src/crypto/internal/nistec/p224.go - go - Git at Google

 // Copyright 2022 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.

 // Code generated by generate.go. DO NOT EDIT.

 package nistec

 import (
 	"crypto/internal/nistec/fiat"
 	"crypto/subtle"
 	"errors"
 	"sync"
 )

 // p224ElementLength is the length of an element of the base or scalar field,
 // which have the same bytes length for all NIST P curves.
 const p224ElementLength = 28

 // P224Point is a P224 point. The zero value is NOT valid.
 type P224Point struct {
 	// The point is represented in projective coordinates (X:Y:Z),
 	// where x = X/Z and y = Y/Z.
 	x, y, z *fiat.P224Element
 }

 // NewP224Point returns a new P224Point representing the point at infinity point.
 func NewP224Point() *P224Point {
 	return &P224Point{
 		x: new(fiat.P224Element),
 		y: new(fiat.P224Element).One(),
 		z: new(fiat.P224Element),
 	}
 }

 // SetGenerator sets p to the canonical generator and returns p.
 func (p *P224Point) SetGenerator() *P224Point {
 	p.x.SetBytes([]byte{0xb7, 0xe, 0xc, 0xbd, 0x6b, 0xb4, 0xbf, 0x7f, 0x32, 0x13, 0x90, 0xb9, 0x4a, 0x3, 0xc1, 0xd3, 0x56, 0xc2, 0x11, 0x22, 0x34, 0x32, 0x80, 0xd6, 0x11, 0x5c, 0x1d, 0x21})
 	p.y.SetBytes([]byte{0xbd, 0x37, 0x63, 0x88, 0xb5, 0xf7, 0x23, 0xfb, 0x4c, 0x22, 0xdf, 0xe6, 0xcd, 0x43, 0x75, 0xa0, 0x5a, 0x7, 0x47, 0x64, 0x44, 0xd5, 0x81, 0x99, 0x85, 0x0, 0x7e, 0x34})
 	p.z.One()
 	return p
 }

 // Set sets p = q and returns p.
 func (p *P224Point) Set(q *P224Point) *P224Point {
 	p.x.Set(q.x)
 	p.y.Set(q.y)
 	p.z.Set(q.z)
 	return p
 }

 // SetBytes sets p to the compressed, uncompressed, or infinity value encoded in
 // b, as specified in SEC 1, Version 2.0, Section 2.3.4. If the point is not on
 // the curve, it returns nil and an error, and the receiver is unchanged.
 // Otherwise, it returns p.
 func (p *P224Point) SetBytes(b []byte) (*P224Point, error) {
 	switch {
 	// Point at infinity.
 	case len(b) == 1 && b[0] == 0:
 		return p.Set(NewP224Point()), nil

 	// Uncompressed form.
 	case len(b) == 1+2*p224ElementLength && b[0] == 4:
 		x, err := new(fiat.P224Element).SetBytes(b[1 : 1+p224ElementLength])
 		if err != nil {
 			return nil, err
 		}
 		y, err := new(fiat.P224Element).SetBytes(b[1+p224ElementLength:])
 		if err != nil {
 			return nil, err
 		}
 		if err := p224CheckOnCurve(x, y); err != nil {
 			return nil, err
 		}
 		p.x.Set(x)
 		p.y.Set(y)
 		p.z.One()
 		return p, nil

 	// Compressed form.
 	case len(b) == 1+p224ElementLength && (b[0] == 2 || b[0] == 3):
 		x, err := new(fiat.P224Element).SetBytes(b[1:])
 		if err != nil {
 			return nil, err
 		}

 		// y² = x³ - 3x + b
 		y := p224Polynomial(new(fiat.P224Element), x)
 		if !p224Sqrt(y, y) {
 			return nil, errors.New("invalid P224 compressed point encoding")
 		}

 		// Select the positive or negative root, as indicated by the least
 		// significant bit, based on the encoding type byte.
 		otherRoot := new(fiat.P224Element)
 		otherRoot.Sub(otherRoot, y)
 		cond := y.Bytes()[p224ElementLength-1]&1 ^ b[0]&1
 		y.Select(otherRoot, y, int(cond))

 		p.x.Set(x)
 		p.y.Set(y)
 		p.z.One()
 		return p, nil

 	default:
 		return nil, errors.New("invalid P224 point encoding")
 	}
 }

 var _p224B *fiat.P224Element
 var _p224BOnce sync.Once

 func p224B() *fiat.P224Element {
 	_p224BOnce.Do(func() {
 		_p224B, _ = new(fiat.P224Element).SetBytes([]byte{0xb4, 0x5, 0xa, 0x85, 0xc, 0x4, 0xb3, 0xab, 0xf5, 0x41, 0x32, 0x56, 0x50, 0x44, 0xb0, 0xb7, 0xd7, 0xbf, 0xd8, 0xba, 0x27, 0xb, 0x39, 0x43, 0x23, 0x55, 0xff, 0xb4})
 	})
 	return _p224B
 }

