i+j] += r;
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} else {
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tmp[i+j] += r << 1;
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}
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}
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}
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ReduceLarge(out, &tmp);
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}
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// Reduce reduces the coefficients of in_out to smaller bounds.
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//
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// On entry: a[i] < 2**31 + 2**30
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// On exit: a[i] < 2**29
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void Reduce(FieldElement* in_out) {
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FieldElement& a = *in_out;
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for (int i = 0; i < 7; i++) {
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a[i+1] += a[i] >> 28;
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a[i] &= kBottom28Bits;
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}
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uint32_t top = a[7] >> 28;
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a[7] &= kBottom28Bits;
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// top < 2**4
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// Constant-time: mask = (top != 0) ? 0xffffffff : 0
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uint32_t mask = top;
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mask |= mask >> 2;
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mask |= mask >> 1;
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mask <<= 31;
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mask = static_cast<uint32_t>(static_cast<int32_t>(mask) >> 31);
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// Eliminate top while maintaining the same value mod p.
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a[0] -= top;
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a[3] += top << 12;
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// We may have just made a[0] negative but, if we did, then we must
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// have added something to a[3], thus it's > 2**12. Therefore we can
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// carry down to a[0].
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a[3] -= 1 & mask;
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a[2] += mask & ((1<<28) - 1);
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a[1] += mask & ((1<<28) - 1);
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a[0] += mask & (1<<28);
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}
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// Invert calcuates *out = in**-1 by computing in**(2**224 - 2**96 - 1), i.e.
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// Fermat's little theorem.
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void Invert(FieldElement* out, const FieldElement& in) {
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FieldElement f1, f2, f3, f4;
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Square(&f1, in); // 2
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Mul(&f1, f1, in); // 2**2 - 1
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Square(&f1, f1); // 2**3 - 2
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Mul(&f1, f1, in); // 2**3 - 1
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Square(&f2, f1); // 2**4 - 2
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Square(&f2, f2); // 2**5 - 4
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Square(&f2, f2); // 2**6 - 8
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Mul(&f1, f1, f2); // 2**6 - 1
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Square(&f2, f1); // 2**7 - 2
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for (int i = 0; i < 5; i++) { // 2**12 - 2**6
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Square(&f2, f2);
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}
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Mul(&f2, f2, f1); // 2**12 - 1
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Square(&f3, f2); // 2**13 - 2
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for (int i = 0; i < 11; i++) { // 2**24 - 2**12
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Square(&f3, f3);
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}
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Mul(&f2, f3, f2); // 2**24 - 1
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Square(&f3, f2); // 2**25 - 2
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for (int i = 0; i < 23; i++) { // 2**48 - 2**24
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Square(&f3, f3);
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}
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Mul(&f3, f3, f2); // 2**48 - 1
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Square(&f4, f3); // 2**49 - 2
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for (int i = 0; i < 47; i++) { // 2**96 - 2**48
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Square(&f4, f4);
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}
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Mul(&f3, f3, f4); // 2**96 - 1
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Square(&f4, f3); // 2**97 - 2
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for (int i = 0; i < 23; i++) { // 2**120 - 2**24
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Square(&f4, f4);
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}
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Mul(&f2, f4, f2); // 2**120 - 1
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for (int i = 0; i < 6; i++) { // 2**126 - 2**6
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Square(&f2, f2);
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}
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Mul(&f1, f1, f2); // 2**126 - 1
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Square(&f1, f1); // 2**127 - 2
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Mul(&f1, f1, in); // 2**127 - 1
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for (int i = 0; i < 97; i++) { // 2**224 - 2**97
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Square(&f1, f1);
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}
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Mul(out, f1, f3); // 2**224 - 2**96 - 1
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}
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// Contract converts a FieldElement to its minimal, distinguished form.
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//
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// On entry, in[i] < 2**29
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// On exit, in[i] < 2**28
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void Contract(FieldElement* inout) {
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FieldElement& out = *inout;
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// Reduce the coefficients to < 2**28.
