libgo/go/crypto/aes/gcm_ppc64le.go - rust-lang/gcc - Git at Google

 // Copyright 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.

 //go:build ignore && ppc64le

 package aes

 import (
 	"crypto/cipher"
 	"crypto/subtle"
 	"encoding/binary"
 	"errors"
 )

 // This file implements GCM using an optimized GHASH function.

 //go:noescape
 func gcmInit(productTable *[256]byte, h []byte)

 //go:noescape
 func gcmHash(output []byte, productTable *[256]byte, inp []byte, len int)

 //go:noescape
 func gcmMul(output []byte, productTable *[256]byte)

 const (
 	gcmCounterSize       = 16
 	gcmBlockSize         = 16
 	gcmTagSize           = 16
 	gcmStandardNonceSize = 12
 )

 var errOpen = errors.New("cipher: message authentication failed")

 // Assert that aesCipherGCM implements the gcmAble interface.
 var _ gcmAble = (*aesCipherAsm)(nil)

 type gcmAsm struct {
 	cipher *aesCipherAsm
 	// ks is the key schedule, the length of which depends on the size of
 	// the AES key.
 	ks []uint32
 	// productTable contains pre-computed multiples of the binary-field
 	// element used in GHASH.
 	productTable [256]byte
 	// nonceSize contains the expected size of the nonce, in bytes.
 	nonceSize int
 	// tagSize contains the size of the tag, in bytes.
 	tagSize int
 }

 // NewGCM returns the AES cipher wrapped in Galois Counter Mode. This is only
 // called by crypto/cipher.NewGCM via the gcmAble interface.
 func (c *aesCipherAsm) NewGCM(nonceSize, tagSize int) (cipher.AEAD, error) {
 	g := &gcmAsm{cipher: c, ks: c.enc, nonceSize: nonceSize, tagSize: tagSize}

 	hle := make([]byte, gcmBlockSize)
 	c.Encrypt(hle, hle)

 	// Reverse the bytes in each 8 byte chunk
 	// Load little endian, store big endian
 	h1 := binary.LittleEndian.Uint64(hle[:8])
 	h2 := binary.LittleEndian.Uint64(hle[8:])
 	binary.BigEndian.PutUint64(hle[:8], h1)
 	binary.BigEndian.PutUint64(hle[8:], h2)
 	gcmInit(&g.productTable, hle)

 	return g, nil
 }

 func (g *gcmAsm) NonceSize() int {
 	return g.nonceSize
 }

 func (g *gcmAsm) Overhead() int {
 	return g.tagSize
 }

 func sliceForAppend(in []byte, n int) (head, tail []byte) {
 	if total := len(in) + n; cap(in) >= total {
 		head = in[:total]
 	} else {
 		head = make([]byte, total)
 		copy(head, in)
 	}
 	tail = head[len(in):]
 	return
 }

 // deriveCounter computes the initial GCM counter state from the given nonce.
 func (g *gcmAsm) deriveCounter(counter *[gcmBlockSize]byte, nonce []byte) {
 	if len(nonce) == gcmStandardNonceSize {
 		copy(counter[:], nonce)
 		counter[gcmBlockSize-1] = 1
 	} else {
 		var hash [16]byte
 		g.paddedGHASH(&hash, nonce)
 		lens := gcmLengths(0, uint64(len(nonce))*8)
 		g.paddedGHASH(&hash, lens[:])
 		copy(counter[:], hash[:])
 	}
 }

 // counterCrypt encrypts in using AES in counter mode and places the result
 // into out. counter is the initial count value and will be updated with the next
 // count value. The length of out must be greater than or equal to the length
 // of in.
 func (g *gcmAsm) counterCrypt(out, in []byte, counter *[gcmBlockSize]byte) {
 	var mask [gcmBlockSize]byte

 	for len(in) >= gcmBlockSize {
 		// Hint to avoid bounds check
 		_, _ = in[15], out[15]
 		g.cipher.Encrypt(mask[:], counter[:])
 		gcmInc32(counter)

 		// XOR 16 bytes each loop iteration in 8 byte chunks
 		in0 := binary.LittleEndian.Uint64(in[0:])
 		in1 := binary.LittleEndian.Uint64(in[8:])
 		m0 := binary.LittleEndian.Uint64(mask[:8])
 		m1 := binary.LittleEndian.Uint64(mask[8:])
 		binary.LittleEndian.PutUint64(out[:8], in0^m0)
 		binary.LittleEndian.PutUint64(out[8:], in1^m1)
 		out = out[16:]
 		in = in[16:]
 	}

 	if len(in) > 0 {
 		g.cipher.Encrypt(mask[:], counter[:])
 		gcmInc32(counter)
 		// XOR leftover bytes
 		for i, inb := range in {
 			out[i] = inb ^ mask[i]
 		}
 	}
 }