 // p224Polynomial sets y2 to x³ - 3x + b, and returns y2.
 func p224Polynomial(y2, x *fiat.P224Element) *fiat.P224Element {
 	y2.Square(x)
 	y2.Mul(y2, x)

 	threeX := new(fiat.P224Element).Add(x, x)
 	threeX.Add(threeX, x)
 	y2.Sub(y2, threeX)

 	return y2.Add(y2, p224B())
 }

 func p224CheckOnCurve(x, y *fiat.P224Element) error {
 	// y² = x³ - 3x + b
 	rhs := p224Polynomial(new(fiat.P224Element), x)
 	lhs := new(fiat.P224Element).Square(y)
 	if rhs.Equal(lhs) != 1 {
 		return errors.New("P224 point not on curve")
 	}
 	return nil
 }

 // Bytes returns the uncompressed or infinity encoding of p, as specified in
 // SEC 1, Version 2.0, Section 2.3.3. Note that the encoding of the point at
 // infinity is shorter than all other encodings.
 func (p *P224Point) Bytes() []byte {
 	// This function is outlined to make the allocations inline in the caller
 	// rather than happen on the heap.
 	var out [1 + 2*p224ElementLength]byte
 	return p.bytes(&out)
 }

 func (p *P224Point) bytes(out *[1 + 2*p224ElementLength]byte) []byte {
 	if p.z.IsZero() == 1 {
 		return append(out[:0], 0)
 	}

 	zinv := new(fiat.P224Element).Invert(p.z)
 	x := new(fiat.P224Element).Mul(p.x, zinv)
 	y := new(fiat.P224Element).Mul(p.y, zinv)

 	buf := append(out[:0], 4)
 	buf = append(buf, x.Bytes()...)
 	buf = append(buf, y.Bytes()...)
 	return buf
 }

 // BytesX returns the encoding of the x-coordinate of p, as specified in SEC 1,
 // Version 2.0, Section 2.3.5, or an error if p is the point at infinity.
 func (p *P224Point) BytesX() ([]byte, error) {
 	// This function is outlined to make the allocations inline in the caller
 	// rather than happen on the heap.
 	var out [p224ElementLength]byte
 	return p.bytesX(&out)
 }

 func (p *P224Point) bytesX(out *[p224ElementLength]byte) ([]byte, error) {
 	if p.z.IsZero() == 1 {
 		return nil, errors.New("P224 point is the point at infinity")
 	}

 	zinv := new(fiat.P224Element).Invert(p.z)
 	x := new(fiat.P224Element).Mul(p.x, zinv)

 	return append(out[:0], x.Bytes()...), nil
 }

 // BytesCompressed returns the compressed or infinity encoding of p, as
 // specified in SEC 1, Version 2.0, Section 2.3.3. Note that the encoding of the
 // point at infinity is shorter than all other encodings.
 func (p *P224Point) BytesCompressed() []byte {
 	// This function is outlined to make the allocations inline in the caller
 	// rather than happen on the heap.
 	var out [1 + p224ElementLength]byte
 	return p.bytesCompressed(&out)
 }

 func (p *P224Point) bytesCompressed(out *[1 + p224ElementLength]byte) []byte {
 	if p.z.IsZero() == 1 {
 		return append(out[:0], 0)
 	}

 	zinv := new(fiat.P224Element).Invert(p.z)
 	x := new(fiat.P224Element).Mul(p.x, zinv)
 	y := new(fiat.P224Element).Mul(p.y, zinv)

 	// Encode the sign of the y coordinate (indicated by the least significant
 	// bit) as the encoding type (2 or 3).
 	buf := append(out[:0], 2)
 	buf[0] |= y.Bytes()[p224ElementLength-1] & 1
 	buf = append(buf, x.Bytes()...)
 	return buf
 }

 // Add sets q = p1 + p2, and returns q. The points may overlap.
 func (q *P224Point) Add(p1, p2 *P224Point) *P224Point {
 	// Complete addition formula for a = -3 from "Complete addition formulas for
 	// prime order elliptic curves" (https://eprint.iacr.org/2015/1060), §A.2.