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for (int i = 0; i < 7; i++) {
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out[i+1] += out[i] >> 28;
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out[i] &= kBottom28Bits;
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}
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uint32_t top = out[7] >> 28;
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out[7] &= kBottom28Bits;
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// Eliminate top while maintaining the same value mod p.
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out[0] -= top;
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out[3] += top << 12;
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// We may just have made out[0] negative. So we carry down. If we made
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// out[0] negative then we know that out[3] is sufficiently positive
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// because we just added to it.
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for (int i = 0; i < 3; i++) {
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uint32_t mask = static_cast<uint32_t>(static_cast<int32_t>(out[i]) >> 31);
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out[i] += (1 << 28) & mask;
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out[i+1] -= 1 & mask;
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}
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// We might have pushed out[3] over 2**28 so we perform another, partial
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// carry chain.
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for (int i = 3; i < 7; i++) {
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out[i+1] += out[i] >> 28;
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out[i] &= kBottom28Bits;
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}
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top = out[7] >> 28;
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out[7] &= kBottom28Bits;
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// Eliminate top while maintaining the same value mod p.
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out[0] -= top;
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out[3] += top << 12;
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// There are two cases to consider for out[3]:
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// 1) The first time that we eliminated top, we didn't push out[3] over
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// 2**28. In this case, the partial carry chain didn't change any values
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// and top is zero.
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// 2) We did push out[3] over 2**28 the first time that we eliminated top.
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// The first value of top was in [0..16), therefore, prior to eliminating
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// the first top, 0xfff1000 <= out[3] <= 0xfffffff. Therefore, after
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// overflowing and being reduced by the second carry chain, out[3] <=
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// 0xf000. Thus it cannot have overflowed when we eliminated top for the
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// second time.
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// Again, we may just have made out[0] negative, so do the same carry down.
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// As before, if we made out[0] negative then we know that out[3] is
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// sufficiently positive.
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for (int i = 0; i < 3; i++) {
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uint32_t mask = static_cast<uint32_t>(static_cast<int32_t>(out[i]) >> 31);
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out[i] += (1 << 28) & mask;
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out[i+1] -= 1 & mask;
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}
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// The value is < 2**224, but maybe greater than p. In order to reduce to a
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// unique, minimal value we see if the value is >= p and, if so, subtract p.
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// First we build a mask from the top four limbs, which must all be
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// equal to bottom28Bits if the whole value is >= p. If top_4_all_ones
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// ends up with any zero bits in the bottom 28 bits, then this wasn't
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// true.
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uint32_t top_4_all_ones = 0xffffffffu;
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for (int i = 4; i < 8; i++) {
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top_4_all_ones &= out[i];
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}
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top_4_all_ones |= 0xf0000000;
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// Now we replicate any zero bits to all the bits in top_4_all_ones.
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top_4_all_ones &= top_4_all_ones >> 16;
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top_4_all_ones &= top_4_all_ones >> 8;
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top_4_all_ones &= top_4_all_ones >> 4;
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top_4_all_ones &= top_4_all_ones >> 2;
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top_4_all_ones &= top_4_all_ones >> 1;
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top_4_all_ones =
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static_cast<uint32_t>(static_cast<int32_t>(top_4_all_ones << 31) >> 31);
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// Now we test whether the bottom three limbs are non-zero.
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uint32_t bottom_3_non_zero = out[0] | out[1] | out[2];
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bottom_3_non_zero |= bottom_3_non_zero >> 16;
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bottom_3_non_zero |= bottom_3_non_zero >> 8;
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bottom_3_non_zero |= bottom_3_non_zero >> 4;
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bottom_3_non_zero |= bottom_3_non_zero >> 2;
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bottom_3_non_zero |= bottom_3_non_zero >> 1;
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bottom_3_non_zero =
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static_cast<uint32_t>(static_cast<int32_t>(bottom_3_non_zero) >> 31);
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// Everything depends on the value of out[3].