 // increments the rightmost 32-bits of the count value by 1.
 func gcmInc32(counterBlock *[16]byte) {
 	c := counterBlock[len(counterBlock)-4:]
 	x := binary.BigEndian.Uint32(c) + 1
 	binary.BigEndian.PutUint32(c, x)
 }

 // paddedGHASH pads data with zeroes until its length is a multiple of
 // 16-bytes. It then calculates a new value for hash using the ghash
 // algorithm.
 func (g *gcmAsm) paddedGHASH(hash *[16]byte, data []byte) {
 	if siz := len(data) - (len(data) % gcmBlockSize); siz > 0 {
 		gcmHash(hash[:], &g.productTable, data[:], siz)
 		data = data[siz:]
 	}
 	if len(data) > 0 {
 		var s [16]byte
 		copy(s[:], data)
 		gcmHash(hash[:], &g.productTable, s[:], len(s))
 	}
 }

 // auth calculates GHASH(ciphertext, additionalData), masks the result with
 // tagMask and writes the result to out.
 func (g *gcmAsm) auth(out, ciphertext, aad []byte, tagMask *[gcmTagSize]byte) {
 	var hash [16]byte
 	g.paddedGHASH(&hash, aad)
 	g.paddedGHASH(&hash, ciphertext)
 	lens := gcmLengths(uint64(len(aad))*8, uint64(len(ciphertext))*8)
 	g.paddedGHASH(&hash, lens[:])

 	copy(out, hash[:])
 	for i := range out {
 		out[i] ^= tagMask[i]
 	}
 }

 // Seal encrypts and authenticates plaintext. See the cipher.AEAD interface for
 // details.
 func (g *gcmAsm) Seal(dst, nonce, plaintext, data []byte) []byte {
 	if len(nonce) != g.nonceSize {
 		panic("cipher: incorrect nonce length given to GCM")
 	}
 	if uint64(len(plaintext)) > ((1<<32)-2)*BlockSize {
 		panic("cipher: message too large for GCM")
 	}

 	ret, out := sliceForAppend(dst, len(plaintext)+g.tagSize)

 	var counter, tagMask [gcmBlockSize]byte
 	g.deriveCounter(&counter, nonce)

 	g.cipher.Encrypt(tagMask[:], counter[:])
 	gcmInc32(&counter)

 	g.counterCrypt(out, plaintext, &counter)
 	g.auth(out[len(plaintext):], out[:len(plaintext)], data, &tagMask)

 	return ret
 }

 // Open authenticates and decrypts ciphertext. See the cipher.AEAD interface
 // for details.
 func (g *gcmAsm) Open(dst, nonce, ciphertext, data []byte) ([]byte, error) {
 	if len(nonce) != g.nonceSize {
 		panic("cipher: incorrect nonce length given to GCM")
 	}
 	if len(ciphertext) < g.tagSize {
 		return nil, errOpen
 	}
 	if uint64(len(ciphertext)) > ((1<<32)-2)*uint64(BlockSize)+uint64(g.tagSize) {
 		return nil, errOpen
 	}

 	tag := ciphertext[len(ciphertext)-g.tagSize:]
 	ciphertext = ciphertext[:len(ciphertext)-g.tagSize]

 	var counter, tagMask [gcmBlockSize]byte
 	g.deriveCounter(&counter, nonce)

 	g.cipher.Encrypt(tagMask[:], counter[:])
 	gcmInc32(&counter)

 	var expectedTag [gcmTagSize]byte
 	g.auth(expectedTag[:], ciphertext, data, &tagMask)

 	ret, out := sliceForAppend(dst, len(ciphertext))

 	if subtle.ConstantTimeCompare(expectedTag[:g.tagSize], tag) != 1 {
 		for i := range out {
 			out[i] = 0
 		}
 		return nil, errOpen
 	}

 	g.counterCrypt(out, ciphertext, &counter)
 	return ret, nil
 }

 func gcmLengths(len0, len1 uint64) [16]byte {
 	return [16]byte{
 		byte(len0 >> 56),
 		byte(len0 >> 48),
 		byte(len0 >> 40),
 		byte(len0 >> 32),
 		byte(len0 >> 24),
 		byte(len0 >> 16),
 		byte(len0 >> 8),
 		byte(len0),
 		byte(len1 >> 56),
 		byte(len1 >> 48),
 		byte(len1 >> 40),
 		byte(len1 >> 32),
 		byte(len1 >> 24),
 		byte(len1 >> 16),
 		byte(len1 >> 8),
 		byte(len1),
 	}
 }
	// Copyright 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.