 	t0 := new(fiat.P224Element).Mul(p1.x, p2.x)  // t0 := X1 * X2
 	t1 := new(fiat.P224Element).Mul(p1.y, p2.y)  // t1 := Y1 * Y2
 	t2 := new(fiat.P224Element).Mul(p1.z, p2.z)  // t2 := Z1 * Z2
 	t3 := new(fiat.P224Element).Add(p1.x, p1.y)  // t3 := X1 + Y1
 	t4 := new(fiat.P224Element).Add(p2.x, p2.y)  // t4 := X2 + Y2
 	t3.Mul(t3, t4)                               // t3 := t3 * t4
 	t4.Add(t0, t1)                               // t4 := t0 + t1
 	t3.Sub(t3, t4)                               // t3 := t3 - t4
 	t4.Add(p1.y, p1.z)                           // t4 := Y1 + Z1
 	x3 := new(fiat.P224Element).Add(p2.y, p2.z)  // X3 := Y2 + Z2
 	t4.Mul(t4, x3)                               // t4 := t4 * X3
 	x3.Add(t1, t2)                               // X3 := t1 + t2
 	t4.Sub(t4, x3)                               // t4 := t4 - X3
 	x3.Add(p1.x, p1.z)                           // X3 := X1 + Z1
 	y3 := new(fiat.P224Element).Add(p2.x, p2.z)  // Y3 := X2 + Z2
 	x3.Mul(x3, y3)                               // X3 := X3 * Y3
 	y3.Add(t0, t2)                               // Y3 := t0 + t2
 	y3.Sub(x3, y3)                               // Y3 := X3 - Y3
 	z3 := new(fiat.P224Element).Mul(p224B(), t2) // Z3 := b * t2
 	x3.Sub(y3, z3)                               // X3 := Y3 - Z3
 	z3.Add(x3, x3)                               // Z3 := X3 + X3
 	x3.Add(x3, z3)                               // X3 := X3 + Z3
 	z3.Sub(t1, x3)                               // Z3 := t1 - X3
 	x3.Add(t1, x3)                               // X3 := t1 + X3
 	y3.Mul(p224B(), y3)                          // Y3 := b * Y3
 	t1.Add(t2, t2)                               // t1 := t2 + t2
 	t2.Add(t1, t2)                               // t2 := t1 + t2
 	y3.Sub(y3, t2)                               // Y3 := Y3 - t2
 	y3.Sub(y3, t0)                               // Y3 := Y3 - t0
 	t1.Add(y3, y3)                               // t1 := Y3 + Y3
 	y3.Add(t1, y3)                               // Y3 := t1 + Y3
 	t1.Add(t0, t0)                               // t1 := t0 + t0
 	t0.Add(t1, t0)                               // t0 := t1 + t0
 	t0.Sub(t0, t2)                               // t0 := t0 - t2
 	t1.Mul(t4, y3)                               // t1 := t4 * Y3
 	t2.Mul(t0, y3)                               // t2 := t0 * Y3
 	y3.Mul(x3, z3)                               // Y3 := X3 * Z3
 	y3.Add(y3, t2)                               // Y3 := Y3 + t2
 	x3.Mul(t3, x3)                               // X3 := t3 * X3
 	x3.Sub(x3, t1)                               // X3 := X3 - t1
 	z3.Mul(t4, z3)                               // Z3 := t4 * Z3
 	t1.Mul(t3, t0)                               // t1 := t3 * t0
 	z3.Add(z3, t1)                               // Z3 := Z3 + t1

 	q.x.Set(x3)
 	q.y.Set(y3)
 	q.z.Set(z3)
 	return q
 }

 // Double sets q = p + p, and returns q. The points may overlap.
 func (q *P224Point) Double(p *P224Point) *P224Point {
 	// Complete addition formula for a = -3 from "Complete addition formulas for
 	// prime order elliptic curves" (https://eprint.iacr.org/2015/1060), §A.2.

 	t0 := new(fiat.P224Element).Square(p.x)      // t0 := X ^ 2
 	t1 := new(fiat.P224Element).Square(p.y)      // t1 := Y ^ 2
 	t2 := new(fiat.P224Element).Square(p.z)      // t2 := Z ^ 2
 	t3 := new(fiat.P224Element).Mul(p.x, p.y)    // t3 := X * Y
 	t3.Add(t3, t3)                               // t3 := t3 + t3
 	z3 := new(fiat.P224Element).Mul(p.x, p.z)    // Z3 := X * Z
 	z3.Add(z3, z3)                               // Z3 := Z3 + Z3
 	y3 := new(fiat.P224Element).Mul(p224B(), t2) // Y3 := b * t2
 	y3.Sub(y3, z3)                               // Y3 := Y3 - Z3
 	x3 := new(fiat.P224Element).Add(y3, y3)      // X3 := Y3 + Y3
 	y3.Add(x3, y3)                               // Y3 := X3 + Y3
 	x3.Sub(t1, y3)                               // X3 := t1 - Y3
 	y3.Add(t1, y3)                               // Y3 := t1 + Y3
 	y3.Mul(x3, y3)                               // Y3 := X3 * Y3
 	x3.Mul(x3, t3)                               // X3 := X3 * t3
 	t3.Add(t2, t2)                               // t3 := t2 + t2
 	t2.Add(t2, t3)                               // t2 := t2 + t3
 	z3.Mul(p224B(), z3)                          // Z3 := b * Z3
 	z3.Sub(z3, t2)                               // Z3 := Z3 - t2
 	z3.Sub(z3, t0)                               // Z3 := Z3 - t0
 	t3.Add(z3, z3)                               // t3 := Z3 + Z3
 	z3.Add(z3, t3)                               // Z3 := Z3 + t3
 	t3.Add(t0, t0)                               // t3 := t0 + t0
 	t0.Add(t3, t0)                               // t0 := t3 + t0
 	t0.Sub(t0, t2)                               // t0 := t0 - t2
 	t0.Mul(t0, z3)                               // t0 := t0 * Z3
 	y3.Add(y3, t0)                               // Y3 := Y3 + t0
 	t0.Mul(p.y, p.z)                             // t0 := Y * Z
 	t0.Add(t0, t0)                               // t0 := t0 + t0
 	z3.Mul(t0, z3)                               // Z3 := t0 * Z3
 	x3.Sub(x3, z3)                               // X3 := X3 - Z3
 	z3.Mul(t0, t1)                               // Z3 := t0 * t1
 	z3.Add(z3, z3)                               // Z3 := Z3 + Z3
 	z3.Add(z3, z3)                               // Z3 := Z3 + Z3

 	q.x.Set(x3)
 	q.y.Set(y3)
 	q.z.Set(z3)
 	return q
 }

 // Select sets q to p1 if cond == 1, and to p2 if cond == 0.
 func (q *P224Point) Select(p1, p2 *P224Point, cond int) *P224Point {
 	q.x.Select(p1.x, p2.x, cond)
 	q.y.Select(p1.y, p2.y, cond)
 	q.z.Select(p1.z, p2.z, cond)
 	return q
 }

