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// Copyright (C) 2019 ProtonTech AG
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// Package eax provides an implementation of the EAX
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// (encrypt-authenticate-translate) mode of operation, as described in
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// Bellare, Rogaway, and Wagner "THE EAX MODE OF OPERATION: A TWO-PASS
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// AUTHENTICATED-ENCRYPTION SCHEME OPTIMIZED FOR SIMPLICITY AND EFFICIENCY."
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// In FSE'04, volume 3017 of LNCS, 2004
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package eax
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import (
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"crypto/cipher"
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"crypto/subtle"
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"errors"
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"github.com/ProtonMail/go-crypto/internal/byteutil"
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)
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const (
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defaultTagSize = 16
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defaultNonceSize = 16
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)
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type eax struct {
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block cipher.Block // Only AES-{128, 192, 256} supported
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tagSize int // At least 12 bytes recommended
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nonceSize int
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}
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func (e *eax) NonceSize() int {
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return e.nonceSize
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}
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func (e *eax) Overhead() int {
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return e.tagSize
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}
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// NewEAX returns an EAX instance with AES-{KEYLENGTH} and default nonce and
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// tag lengths. Supports {128, 192, 256}- bit key length.
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func NewEAX(block cipher.Block) (cipher.AEAD, error) {
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return NewEAXWithNonceAndTagSize(block, defaultNonceSize, defaultTagSize)
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}
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// NewEAXWithNonceAndTagSize returns an EAX instance with AES-{keyLength} and
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// given nonce and tag lengths in bytes. Panics on zero nonceSize and
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// exceedingly long tags.
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//
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// It is recommended to use at least 12 bytes as tag length (see, for instance,
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// NIST SP 800-38D).
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//
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// Only to be used for compatibility with existing cryptosystems with
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// non-standard parameters. For all other cases, prefer NewEAX.
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func NewEAXWithNonceAndTagSize(
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block cipher.Block, nonceSize, tagSize int) (cipher.AEAD, error) {
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if nonceSize < 1 {
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return nil, eaxError("Cannot initialize EAX with nonceSize = 0")
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}
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if tagSize > block.BlockSize() {
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return nil, eaxError("Custom tag length exceeds blocksize")
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}
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return &eax{
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block: block,
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tagSize: tagSize,
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nonceSize: nonceSize,
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}, nil
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}
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func (e *eax) Seal(dst, nonce, plaintext, adata []byte) []byte {
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if len(nonce) > e.nonceSize {
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panic("crypto/eax: Nonce too long for this instance")
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}
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ret, out := byteutil.SliceForAppend(dst, len(plaintext) + e.tagSize)
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omacNonce := e.omacT(0, nonce)
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omacAdata := e.omacT(1, adata)
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// Encrypt message using CTR mode and omacNonce as IV
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ctr := cipher.NewCTR(e.block, omacNonce)
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ciphertextData := out[:len(plaintext)]
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ctr.XORKeyStream(ciphertextData, plaintext)
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omacCiphertext := e.omacT(2, ciphertextData)
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tag := out[len(plaintext):]
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for i := 0; i < e.tagSize; i++ {
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tag[i] = omacCiphertext[i] ^ omacNonce[i] ^ omacAdata[i]
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}
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return ret
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}
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func (e* eax) Open(dst, nonce, ciphertext, adata []byte) ([]byte, error) {
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if len(nonce) > e.nonceSize {
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panic("crypto/eax: Nonce too long for this instance")
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}
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if len(ciphertext) < e.tagSize {
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return nil, eaxError("Ciphertext shorter than tag length")
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}
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sep := len(ciphertext) - e.tagSize
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// Compute tag
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omacNonce := e.omacT(0, nonce)
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omacAdata := e.omacT(1, adata)
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omacCiphertext := e.omacT(2, ciphertext[:sep])
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tag := make([]byte, e.tagSize)
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for i := 0; i < e.tagSize; i++ {
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tag[i] = omacCiphertext[i] ^ omacNonce[i] ^ omacAdata[i]
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}
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// Compare tags
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if subtle.ConstantTimeCompare(ciphertext[sep:], tag) != 1 {
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return nil, eaxError("Tag authentication failed")
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}
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// Decrypt ciphertext
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ret, out := byteutil.SliceForAppend(dst, len(ciphertext))
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ctr := cipher.NewCTR(e.block, omacNonce)
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ctr.XORKeyStream(out, ciphertext[:sep])
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return ret[:sep], nil
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}
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// Tweakable OMAC - Calls OMAC_K([t]_n || plaintext)
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func (e *eax) omacT(t byte, plaintext []byte) []byte {
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blockSize := e.block.BlockSize()
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byteT := make([]byte, blockSize)
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byteT[blockSize-1] = t
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concat := append(byteT, plaintext...)
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return e.omac(concat)
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}
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func (e *eax) omac(plaintext []byte) []byte {
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blockSize := e.block.BlockSize()
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// L ← E_K(0^n); B ← 2L; P ← 4L
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L := make([]byte, blockSize)
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e.block.Encrypt(L, L)
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B := byteutil.GfnDouble(L)
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P := byteutil.GfnDouble(B)
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// CBC with IV = 0
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cbc := cipher.NewCBCEncrypter(e.block, make([]byte, blockSize))
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padded := e.pad(plaintext, B, P)
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cbcCiphertext := make([]byte, len(padded))
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cbc.CryptBlocks(cbcCiphertext, padded)
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return cbcCiphertext[len(cbcCiphertext)-blockSize:]
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}
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func (e *eax) pad(plaintext, B, P []byte) []byte {
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// if |M| in {n, 2n, 3n, ...}
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blockSize := e.block.BlockSize()
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if len(plaintext) != 0 && len(plaintext)%blockSize == 0 {
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return byteutil.RightXor(plaintext, B)
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}
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// else return (M || 1 || 0^(n−1−(|M| % n))) xor→ P
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ending := make([]byte, blockSize-len(plaintext)%blockSize)
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ending[0] = 0x80
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padded := append(plaintext, ending...)
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return byteutil.RightXor(padded, P)
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}
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func eaxError(err string) error {
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return errors.New("crypto/eax: " + err)
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}
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