libgo/go/crypto/ed25519/internal/edwards25519/tables.go - gofrontend - Git at Google

 // Copyright (c) 2019 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package edwards25519

 import (
 	"crypto/subtle"
 )

 // A dynamic lookup table for variable-base, constant-time scalar muls.
 type projLookupTable struct {
 	points [8]projCached
 }

 // A precomputed lookup table for fixed-base, constant-time scalar muls.
 type affineLookupTable struct {
 	points [8]affineCached
 }

 // A dynamic lookup table for variable-base, variable-time scalar muls.
 type nafLookupTable5 struct {
 	points [8]projCached
 }

 // A precomputed lookup table for fixed-base, variable-time scalar muls.
 type nafLookupTable8 struct {
 	points [64]affineCached
 }

 // Constructors.

 // Builds a lookup table at runtime. Fast.
 func (v *projLookupTable) FromP3(q *Point) {
 	// Goal: v.points[i] = (i+1)*Q, i.e., Q, 2Q, ..., 8Q
 	// This allows lookup of -8Q, ..., -Q, 0, Q, ..., 8Q
 	v.points[0].FromP3(q)
 	tmpP3 := Point{}
 	tmpP1xP1 := projP1xP1{}
 	for i := 0; i < 7; i++ {
 		// Compute (i+1)*Q as Q + i*Q and convert to a ProjCached
 		// This is needlessly complicated because the API has explicit
 		// recievers instead of creating stack objects and relying on RVO
 		v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.Add(q, &v.points[i])))
 	}
 }

 // This is not optimised for speed; fixed-base tables should be precomputed.
 func (v *affineLookupTable) FromP3(q *Point) {
 	// Goal: v.points[i] = (i+1)*Q, i.e., Q, 2Q, ..., 8Q
 	// This allows lookup of -8Q, ..., -Q, 0, Q, ..., 8Q
 	v.points[0].FromP3(q)
 	tmpP3 := Point{}
 	tmpP1xP1 := projP1xP1{}
 	for i := 0; i < 7; i++ {
 		// Compute (i+1)*Q as Q + i*Q and convert to AffineCached
 		v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.AddAffine(q, &v.points[i])))
 	}
 }

 // Builds a lookup table at runtime. Fast.
 func (v *nafLookupTable5) FromP3(q *Point) {
 	// Goal: v.points[i] = (2*i+1)*Q, i.e., Q, 3Q, 5Q, ..., 15Q
 	// This allows lookup of -15Q, ..., -3Q, -Q, 0, Q, 3Q, ..., 15Q
 	v.points[0].FromP3(q)
 	q2 := Point{}
 	q2.Add(q, q)
 	tmpP3 := Point{}
 	tmpP1xP1 := projP1xP1{}
 	for i := 0; i < 7; i++ {
 		v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.Add(&q2, &v.points[i])))
 	}
 }

 // This is not optimised for speed; fixed-base tables should be precomputed.
 func (v *nafLookupTable8) FromP3(q *Point) {
 	v.points[0].FromP3(q)
 	q2 := Point{}
 	q2.Add(q, q)
 	tmpP3 := Point{}
 	tmpP1xP1 := projP1xP1{}
 	for i := 0; i < 63; i++ {
 		v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.AddAffine(&q2, &v.points[i])))
 	}
 }

 // Selectors.

 // Set dest to x*Q, where -8 <= x <= 8, in constant time.
 func (v *projLookupTable) SelectInto(dest *projCached, x int8) {
 	// Compute xabs = |x|
 	xmask := x >> 7
 	xabs := uint8((x + xmask) ^ xmask)

 	dest.Zero()
 	for j := 1; j <= 8; j++ {
 		// Set dest = j*Q if |x| = j
 		cond := subtle.ConstantTimeByteEq(xabs, uint8(j))
 		dest.Select(&v.points[j-1], dest, cond)
 	}
 	// Now dest = |x|*Q, conditionally negate to get x*Q
 	dest.CondNeg(int(xmask & 1))
 }

 // Set dest to x*Q, where -8 <= x <= 8, in constant time.
 func (v *affineLookupTable) SelectInto(dest *affineCached, x int8) {
 	// Compute xabs = |x|
 	xmask := x >> 7
 	xabs := uint8((x + xmask) ^ xmask)

 	dest.Zero()
 	for j := 1; j <= 8; j++ {
 		// Set dest = j*Q if |x| = j
 		cond := subtle.ConstantTimeByteEq(xabs, uint8(j))
 		dest.Select(&v.points[j-1], dest, cond)
 	}
 	// Now dest = |x|*Q, conditionally negate to get x*Q
 	dest.CondNeg(int(xmask & 1))
 }

 // Given odd x with 0 < x < 2^4, return x*Q (in variable time).
 func (v *nafLookupTable5) SelectInto(dest *projCached, x int8) {
 	*dest = v.points[x/2]
 }