 // A p224Table holds the first 15 multiples of a point at offset -1, so [1]P
 // is at table[0], [15]P is at table[14], and [0]P is implicitly the identity
 // point.
 type p224Table [15]*P224Point

 // Select selects the n-th multiple of the table base point into p. It works in
 // constant time by iterating over every entry of the table. n must be in [0, 15].
 func (table *p224Table) Select(p *P224Point, n uint8) {
 	if n >= 16 {
 		panic("nistec: internal error: p224Table called with out-of-bounds value")
 	}
 	p.Set(NewP224Point())
 	for i := uint8(1); i < 16; i++ {
 		cond := subtle.ConstantTimeByteEq(i, n)
 		p.Select(table[i-1], p, cond)
 	}
 }

 // ScalarMult sets p = scalar * q, and returns p.
 func (p *P224Point) ScalarMult(q *P224Point, scalar []byte) (*P224Point, error) {
 	// Compute a p224Table for the base point q. The explicit NewP224Point
 	// calls get inlined, letting the allocations live on the stack.
 	var table = p224Table{NewP224Point(), NewP224Point(), NewP224Point(),
 		NewP224Point(), NewP224Point(), NewP224Point(), NewP224Point(),
 		NewP224Point(), NewP224Point(), NewP224Point(), NewP224Point(),
 		NewP224Point(), NewP224Point(), NewP224Point(), NewP224Point()}
 	table[0].Set(q)
 	for i := 1; i < 15; i += 2 {
 		table[i].Double(table[i/2])
 		table[i+1].Add(table[i], q)
 	}

 	// Instead of doing the classic double-and-add chain, we do it with a
 	// four-bit window: we double four times, and then add [0-15]P.
 	t := NewP224Point()
 	p.Set(NewP224Point())
 	for i, byte := range scalar {
 		// No need to double on the first iteration, as p is the identity at
 		// this point, and [N]∞ = ∞.
 		if i != 0 {
 			p.Double(p)
 			p.Double(p)
 			p.Double(p)
 			p.Double(p)
 		}

 		windowValue := byte >> 4
 		table.Select(t, windowValue)
 		p.Add(p, t)

 		p.Double(p)
 		p.Double(p)
 		p.Double(p)
 		p.Double(p)

 		windowValue = byte & 0b1111
 		table.Select(t, windowValue)
 		p.Add(p, t)
 	}

 	return p, nil
 }

 var p224GeneratorTable *[p224ElementLength * 2]p224Table
 var p224GeneratorTableOnce sync.Once

 // generatorTable returns a sequence of p224Tables. The first table contains
 // multiples of G. Each successive table is the previous table doubled four
 // times.
 func (p *P224Point) generatorTable() *[p224ElementLength * 2]p224Table {
 	p224GeneratorTableOnce.Do(func() {
 		p224GeneratorTable = new([p224ElementLength * 2]p224Table)
 		base := NewP224Point().SetGenerator()
 		for i := 0; i < p224ElementLength*2; i++ {
 			p224GeneratorTable[i][0] = NewP224Point().Set(base)
 			for j := 1; j < 15; j++ {
 				p224GeneratorTable[i][j] = NewP224Point().Add(p224GeneratorTable[i][j-1], base)
 			}
 			base.Double(base)
 			base.Double(base)
 			base.Double(base)
 			base.Double(base)
 		}
 	})
 	return p224GeneratorTable
 }

 // ScalarBaseMult sets p = scalar * B, where B is the canonical generator, and
 // returns p.
 func (p *P224Point) ScalarBaseMult(scalar []byte) (*P224Point, error) {
 	if len(scalar) != p224ElementLength {
 		return nil, errors.New("invalid scalar length")
 	}
 	tables := p.generatorTable()

 	// This is also a scalar multiplication with a four-bit window like in
 	// ScalarMult, but in this case the doublings are precomputed. The value
 	// [windowValue]G added at iteration k would normally get doubled
 	// (totIterations-k)×4 times, but with a larger precomputation we can
 	// instead add [2^((totIterations-k)×4)][windowValue]G and avoid the
 	// doublings between iterations.
 	t := NewP224Point()
 	p.Set(NewP224Point())
 	tableIndex := len(tables) - 1
 	for _, byte := range scalar {
 		windowValue := byte >> 4
 		tables[tableIndex].Select(t, windowValue)
 		p.Add(p, t)
 		tableIndex--

 		windowValue = byte & 0b1111
 		tables[tableIndex].Select(t, windowValue)
 		p.Add(p, t)
 		tableIndex--
 	}

 	return p, nil
 }

 // p224Sqrt sets e to a square root of x. If x is not a square, p224Sqrt returns
 // false and e is unchanged. e and x can overlap.
 func p224Sqrt(e, x *fiat.P224Element) (isSquare bool) {
 	candidate := new(fiat.P224Element)
 	p224SqrtCandidate(candidate, x)
 	square := new(fiat.P224Element).Square(candidate)
 	if square.Equal(x) != 1 {
 		return false
 	}
 	e.Set(candidate)
 	return true
 }
	// Copyright 2022 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.