	//go:build ignore && ppc64le

	package aes

	import (
	"crypto/cipher"
	"crypto/subtle"
	"encoding/binary"
	"errors"
	)

	// This file implements GCM using an optimized GHASH function.

	//go:noescape
	func gcmInit(productTable *[256]byte, h []byte)

	//go:noescape
	func gcmHash(output []byte, productTable *[256]byte, inp []byte, len int)

	//go:noescape
	func gcmMul(output []byte, productTable *[256]byte)

	const (
	gcmCounterSize = 16
	gcmBlockSize = 16
	gcmTagSize = 16
	gcmStandardNonceSize = 12
	)

	var errOpen = errors.New("cipher: message authentication failed")

	// Assert that aesCipherGCM implements the gcmAble interface.
	var _ gcmAble = (*aesCipherAsm)(nil)

	type gcmAsm struct {
	cipher *aesCipherAsm
	// ks is the key schedule, the length of which depends on the size of
	// the AES key.
	ks []uint32
	// productTable contains pre-computed multiples of the binary-field
	// element used in GHASH.
	productTable [256]byte
	// nonceSize contains the expected size of the nonce, in bytes.
	nonceSize int
	// tagSize contains the size of the tag, in bytes.
	tagSize int
	}

	// NewGCM returns the AES cipher wrapped in Galois Counter Mode. This is only
	// called by crypto/cipher.NewGCM via the gcmAble interface.
	func (c *aesCipherAsm) NewGCM(nonceSize, tagSize int) (cipher.AEAD, error) {
	g := &gcmAsm{cipher: c, ks: c.enc, nonceSize: nonceSize, tagSize: tagSize}

	hle := make([]byte, gcmBlockSize)
	c.Encrypt(hle, hle)

	// Reverse the bytes in each 8 byte chunk
	// Load little endian, store big endian
	h1 := binary.LittleEndian.Uint64(hle[:8])
	h2 := binary.LittleEndian.Uint64(hle[8:])
	binary.BigEndian.PutUint64(hle[:8], h1)
	binary.BigEndian.PutUint64(hle[8:], h2)
	gcmInit(&g.productTable, hle)

	return g, nil
	}

	func (g *gcmAsm) NonceSize() int {
	return g.nonceSize
	}

	func (g *gcmAsm) Overhead() int {
	return g.tagSize
	}

	func sliceForAppend(in []byte, n int) (head, tail []byte) {
	if total := len(in) + n; cap(in) >= total {
	head = in[:total]
	} else {
	head = make([]byte, total)
	copy(head, in)
	}
	tail = head[len(in):]
	return
	}

	// deriveCounter computes the initial GCM counter state from the given nonce.
	func (g gcmAsm) deriveCounter(counter [gcmBlockSize]byte, nonce []byte) {
	if len(nonce) == gcmStandardNonceSize {
	copy(counter[:], nonce)
	counter[gcmBlockSize-1] = 1
	} else {
	var hash [16]byte
	g.paddedGHASH(&hash, nonce)
	lens := gcmLengths(0, uint64(len(nonce))*8)
	g.paddedGHASH(&hash, lens[:])
	copy(counter[:], hash[:])
	}
	}

	// counterCrypt encrypts in using AES in counter mode and places the result
	// into out. counter is the initial count value and will be updated with the next
	// count value. The length of out must be greater than or equal to the length
	// of in.
	func (g gcmAsm) counterCrypt(out, in []byte, counter [gcmBlockSize]byte) {
	var mask [gcmBlockSize]byte

	for len(in) >= gcmBlockSize {
	// Hint to avoid bounds check
	_, _ = in[15], out[15]
	g.cipher.Encrypt(mask[:], counter[:])
	gcmInc32(counter)

	// XOR 16 bytes each loop iteration in 8 byte chunks
	in0 := binary.LittleEndian.Uint64(in[0:])
	in1 := binary.LittleEndian.Uint64(in[8:])
	m0 := binary.LittleEndian.Uint64(mask[:8])
	m1 := binary.LittleEndian.Uint64(mask[8:])
	binary.LittleEndian.PutUint64(out[:8], in0^m0)
	binary.LittleEndian.PutUint64(out[8:], in1^m1)
	out = out[16:]
	in = in[16:]
	}

	if len(in) > 0 {
	g.cipher.Encrypt(mask[:], counter[:])
	gcmInc32(counter)
	// XOR leftover bytes
	for i, inb := range in {
	out[i] = inb ^ mask[i]
	}
	}
	}