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// If it's > 0xffff000 and top_4_all_ones != 0 then the whole value is >= p
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// If it's = 0xffff000 and top_4_all_ones != 0 and bottom_3_non_zero != 0,
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// then the whole value is >= p
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// If it's < 0xffff000, then the whole value is < p
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uint32_t n = out[3] - 0xffff000;
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uint32_t out_3_equal = n;
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out_3_equal |= out_3_equal >> 16;
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out_3_equal |= out_3_equal >> 8;
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out_3_equal |= out_3_equal >> 4;
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out_3_equal |= out_3_equal >> 2;
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out_3_equal |= out_3_equal >> 1;
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out_3_equal =
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~static_cast<uint32_t>(static_cast<int32_t>(out_3_equal << 31) >> 31);
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// If out[3] > 0xffff000 then n's MSB will be zero.
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uint32_t out_3_gt =
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~static_cast<uint32_t>(static_cast<int32_t>(n << 31) >> 31);
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uint32_t mask =
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top_4_all_ones & ((out_3_equal & bottom_3_non_zero) | out_3_gt);
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out[0] -= 1 & mask;
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out[3] -= 0xffff000 & mask;
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out[4] -= 0xfffffff & mask;
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out[5] -= 0xfffffff & mask;
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out[6] -= 0xfffffff & mask;
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out[7] -= 0xfffffff & mask;
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}
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// Group element functions.
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//
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// These functions deal with group elements. The group is an elliptic curve
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// group with a = -3 defined in FIPS 186-3, section D.2.2.
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using crypto::p224::Point;
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// kB is parameter of the elliptic curve.
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const FieldElement kB = {
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55967668, 11768882, 265861671, 185302395,
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39211076, 180311059, 84673715, 188764328,
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};
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void CopyConditional(Point* out, const Point& a, uint32_t mask);
|
||
void DoubleJacobian(Point* out, const Point& a);
|
||
|
||
// AddJacobian computes *out = a+b where a != b.
|
||
void AddJacobian(Point *out,
|
||
const Point& a,
|
||
const Point& b) {
|
||
// See http://hyperelliptic.org/EFD/g1p/auto-shortw-jacobian-3.html#addition-add-2007-bl
|
||
FieldElement z1z1, z2z2, u1, u2, s1, s2, h, i, j, r, v;
|
||
|
||
uint32_t z1_is_zero = IsZero(a.z);
|
||
uint32_t z2_is_zero = IsZero(b.z);
|
||
|
||
// Z1Z1 = Z1²
|
||
Square(&z1z1, a.z);
|
||
|
||
// Z2Z2 = Z2²
|
||
Square(&z2z2, b.z);
|
||
|
||
// U1 = X1*Z2Z2
|
||
Mul(&u1, a.x, z2z2);
|
||
|
||
// U2 = X2*Z1Z1
|
||
Mul(&u2, b.x, z1z1);
|
||
|
||
// S1 = Y1*Z2*Z2Z2
|
||
Mul(&s1, b.z, z2z2);
|
||
Mul(&s1, a.y, s1);
|
||
|
||
// S2 = Y2*Z1*Z1Z1
|
||
Mul(&s2, a.z, z1z1);
|
||
Mul(&s2, b.y, s2);
|
||
|
||
// H = U2-U1
|
||
Subtract(&h, u2, u1);
|
||
Reduce(&h);
|
||
uint32_t x_equal = IsZero(h);
|
||
|
||
// I = (2*H)²
|
||
for (int k = 0; k < 8; k++) {
|
||
i[k] = h[k] << 1;
|
||
}
|
||
Reduce(&i);
|
||
Square(&i, i);
|
||
|
||
// J = H*I
|
||
Mul(&j, h, i);
|
||
// r = 2*(S2-S1)
|
||
Subtract(&r, s2, s1);
|
||
Reduce(&r);
|
||
uint32_t y_equal = IsZero(r);
|
||
|
||
if (x_equal && y_equal && !z1_is_zero && !z2_is_zero) {
|
||
// The two input points are the same therefore we must use the dedicated
|
||
// doubling function as the slope of the line is undefined.