	// Code generated by generate.go. DO NOT EDIT.

	package nistec

	import (
	"crypto/internal/nistec/fiat"
	"crypto/subtle"
	"errors"
	"sync"
	)

	// p224ElementLength is the length of an element of the base or scalar field,
	// which have the same bytes length for all NIST P curves.
	const p224ElementLength = 28

	// P224Point is a P224 point. The zero value is NOT valid.
	type P224Point struct {
	// The point is represented in projective coordinates (X:Y:Z),
	// where x = X/Z and y = Y/Z.
	x, y, z *fiat.P224Element
	}

	// NewP224Point returns a new P224Point representing the point at infinity point.
	func NewP224Point() *P224Point {
	return &P224Point{
	x: new(fiat.P224Element),
	y: new(fiat.P224Element).One(),
	z: new(fiat.P224Element),
	}
	}

	// SetGenerator sets p to the canonical generator and returns p.
	func (p P224Point) SetGenerator() P224Point {
	p.x.SetBytes([]byte{0xb7, 0xe, 0xc, 0xbd, 0x6b, 0xb4, 0xbf, 0x7f, 0x32, 0x13, 0x90, 0xb9, 0x4a, 0x3, 0xc1, 0xd3, 0x56, 0xc2, 0x11, 0x22, 0x34, 0x32, 0x80, 0xd6, 0x11, 0x5c, 0x1d, 0x21})
	p.y.SetBytes([]byte{0xbd, 0x37, 0x63, 0x88, 0xb5, 0xf7, 0x23, 0xfb, 0x4c, 0x22, 0xdf, 0xe6, 0xcd, 0x43, 0x75, 0xa0, 0x5a, 0x7, 0x47, 0x64, 0x44, 0xd5, 0x81, 0x99, 0x85, 0x0, 0x7e, 0x34})
	p.z.One()
	return p
	}

	// Set sets p = q and returns p.
	func (p P224Point) Set(q P224Point) *P224Point {
	p.x.Set(q.x)
	p.y.Set(q.y)
	p.z.Set(q.z)
	return p
	}

	// SetBytes sets p to the compressed, uncompressed, or infinity value encoded in
	// b, as specified in SEC 1, Version 2.0, Section 2.3.4. If the point is not on
	// the curve, it returns nil and an error, and the receiver is unchanged.
	// Otherwise, it returns p.
	func (p P224Point) SetBytes(b []byte) (P224Point, error) {
	switch {
	// Point at infinity.
	case len(b) == 1 && b[0] == 0:
	return p.Set(NewP224Point()), nil

	// Uncompressed form.
	case len(b) == 1+2*p224ElementLength && b[0] == 4:
	x, err := new(fiat.P224Element).SetBytes(b[1 : 1+p224ElementLength])
	if err != nil {
	return nil, err
	}
	y, err := new(fiat.P224Element).SetBytes(b[1+p224ElementLength:])
	if err != nil {
	return nil, err
	}
	if err := p224CheckOnCurve(x, y); err != nil {
	return nil, err
	}
	p.x.Set(x)
	p.y.Set(y)
	p.z.One()
	return p, nil

	// Compressed form.
	case len(b) == 1+p224ElementLength && (b[0] == 2 \|\| b[0] == 3):
	x, err := new(fiat.P224Element).SetBytes(b[1:])
	if err != nil {
	return nil, err
	}

	// y² = x³ - 3x + b
	y := p224Polynomial(new(fiat.P224Element), x)
	if !p224Sqrt(y, y) {
	return nil, errors.New("invalid P224 compressed point encoding")
	}

	// Select the positive or negative root, as indicated by the least
	// significant bit, based on the encoding type byte.
	otherRoot := new(fiat.P224Element)
	otherRoot.Sub(otherRoot, y)
	cond := y.Bytes()[p224ElementLength-1]&1 ^ b[0]&1
	y.Select(otherRoot, y, int(cond))

	p.x.Set(x)
	p.y.Set(y)
	p.z.One()
	return p, nil

	default:
	return nil, errors.New("invalid P224 point encoding")
	}
	}

	var _p224B *fiat.P224Element
	var _p224BOnce sync.Once

	func p224B() *fiat.P224Element {
	_p224BOnce.Do(func() {
	_p224B, _ = new(fiat.P224Element).SetBytes([]byte{0xb4, 0x5, 0xa, 0x85, 0xc, 0x4, 0xb3, 0xab, 0xf5, 0x41, 0x32, 0x56, 0x50, 0x44, 0xb0, 0xb7, 0xd7, 0xbf, 0xd8, 0xba, 0x27, 0xb, 0x39, 0x43, 0x23, 0x55, 0xff, 0xb4})
	})
	return _p224B
	}