	// increments the rightmost 32-bits of the count value by 1.
	func gcmInc32(counterBlock *[16]byte) {
	c := counterBlock[len(counterBlock)-4:]
	x := binary.BigEndian.Uint32(c) + 1
	binary.BigEndian.PutUint32(c, x)
	}

	// paddedGHASH pads data with zeroes until its length is a multiple of
	// 16-bytes. It then calculates a new value for hash using the ghash
	// algorithm.
	func (g gcmAsm) paddedGHASH(hash [16]byte, data []byte) {
	if siz := len(data) - (len(data) % gcmBlockSize); siz > 0 {
	gcmHash(hash[:], &g.productTable, data[:], siz)
	data = data[siz:]
	}
	if len(data) > 0 {
	var s [16]byte
	copy(s[:], data)
	gcmHash(hash[:], &g.productTable, s[:], len(s))
	}
	}

	// auth calculates GHASH(ciphertext, additionalData), masks the result with
	// tagMask and writes the result to out.
	func (g gcmAsm) auth(out, ciphertext, aad []byte, tagMask [gcmTagSize]byte) {
	var hash [16]byte
	g.paddedGHASH(&hash, aad)
	g.paddedGHASH(&hash, ciphertext)
	lens := gcmLengths(uint64(len(aad))8, uint64(len(ciphertext))8)
	g.paddedGHASH(&hash, lens[:])

	copy(out, hash[:])
	for i := range out {
	out[i] ^= tagMask[i]
	}
	}

	// Seal encrypts and authenticates plaintext. See the cipher.AEAD interface for
	// details.
	func (g *gcmAsm) Seal(dst, nonce, plaintext, data []byte) []byte {
	if len(nonce) != g.nonceSize {
	panic("cipher: incorrect nonce length given to GCM")
	}
	if uint64(len(plaintext)) > ((1<<32)-2)*BlockSize {
	panic("cipher: message too large for GCM")
	}

	ret, out := sliceForAppend(dst, len(plaintext)+g.tagSize)

	var counter, tagMask [gcmBlockSize]byte
	g.deriveCounter(&counter, nonce)

	g.cipher.Encrypt(tagMask[:], counter[:])
	gcmInc32(&counter)

	g.counterCrypt(out, plaintext, &counter)
	g.auth(out[len(plaintext):], out[:len(plaintext)], data, &tagMask)

	return ret
	}

	// Open authenticates and decrypts ciphertext. See the cipher.AEAD interface
	// for details.
	func (g *gcmAsm) Open(dst, nonce, ciphertext, data []byte) ([]byte, error) {
	if len(nonce) != g.nonceSize {
	panic("cipher: incorrect nonce length given to GCM")
	}
	if len(ciphertext) < g.tagSize {
	return nil, errOpen
	}
	if uint64(len(ciphertext)) > ((1<<32)-2)*uint64(BlockSize)+uint64(g.tagSize) {
	return nil, errOpen
	}

	tag := ciphertext[len(ciphertext)-g.tagSize:]
	ciphertext = ciphertext[:len(ciphertext)-g.tagSize]

	var counter, tagMask [gcmBlockSize]byte
	g.deriveCounter(&counter, nonce)

	g.cipher.Encrypt(tagMask[:], counter[:])
	gcmInc32(&counter)

	var expectedTag [gcmTagSize]byte
	g.auth(expectedTag[:], ciphertext, data, &tagMask)

	ret, out := sliceForAppend(dst, len(ciphertext))

	if subtle.ConstantTimeCompare(expectedTag[:g.tagSize], tag) != 1 {
	for i := range out {
	out[i] = 0
	}
	return nil, errOpen
	}

	g.counterCrypt(out, ciphertext, &counter)
	return ret, nil
	}

	func gcmLengths(len0, len1 uint64) [16]byte {
	return [16]byte{
	byte(len0 >> 56),
	byte(len0 >> 48),
	byte(len0 >> 40),
	byte(len0 >> 32),
	byte(len0 >> 24),
	byte(len0 >> 16),
	byte(len0 >> 8),
	byte(len0),
	byte(len1 >> 56),
	byte(len1 >> 48),
	byte(len1 >> 40),
	byte(len1 >> 32),
	byte(len1 >> 24),
	byte(len1 >> 16),
	byte(len1 >> 8),
	byte(len1),
	}
	}