|
||
DoubleJacobian(out, a);
|
||
return;
|
||
}
|
||
|
||
for (int k = 0; k < 8; k++) {
|
||
r[k] <<= 1;
|
||
}
|
||
Reduce(&r);
|
||
|
||
// V = U1*I
|
||
Mul(&v, u1, i);
|
||
|
||
// Z3 = ((Z1+Z2)²-Z1Z1-Z2Z2)*H
|
||
Add(&z1z1, z1z1, z2z2);
|
||
Add(&z2z2, a.z, b.z);
|
||
Reduce(&z2z2);
|
||
Square(&z2z2, z2z2);
|
||
Subtract(&out->z, z2z2, z1z1);
|
||
Reduce(&out->z);
|
||
Mul(&out->z, out->z, h);
|
||
|
||
// X3 = r²-J-2*V
|
||
for (int k = 0; k < 8; k++) {
|
||
z1z1[k] = v[k] << 1;
|
||
}
|
||
Add(&z1z1, j, z1z1);
|
||
Reduce(&z1z1);
|
||
Square(&out->x, r);
|
||
Subtract(&out->x, out->x, z1z1);
|
||
Reduce(&out->x);
|
||
|
||
// Y3 = r*(V-X3)-2*S1*J
|
||
for (int k = 0; k < 8; k++) {
|
||
s1[k] <<= 1;
|
||
}
|
||
Mul(&s1, s1, j);
|
||
Subtract(&z1z1, v, out->x);
|
||
Reduce(&z1z1);
|
||
Mul(&z1z1, z1z1, r);
|
||
Subtract(&out->y, z1z1, s1);
|
||
Reduce(&out->y);
|
||
|
||
CopyConditional(out, a, z2_is_zero);
|
||
CopyConditional(out, b, z1_is_zero);
|
||
}
|
||
|
||
// DoubleJacobian computes *out = a+a.
|
||
void DoubleJacobian(Point* out, const Point& a) {
|
||
// See http://hyperelliptic.org/EFD/g1p/auto-shortw-jacobian-3.html#doubling-dbl-2001-b
|
||
FieldElement delta, gamma, beta, alpha, t;
|
||
|
||
Square(&delta, a.z);
|
||
Square(&gamma, a.y);
|
||
Mul(&beta, a.x, gamma);
|
||
|
||
// alpha = 3*(X1-delta)*(X1+delta)
|
||
Add(&t, a.x, delta);
|
||
for (int i = 0; i < 8; i++) {
|
||
t[i] += t[i] << 1;
|
||
}
|
||
Reduce(&t);
|
||
Subtract(&alpha, a.x, delta);
|
||
Reduce(&alpha);
|
||
Mul(&alpha, alpha, t);
|
||
|
||
// Z3 = (Y1+Z1)²-gamma-delta
|
||
Add(&out->z, a.y, a.z);
|
||
Reduce(&out->z);
|
||
Square(&out->z, out->z);
|
||
Subtract(&out->z, out->z, gamma);
|
||
Reduce(&out->z);
|
||
Subtract(&out->z, out->z, delta);
|
||
Reduce(&out->z);
|
||
|
||
// X3 = alpha²-8*beta
|
||
for (int i = 0; i < 8; i++) {
|
||
delta[i] = beta[i] << 3;
|
||
}
|
||
Reduce(&delta);
|
||
Square(&out->x, alpha);
|
||
Subtract(&out->x, out->x, delta);
|
||
Reduce(&out->x);
|
||
|
||
// Y3 = alpha*(4*beta-X3)-8*gamma²
|
||
for (int i = 0; i < 8; i++) {
|
||
beta[i] <<= 2;
|
||
}
|
||
Reduce(&beta);
|
||
Subtract(&beta, beta, out->x);
|
||
Reduce(&beta);
|
||
Square(&gamma, gamma);
|
||
for (int i = 0; i < 8; i++) {
|
||
gamma[i] <<= 3;
|
||
}
|
||
Reduce(&gamma);
|
||
Mul(&out->y, alpha, beta);
|
||
Subtract(&out->y, out->y, gamma);
|
||
Reduce(&out->y);
|
||
}
|
||
|
||
// CopyConditional sets *out=a if mask is 0xffffffff. mask must be either 0 of
|
||
// 0xffffffff.
