mirror of
https://github.com/cheat/cheat.git
synced 2024-12-23 13:09:44 +01:00
80c91cbdee
Integrate `go-git` into the application, and use it to `git clone` cheatsheets when the installer runs. Previously, the installer required that `git` be installed on the system `PATH`, so this change has to big advantages: 1. It removes that system dependency on `git` 2. It paves the way for implementing the `--update` command Additionally, `cheat` now performs a `--depth=1` clone when installing cheatsheets, which should at least somewhat improve installation times (especially on slow network connections).
318 lines
9.4 KiB
Go
318 lines
9.4 KiB
Go
// Copyright (C) 2019 ProtonTech AG
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// Package ocb provides an implementation of the OCB (offset codebook) mode of
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// operation, as described in RFC-7253 of the IRTF and in Rogaway, Bellare,
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// Black and Krovetz - OCB: A BLOCK-CIPHER MODE OF OPERATION FOR EFFICIENT
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// AUTHENTICATED ENCRYPTION (2003).
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// Security considerations (from RFC-7253): A private key MUST NOT be used to
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// encrypt more than 2^48 blocks. Tag length should be at least 12 bytes (a
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// brute-force forging adversary succeeds after 2^{tag length} attempts). A
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// single key SHOULD NOT be used to decrypt ciphertext with different tag
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// lengths. Nonces need not be secret, but MUST NOT be reused.
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// This package only supports underlying block ciphers with 128-bit blocks,
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// such as AES-{128, 192, 256}, but may be extended to other sizes.
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package ocb
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import (
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"bytes"
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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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"math/bits"
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)
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type ocb struct {
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block cipher.Block
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tagSize int
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nonceSize int
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mask mask
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// Optimized en/decrypt: For each nonce N used to en/decrypt, the 'Ktop'
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// internal variable can be reused for en/decrypting with nonces sharing
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// all but the last 6 bits with N. The prefix of the first nonce used to
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// compute the new Ktop, and the Ktop value itself, are stored in
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// reusableKtop. If using incremental nonces, this saves one block cipher
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// call every 63 out of 64 OCB encryptions, and stores one nonce and one
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// output of the block cipher in memory only.
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reusableKtop reusableKtop
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}
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type mask struct {
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// L_*, L_$, (L_i)_{i ∈ N}
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lAst []byte
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lDol []byte
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L [][]byte
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}
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type reusableKtop struct {
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noncePrefix []byte
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Ktop []byte
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}
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const (
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defaultTagSize = 16
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defaultNonceSize = 15
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)
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const (
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enc = iota
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dec
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)
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func (o *ocb) NonceSize() int {
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return o.nonceSize
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}
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func (o *ocb) Overhead() int {
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return o.tagSize
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}
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// NewOCB returns an OCB instance with the given block cipher and default
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// tag and nonce sizes.
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func NewOCB(block cipher.Block) (cipher.AEAD, error) {
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return NewOCBWithNonceAndTagSize(block, defaultNonceSize, defaultTagSize)
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}
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// NewOCBWithNonceAndTagSize returns an OCB instance with the given block
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// cipher, nonce length, and tag length. Panics on zero nonceSize and
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// exceedingly long tag size.
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//
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// It is recommended to use at least 12 bytes as tag length.
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func NewOCBWithNonceAndTagSize(
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block cipher.Block, nonceSize, tagSize int) (cipher.AEAD, error) {
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if block.BlockSize() != 16 {
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return nil, ocbError("Block cipher must have 128-bit blocks")
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}
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if nonceSize < 1 {
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return nil, ocbError("Incorrect nonce length")
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}
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if nonceSize >= block.BlockSize() {
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return nil, ocbError("Nonce length exceeds blocksize - 1")
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}
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if tagSize > block.BlockSize() {
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return nil, ocbError("Custom tag length exceeds blocksize")
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}
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return &ocb{
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block: block,
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tagSize: tagSize,
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nonceSize: nonceSize,
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mask: initializeMaskTable(block),
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reusableKtop: reusableKtop{
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noncePrefix: nil,
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Ktop: nil,
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},
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}, nil
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}
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func (o *ocb) Seal(dst, nonce, plaintext, adata []byte) []byte {
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if len(nonce) > o.nonceSize {
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panic("crypto/ocb: Incorrect nonce length given to OCB")
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}
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ret, out := byteutil.SliceForAppend(dst, len(plaintext)+o.tagSize)
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o.crypt(enc, out, nonce, adata, plaintext)
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return ret
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}
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func (o *ocb) Open(dst, nonce, ciphertext, adata []byte) ([]byte, error) {
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if len(nonce) > o.nonceSize {
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panic("Nonce too long for this instance")
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}
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if len(ciphertext) < o.tagSize {
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return nil, ocbError("Ciphertext shorter than tag length")
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}
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sep := len(ciphertext) - o.tagSize
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ret, out := byteutil.SliceForAppend(dst, len(ciphertext))
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ciphertextData := ciphertext[:sep]
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tag := ciphertext[sep:]
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o.crypt(dec, out, nonce, adata, ciphertextData)
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if subtle.ConstantTimeCompare(ret[sep:], tag) == 1 {
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ret = ret[:sep]
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return ret, nil
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}
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for i := range out {
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out[i] = 0
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}
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return nil, ocbError("Tag authentication failed")
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}
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// On instruction enc (resp. dec), crypt is the encrypt (resp. decrypt)
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// function. It returns the resulting plain/ciphertext with the tag appended.
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func (o *ocb) crypt(instruction int, Y, nonce, adata, X []byte) []byte {
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//
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// Consider X as a sequence of 128-bit blocks
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//
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// Note: For encryption (resp. decryption), X is the plaintext (resp., the
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// ciphertext without the tag).