 // Given odd x with 0 < x < 2^7, return x*Q (in variable time).
 func (v *nafLookupTable8) SelectInto(dest *affineCached, x int8) {
 	*dest = v.points[x/2]
 }
	// Copyright (c) 2019 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package edwards25519

	import (
	"crypto/subtle"
	)

	// A dynamic lookup table for variable-base, constant-time scalar muls.
	type projLookupTable struct {
	points [8]projCached
	}

	// A precomputed lookup table for fixed-base, constant-time scalar muls.
	type affineLookupTable struct {
	points [8]affineCached
	}

	// A dynamic lookup table for variable-base, variable-time scalar muls.
	type nafLookupTable5 struct {
	points [8]projCached
	}

	// A precomputed lookup table for fixed-base, variable-time scalar muls.
	type nafLookupTable8 struct {
	points [64]affineCached
	}

	// Constructors.

	// Builds a lookup table at runtime. Fast.
	func (v projLookupTable) FromP3(q Point) {
	// Goal: v.points[i] = (i+1)*Q, i.e., Q, 2Q, ..., 8Q
	// This allows lookup of -8Q, ..., -Q, 0, Q, ..., 8Q
	v.points[0].FromP3(q)
	tmpP3 := Point{}
	tmpP1xP1 := projP1xP1{}
	for i := 0; i < 7; i++ {
	// Compute (i+1)Q as Q + iQ and convert to a ProjCached
	// This is needlessly complicated because the API has explicit
	// recievers instead of creating stack objects and relying on RVO
	v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.Add(q, &v.points[i])))
	}
	}

	// This is not optimised for speed; fixed-base tables should be precomputed.
	func (v affineLookupTable) FromP3(q Point) {
	// Goal: v.points[i] = (i+1)*Q, i.e., Q, 2Q, ..., 8Q
	// This allows lookup of -8Q, ..., -Q, 0, Q, ..., 8Q
	v.points[0].FromP3(q)
	tmpP3 := Point{}
	tmpP1xP1 := projP1xP1{}
	for i := 0; i < 7; i++ {
	// Compute (i+1)Q as Q + iQ and convert to AffineCached
	v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.AddAffine(q, &v.points[i])))
	}
	}

	// Builds a lookup table at runtime. Fast.
	func (v nafLookupTable5) FromP3(q Point) {
	// Goal: v.points[i] = (2i+1)Q, i.e., Q, 3Q, 5Q, ..., 15Q
	// This allows lookup of -15Q, ..., -3Q, -Q, 0, Q, 3Q, ..., 15Q
	v.points[0].FromP3(q)
	q2 := Point{}
	q2.Add(q, q)
	tmpP3 := Point{}
	tmpP1xP1 := projP1xP1{}
	for i := 0; i < 7; i++ {
	v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.Add(&q2, &v.points[i])))
	}
	}

	// This is not optimised for speed; fixed-base tables should be precomputed.
	func (v nafLookupTable8) FromP3(q Point) {
	v.points[0].FromP3(q)
	q2 := Point{}
	q2.Add(q, q)
	tmpP3 := Point{}
	tmpP1xP1 := projP1xP1{}
	for i := 0; i < 63; i++ {
	v.points[i+1].FromP3(tmpP3.fromP1xP1(tmpP1xP1.AddAffine(&q2, &v.points[i])))
	}
	}

	// Selectors.

	// Set dest to x*Q, where -8 <= x <= 8, in constant time.
	func (v projLookupTable) SelectInto(dest projCached, x int8) {
	// Compute xabs = \|x\|
	xmask := x >> 7
	xabs := uint8((x + xmask) ^ xmask)

	dest.Zero()
	for j := 1; j <= 8; j++ {
	// Set dest = j*Q if \|x\| = j
	cond := subtle.ConstantTimeByteEq(xabs, uint8(j))
	dest.Select(&v.points[j-1], dest, cond)
	}
	// Now dest = \|x\|Q, conditionally negate to get xQ
	dest.CondNeg(int(xmask & 1))
	}

	// Set dest to x*Q, where -8 <= x <= 8, in constant time.
	func (v affineLookupTable) SelectInto(dest affineCached, x int8) {
	// Compute xabs = \|x\|
	xmask := x >> 7
	xabs := uint8((x + xmask) ^ xmask)

	dest.Zero()
	for j := 1; j <= 8; j++ {
	// Set dest = j*Q if \|x\| = j
	cond := subtle.ConstantTimeByteEq(xabs, uint8(j))
	dest.Select(&v.points[j-1], dest, cond)
	}
	// Now dest = \|x\|Q, conditionally negate to get xQ
	dest.CondNeg(int(xmask & 1))
	}

	// Given odd x with 0 < x < 2^4, return x*Q (in variable time).
	func (v nafLookupTable5) SelectInto(dest projCached, x int8) {
	*dest = v.points[x/2]
	}

	// Given odd x with 0 < x < 2^7, return x*Q (in variable time).
	func (v nafLookupTable8) SelectInto(dest affineCached, x int8) {
	*dest = v.points[x/2]
	}