|
||
void CopyConditional(Point* out, const Point& a, uint32_t mask) {
|
||
for (int i = 0; i < 8; i++) {
|
||
out->x[i] ^= mask & (a.x[i] ^ out->x[i]);
|
||
out->y[i] ^= mask & (a.y[i] ^ out->y[i]);
|
||
out->z[i] ^= mask & (a.z[i] ^ out->z[i]);
|
||
}
|
||
}
|
||
|
||
// ScalarMult calculates *out = a*scalar where scalar is a big-endian number of
|
||
// length scalar_len and != 0.
|
||
void ScalarMult(Point* out,
|
||
const Point& a,
|
||
const uint8_t* scalar,
|
||
size_t scalar_len) {
|
||
memset(out, 0, sizeof(*out));
|
||
Point tmp;
|
||
|
||
for (size_t i = 0; i < scalar_len; i++) {
|
||
for (unsigned int bit_num = 0; bit_num < 8; bit_num++) {
|
||
DoubleJacobian(out, *out);
|
||
uint32_t bit = static_cast<uint32_t>(static_cast<int32_t>(
|
||
(((scalar[i] >> (7 - bit_num)) & 1) << 31) >> 31));
|
||
AddJacobian(&tmp, a, *out);
|
||
CopyConditional(out, tmp, bit);
|
||
}
|
||
}
|
||
}
|
||
|
||
// Get224Bits reads 7 words from in and scatters their contents in
|
||
// little-endian form into 8 words at out, 28 bits per output word.
|
||
void Get224Bits(uint32_t* out, const uint32_t* in) {
|
||
out[0] = NetToHost32(in[6]) & kBottom28Bits;
|
||
out[1] = ((NetToHost32(in[5]) << 4) |
|
||
(NetToHost32(in[6]) >> 28)) & kBottom28Bits;
|
||
out[2] = ((NetToHost32(in[4]) << 8) |
|
||
(NetToHost32(in[5]) >> 24)) & kBottom28Bits;
|
||
out[3] = ((NetToHost32(in[3]) << 12) |
|
||
(NetToHost32(in[4]) >> 20)) & kBottom28Bits;
|
||
out[4] = ((NetToHost32(in[2]) << 16) |
|
||
(NetToHost32(in[3]) >> 16)) & kBottom28Bits;
|
||
out[5] = ((NetToHost32(in[1]) << 20) |
|
||
(NetToHost32(in[2]) >> 12)) & kBottom28Bits;
|
||
out[6] = ((NetToHost32(in[0]) << 24) |
|
||
(NetToHost32(in[1]) >> 8)) & kBottom28Bits;
|
||
out[7] = (NetToHost32(in[0]) >> 4) & kBottom28Bits;
|
||
}
|
||
|
||
// Put224Bits performs the inverse operation to Get224Bits: taking 28 bits from
|
||
// each of 8 input words and writing them in big-endian order to 7 words at
|
||
// out.
|
||
void Put224Bits(uint32_t* out, const uint32_t* in) {
|
||
out[6] = HostToNet32((in[0] >> 0) | (in[1] << 28));
|
||
out[5] = HostToNet32((in[1] >> 4) | (in[2] << 24));
|
||
out[4] = HostToNet32((in[2] >> 8) | (in[3] << 20));
|
||
out[3] = HostToNet32((in[3] >> 12) | (in[4] << 16));
|
||
out[2] = HostToNet32((in[4] >> 16) | (in[5] << 12));
|
||
out[1] = HostToNet32((in[5] >> 20) | (in[6] << 8));
|
||
out[0] = HostToNet32((in[6] >> 24) | (in[7] << 4));
|
||
}
|
||
|
||
} // anonymous namespace
|
||
|
||
namespace crypto {
|
||
|
||
namespace p224 {
|
||
|
||
bool Point::SetFromString(base::StringPiece in) {
|
||
if (in.size() != 2*28)
|
||
return false;
|
||
const uint32_t* inwords = reinterpret_cast<const uint32_t*>(in.data());
|
||
Get224Bits(x, inwords);
|
||
Get224Bits(y, inwords + 7);
|
||
memset(&z, 0, sizeof(z));
|
||
z[0] = 1;
|
||
|
||
// Check that the point is on the curve, i.e. that y² = x³ - 3x + b.