	// p224Polynomial sets y2 to x³ - 3x + b, and returns y2.
	func p224Polynomial(y2, x fiat.P224Element) fiat.P224Element {
	y2.Square(x)
	y2.Mul(y2, x)

	threeX := new(fiat.P224Element).Add(x, x)
	threeX.Add(threeX, x)
	y2.Sub(y2, threeX)

	return y2.Add(y2, p224B())
	}

	func p224CheckOnCurve(x, y *fiat.P224Element) error {
	// y² = x³ - 3x + b
	rhs := p224Polynomial(new(fiat.P224Element), x)
	lhs := new(fiat.P224Element).Square(y)
	if rhs.Equal(lhs) != 1 {
	return errors.New("P224 point not on curve")
	}
	return nil
	}

	// Bytes returns the uncompressed or infinity encoding of p, as specified in
	// SEC 1, Version 2.0, Section 2.3.3. Note that the encoding of the point at
	// infinity is shorter than all other encodings.
	func (p *P224Point) Bytes() []byte {
	// This function is outlined to make the allocations inline in the caller
	// rather than happen on the heap.
	var out [1 + 2*p224ElementLength]byte
	return p.bytes(&out)
	}

	func (p P224Point) bytes(out [1 + 2*p224ElementLength]byte) []byte {
	if p.z.IsZero() == 1 {
	return append(out[:0], 0)
	}

	zinv := new(fiat.P224Element).Invert(p.z)
	x := new(fiat.P224Element).Mul(p.x, zinv)
	y := new(fiat.P224Element).Mul(p.y, zinv)

	buf := append(out[:0], 4)
	buf = append(buf, x.Bytes()...)
	buf = append(buf, y.Bytes()...)
	return buf
	}

	// BytesX returns the encoding of the x-coordinate of p, as specified in SEC 1,
	// Version 2.0, Section 2.3.5, or an error if p is the point at infinity.
	func (p *P224Point) BytesX() ([]byte, error) {
	// This function is outlined to make the allocations inline in the caller
	// rather than happen on the heap.
	var out [p224ElementLength]byte
	return p.bytesX(&out)
	}

	func (p P224Point) bytesX(out [p224ElementLength]byte) ([]byte, error) {
	if p.z.IsZero() == 1 {
	return nil, errors.New("P224 point is the point at infinity")
	}

	zinv := new(fiat.P224Element).Invert(p.z)
	x := new(fiat.P224Element).Mul(p.x, zinv)

	return append(out[:0], x.Bytes()...), nil
	}

	// BytesCompressed returns the compressed or infinity encoding of p, as
	// specified in SEC 1, Version 2.0, Section 2.3.3. Note that the encoding of the
	// point at infinity is shorter than all other encodings.
	func (p *P224Point) BytesCompressed() []byte {
	// This function is outlined to make the allocations inline in the caller
	// rather than happen on the heap.
	var out [1 + p224ElementLength]byte
	return p.bytesCompressed(&out)
	}

	func (p P224Point) bytesCompressed(out [1 + p224ElementLength]byte) []byte {
	if p.z.IsZero() == 1 {
	return append(out[:0], 0)
	}

	zinv := new(fiat.P224Element).Invert(p.z)
	x := new(fiat.P224Element).Mul(p.x, zinv)
	y := new(fiat.P224Element).Mul(p.y, zinv)

	// Encode the sign of the y coordinate (indicated by the least significant
	// bit) as the encoding type (2 or 3).
	buf := append(out[:0], 2)
	buf[0] \|= y.Bytes()[p224ElementLength-1] & 1
	buf = append(buf, x.Bytes()...)
	return buf
	}

	// Add sets q = p1 + p2, and returns q. The points may overlap.
	func (q P224Point) Add(p1, p2 P224Point) *P224Point {
	// Complete addition formula for a = -3 from "Complete addition formulas for
	// prime order elliptic curves" (https://eprint.iacr.org/2015/1060), §A.2.

	t0 := new(fiat.P224Element).Mul(p1.x, p2.x) // t0 := X1 * X2
	t1 := new(fiat.P224Element).Mul(p1.y, p2.y) // t1 := Y1 * Y2
	t2 := new(fiat.P224Element).Mul(p1.z, p2.z) // t2 := Z1 * Z2
	t3 := new(fiat.P224Element).Add(p1.x, p1.y) // t3 := X1 + Y1
	t4 := new(fiat.P224Element).Add(p2.x, p2.y) // t4 := X2 + Y2
	t3.Mul(t3, t4) // t3 := t3 * t4
	t4.Add(t0, t1) // t4 := t0 + t1
	t3.Sub(t3, t4) // t3 := t3 - t4
	t4.Add(p1.y, p1.z) // t4 := Y1 + Z1
	x3 := new(fiat.P224Element).Add(p2.y, p2.z) // X3 := Y2 + Z2
	t4.Mul(t4, x3) // t4 := t4 * X3
	x3.Add(t1, t2) // X3 := t1 + t2
	t4.Sub(t4, x3) // t4 := t4 - X3
	x3.Add(p1.x, p1.z) // X3 := X1 + Z1
	y3 := new(fiat.P224Element).Add(p2.x, p2.z) // Y3 := X2 + Z2
	x3.Mul(x3, y3) // X3 := X3 * Y3
	y3.Add(t0, t2) // Y3 := t0 + t2
	y3.Sub(x3, y3) // Y3 := X3 - Y3
	z3 := new(fiat.P224Element).Mul(p224B(), t2) // Z3 := b * t2
	x3.Sub(y3, z3) // X3 := Y3 - Z3
	z3.Add(x3, x3) // Z3 := X3 + X3
	x3.Add(x3, z3) // X3 := X3 + Z3
	z3.Sub(t1, x3) // Z3 := t1 - X3
	x3.Add(t1, x3) // X3 := t1 + X3
	y3.Mul(p224B(), y3) // Y3 := b * Y3
	t1.Add(t2, t2) // t1 := t2 + t2
	t2.Add(t1, t2) // t2 := t1 + t2
	y3.Sub(y3, t2) // Y3 := Y3 - t2
	y3.Sub(y3, t0) // Y3 := Y3 - t0
	t1.Add(y3, y3) // t1 := Y3 + Y3
	y3.Add(t1, y3) // Y3 := t1 + Y3
	t1.Add(t0, t0) // t1 := t0 + t0
	t0.Add(t1, t0) // t0 := t1 + t0
	t0.Sub(t0, t2) // t0 := t0 - t2
	t1.Mul(t4, y3) // t1 := t4 * Y3
	t2.Mul(t0, y3) // t2 := t0 * Y3
	y3.Mul(x3, z3) // Y3 := X3 * Z3
	y3.Add(y3, t2) // Y3 := Y3 + t2
	x3.Mul(t3, x3) // X3 := t3 * X3
	x3.Sub(x3, t1) // X3 := X3 - t1
	z3.Mul(t4, z3) // Z3 := t4 * Z3
	t1.Mul(t3, t0) // t1 := t3 * t0
	z3.Add(z3, t1) // Z3 := Z3 + t1

	q.x.Set(x3)
	q.y.Set(y3)
	q.z.Set(z3)
	return q
	}

	// Double sets q = p + p, and returns q. The points may overlap.
	func (q P224Point) Double(p P224Point) *P224Point {
	// Complete addition formula for a = -3 from "Complete addition formulas for
	// prime order elliptic curves" (https://eprint.iacr.org/2015/1060), §A.2.

	t0 := new(fiat.P224Element).Square(p.x) // t0 := X ^ 2
	t1 := new(fiat.P224Element).Square(p.y) // t1 := Y ^ 2
	t2 := new(fiat.P224Element).Square(p.z) // t2 := Z ^ 2
	t3 := new(fiat.P224Element).Mul(p.x, p.y) // t3 := X * Y
	t3.Add(t3, t3) // t3 := t3 + t3
	z3 := new(fiat.P224Element).Mul(p.x, p.z) // Z3 := X * Z
	z3.Add(z3, z3) // Z3 := Z3 + Z3
	y3 := new(fiat.P224Element).Mul(p224B(), t2) // Y3 := b * t2
	y3.Sub(y3, z3) // Y3 := Y3 - Z3
	x3 := new(fiat.P224Element).Add(y3, y3) // X3 := Y3 + Y3
	y3.Add(x3, y3) // Y3 := X3 + Y3
	x3.Sub(t1, y3) // X3 := t1 - Y3
	y3.Add(t1, y3) // Y3 := t1 + Y3
	y3.Mul(x3, y3) // Y3 := X3 * Y3
	x3.Mul(x3, t3) // X3 := X3 * t3
	t3.Add(t2, t2) // t3 := t2 + t2
	t2.Add(t2, t3) // t2 := t2 + t3
	z3.Mul(p224B(), z3) // Z3 := b * Z3
	z3.Sub(z3, t2) // Z3 := Z3 - t2
	z3.Sub(z3, t0) // Z3 := Z3 - t0
	t3.Add(z3, z3) // t3 := Z3 + Z3
	z3.Add(z3, t3) // Z3 := Z3 + t3
	t3.Add(t0, t0) // t3 := t0 + t0
	t0.Add(t3, t0) // t0 := t3 + t0
	t0.Sub(t0, t2) // t0 := t0 - t2
	t0.Mul(t0, z3) // t0 := t0 * Z3
	y3.Add(y3, t0) // Y3 := Y3 + t0
	t0.Mul(p.y, p.z) // t0 := Y * Z
	t0.Add(t0, t0) // t0 := t0 + t0
	z3.Mul(t0, z3) // Z3 := t0 * Z3
	x3.Sub(x3, z3) // X3 := X3 - Z3
	z3.Mul(t0, t1) // Z3 := t0 * t1
	z3.Add(z3, z3) // Z3 := Z3 + Z3
	z3.Add(z3, z3) // Z3 := Z3 + Z3

	q.x.Set(x3)
	q.y.Set(y3)
	q.z.Set(z3)
	return q
	}

	// Select sets q to p1 if cond == 1, and to p2 if cond == 0.
	func (q P224Point) Select(p1, p2 P224Point, cond int) *P224Point {
	q.x.Select(p1.x, p2.x, cond)
	q.y.Select(p1.y, p2.y, cond)
	q.z.Select(p1.z, p2.z, cond)
	return q
	}