|
||
FieldElement lhs;
|
||
Square(&lhs, y);
|
||
Contract(&lhs);
|
||
|
||
FieldElement rhs;
|
||
Square(&rhs, x);
|
||
Mul(&rhs, x, rhs);
|
||
|
||
FieldElement three_x;
|
||
for (int i = 0; i < 8; i++) {
|
||
three_x[i] = x[i] * 3;
|
||
}
|
||
Reduce(&three_x);
|
||
Subtract(&rhs, rhs, three_x);
|
||
Reduce(&rhs);
|
||
|
||
::Add(&rhs, rhs, kB);
|
||
Contract(&rhs);
|
||
return memcmp(&lhs, &rhs, sizeof(lhs)) == 0;
|
||
}
|
||
|
||
std::string Point::ToString() const {
|
||
FieldElement zinv, zinv_sq, xx, yy;
|
||
|
||
// If this is the point at infinity we return a string of all zeros.
|
||
if (IsZero(this->z)) {
|
||
static const char zeros[56] = {0};
|
||
return std::string(zeros, sizeof(zeros));
|
||
}
|
||
|
||
Invert(&zinv, this->z);
|
||
Square(&zinv_sq, zinv);
|
||
Mul(&xx, x, zinv_sq);
|
||
Mul(&zinv_sq, zinv_sq, zinv);
|
||
Mul(&yy, y, zinv_sq);
|
||
|
||
Contract(&xx);
|
||
Contract(&yy);
|
||
|
||
uint32_t outwords[14];
|
||
Put224Bits(outwords, xx);
|
||
Put224Bits(outwords + 7, yy);
|
||
return std::string(reinterpret_cast<const char*>(outwords), sizeof(outwords));
|
||
}
|
||
|
||
void ScalarMult(const Point& in, const uint8_t* scalar, Point* out) {
|
||
::ScalarMult(out, in, scalar, 28);
|
||
}
|
||
|
||
// kBasePoint is the base point (generator) of the elliptic curve group.
|
||
static const Point kBasePoint = {
|
||
{22813985, 52956513, 34677300, 203240812,
|
||
12143107, 133374265, 225162431, 191946955},
|
||
{83918388, 223877528, 122119236, 123340192,
|
||
266784067, 263504429, 146143011, 198407736},
|
||
{1, 0, 0, 0, 0, 0, 0, 0},
|
||
};
|
||
|
||
void ScalarBaseMult(const uint8_t* scalar, Point* out) {
|
||
::ScalarMult(out, kBasePoint, scalar, 28);
|
||
}
|
||
|
||
void Add(const Point& a, const Point& b, Point* out) {
|
||
AddJacobian(out, a, b);
|
||
}
|
||
|
||
void Negate(const Point& in, Point* out) {
|
||
// Guide to elliptic curve cryptography, page 89 suggests that (X : X+Y : Z)
|
||
// is the negative in Jacobian coordinates, but it doesn't actually appear to
|
||
// be true in testing so this performs the negation in affine coordinates.
|
||
FieldElement zinv, zinv_sq, y;
|
||
Invert(&zinv, in.z);
|
||
Square(&zinv_sq, zinv);
|
||
Mul(&out->x, in.x, zinv_sq);
|
||
Mul(&zinv_sq, zinv_sq, zinv);
|
||
Mul(&y, in.y, zinv_sq);
|
||
|
||
Subtract(&out->y, kP, y);
|
||
Reduce(&out->y);
|
||
|
||
memset(&out->z, 0, sizeof(out->z));
|
||
out->z[0] = 1;
|
||
}
|
||
|
||
} // namespace p224
|
||
|
||
} // namespace crypto
|