	// A p224Table holds the first 15 multiples of a point at offset -1, so [1]P
	// is at table[0], [15]P is at table[14], and [0]P is implicitly the identity
	// point.
	type p224Table [15]*P224Point

	// Select selects the n-th multiple of the table base point into p. It works in
	// constant time by iterating over every entry of the table. n must be in [0, 15].
	func (table p224Table) Select(p P224Point, n uint8) {
	if n >= 16 {
	panic("nistec: internal error: p224Table called with out-of-bounds value")
	}
	p.Set(NewP224Point())
	for i := uint8(1); i < 16; i++ {
	cond := subtle.ConstantTimeByteEq(i, n)
	p.Select(table[i-1], p, cond)
	}
	}

	// ScalarMult sets p = scalar * q, and returns p.
	func (p P224Point) ScalarMult(q P224Point, scalar []byte) (*P224Point, error) {
	// Compute a p224Table for the base point q. The explicit NewP224Point
	// calls get inlined, letting the allocations live on the stack.
	var table = p224Table{NewP224Point(), NewP224Point(), NewP224Point(),
	NewP224Point(), NewP224Point(), NewP224Point(), NewP224Point(),
	NewP224Point(), NewP224Point(), NewP224Point(), NewP224Point(),
	NewP224Point(), NewP224Point(), NewP224Point(), NewP224Point()}
	table[0].Set(q)
	for i := 1; i < 15; i += 2 {
	table[i].Double(table[i/2])
	table[i+1].Add(table[i], q)
	}

	// Instead of doing the classic double-and-add chain, we do it with a
	// four-bit window: we double four times, and then add [0-15]P.
	t := NewP224Point()
	p.Set(NewP224Point())
	for i, byte := range scalar {
	// No need to double on the first iteration, as p is the identity at
	// this point, and [N]∞ = ∞.
	if i != 0 {
	p.Double(p)
	p.Double(p)
	p.Double(p)
	p.Double(p)
	}

	windowValue := byte >> 4
	table.Select(t, windowValue)
	p.Add(p, t)

	p.Double(p)
	p.Double(p)
	p.Double(p)
	p.Double(p)

	windowValue = byte & 0b1111
	table.Select(t, windowValue)
	p.Add(p, t)
	}

	return p, nil
	}

	var p224GeneratorTable [p224ElementLength 2]p224Table
	var p224GeneratorTableOnce sync.Once

	// generatorTable returns a sequence of p224Tables. The first table contains
	// multiples of G. Each successive table is the previous table doubled four
	// times.
	func (p P224Point) generatorTable() [p224ElementLength * 2]p224Table {
	p224GeneratorTableOnce.Do(func() {
	p224GeneratorTable = new([p224ElementLength * 2]p224Table)
	base := NewP224Point().SetGenerator()
	for i := 0; i < p224ElementLength*2; i++ {
	p224GeneratorTable[i][0] = NewP224Point().Set(base)
	for j := 1; j < 15; j++ {
	p224GeneratorTable[i][j] = NewP224Point().Add(p224GeneratorTable[i][j-1], base)
	}
	base.Double(base)
	base.Double(base)
	base.Double(base)
	base.Double(base)
	}
	})
	return p224GeneratorTable
	}

	// ScalarBaseMult sets p = scalar * B, where B is the canonical generator, and
	// returns p.
	func (p P224Point) ScalarBaseMult(scalar []byte) (P224Point, error) {
	if len(scalar) != p224ElementLength {
	return nil, errors.New("invalid scalar length")
	}
	tables := p.generatorTable()

	// This is also a scalar multiplication with a four-bit window like in
	// ScalarMult, but in this case the doublings are precomputed. The value
	// [windowValue]G added at iteration k would normally get doubled
	// (totIterations-k)×4 times, but with a larger precomputation we can
	// instead add [2^((totIterations-k)×4)][windowValue]G and avoid the
	// doublings between iterations.
	t := NewP224Point()
	p.Set(NewP224Point())
	tableIndex := len(tables) - 1
	for _, byte := range scalar {
	windowValue := byte >> 4
	tables[tableIndex].Select(t, windowValue)
	p.Add(p, t)
	tableIndex--

	windowValue = byte & 0b1111
	tables[tableIndex].Select(t, windowValue)
	p.Add(p, t)
	tableIndex--
	}

	return p, nil
	}

	// p224Sqrt sets e to a square root of x. If x is not a square, p224Sqrt returns
	// false and e is unchanged. e and x can overlap.
	func p224Sqrt(e, x *fiat.P224Element) (isSquare bool) {
	candidate := new(fiat.P224Element)
	p224SqrtCandidate(candidate, x)
	square := new(fiat.P224Element).Square(candidate)
	if square.Equal(x) != 1 {
	return false
	}
	e.Set(candidate)
	return true
	}