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blockSize := o.block.BlockSize()
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//
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// Nonce-dependent and per-encryption variables
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//
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// Zero out the last 6 bits of the nonce into truncatedNonce to see if Ktop
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// is already computed.
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truncatedNonce := make([]byte, len(nonce))
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copy(truncatedNonce, nonce)
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truncatedNonce[len(truncatedNonce)-1] &= 192
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Ktop := make([]byte, blockSize)
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if bytes.Equal(truncatedNonce, o.reusableKtop.noncePrefix) {
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Ktop = o.reusableKtop.Ktop
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} else {
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// Nonce = num2str(TAGLEN mod 128, 7) || zeros(120 - bitlen(N)) || 1 || N
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paddedNonce := append(make([]byte, blockSize-1-len(nonce)), 1)
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paddedNonce = append(paddedNonce, truncatedNonce...)
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paddedNonce[0] |= byte(((8 * o.tagSize) % (8 * blockSize)) << 1)
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// Last 6 bits of paddedNonce are already zero. Encrypt into Ktop
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paddedNonce[blockSize-1] &= 192
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Ktop = paddedNonce
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o.block.Encrypt(Ktop, Ktop)
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o.reusableKtop.noncePrefix = truncatedNonce
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o.reusableKtop.Ktop = Ktop
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}
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// Stretch = Ktop || ((lower half of Ktop) XOR (lower half of Ktop << 8))
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xorHalves := make([]byte, blockSize/2)
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byteutil.XorBytes(xorHalves, Ktop[:blockSize/2], Ktop[1:1+blockSize/2])
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stretch := append(Ktop, xorHalves...)
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bottom := int(nonce[len(nonce)-1] & 63)
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offset := make([]byte, len(stretch))
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byteutil.ShiftNBytesLeft(offset, stretch, bottom)
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offset = offset[:blockSize]
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//
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// Process any whole blocks
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//
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// Note: For encryption Y is ciphertext || tag, for decryption Y is
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// plaintext || tag.
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checksum := make([]byte, blockSize)
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m := len(X) / blockSize
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for i := 0; i < m; i++ {
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index := bits.TrailingZeros(uint(i + 1))
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if len(o.mask.L)-1 < index {
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o.mask.extendTable(index)
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}
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byteutil.XorBytesMut(offset, o.mask.L[bits.TrailingZeros(uint(i+1))])
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blockX := X[i*blockSize : (i+1)*blockSize]
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blockY := Y[i*blockSize : (i+1)*blockSize]
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byteutil.XorBytes(blockY, blockX, offset)
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switch instruction {
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case enc:
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o.block.Encrypt(blockY, blockY)
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byteutil.XorBytesMut(blockY, offset)
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byteutil.XorBytesMut(checksum, blockX)
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case dec:
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o.block.Decrypt(blockY, blockY)
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byteutil.XorBytesMut(blockY, offset)
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byteutil.XorBytesMut(checksum, blockY)
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}
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}
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//
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// Process any final partial block and compute raw tag
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//
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tag := make([]byte, blockSize)
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if len(X)%blockSize != 0 {
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byteutil.XorBytesMut(offset, o.mask.lAst)
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pad := make([]byte, blockSize)
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o.block.Encrypt(pad, offset)
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chunkX := X[blockSize*m:]
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chunkY := Y[blockSize*m : len(X)]
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byteutil.XorBytes(chunkY, chunkX, pad[:len(chunkX)])
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// P_* || bit(1) || zeroes(127) - len(P_*)
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switch instruction {
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case enc:
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paddedY := append(chunkX, byte(128))
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paddedY = append(paddedY, make([]byte, blockSize-len(chunkX)-1)...)
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byteutil.XorBytesMut(checksum, paddedY)
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case dec:
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paddedX := append(chunkY, byte(128))
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paddedX = append(paddedX, make([]byte, blockSize-len(chunkY)-1)...)
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byteutil.XorBytesMut(checksum, paddedX)
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}
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byteutil.XorBytes(tag, checksum, offset)
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byteutil.XorBytesMut(tag, o.mask.lDol)
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o.block.Encrypt(tag, tag)
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byteutil.XorBytesMut(tag, o.hash(adata))
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copy(Y[blockSize*m+len(chunkY):], tag[:o.tagSize])
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} else {
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byteutil.XorBytes(tag, checksum, offset)
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byteutil.XorBytesMut(tag, o.mask.lDol)
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o.block.Encrypt(tag, tag)
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byteutil.XorBytesMut(tag, o.hash(adata))
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copy(Y[blockSize*m:], tag[:o.tagSize])
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}
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return Y
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}
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// This hash function is used to compute the tag. Per design, on empty input it
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// returns a slice of zeros, of the same length as the underlying block cipher
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// block size.
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func (o *ocb) hash(adata []byte) []byte {
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//
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// Consider A as a sequence of 128-bit blocks
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//
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A := make([]byte, len(adata))
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copy(A, adata)
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blockSize := o.block.BlockSize()
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//
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// Process any whole blocks
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//
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sum := make([]byte, blockSize)
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offset := make([]byte, blockSize)
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m := len(A) / blockSize
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for i := 0; i < m; i++ {
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chunk := A[blockSize*i : blockSize*(i+1)]
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index := bits.TrailingZeros(uint(i + 1))
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// If the mask table is too short
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if len(o.mask.L)-1 < index {
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o.mask.extendTable(index)
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}
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byteutil.XorBytesMut(offset, o.mask.L[index])
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byteutil.XorBytesMut(chunk, offset)
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o.block.Encrypt(chunk, chunk)
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byteutil.XorBytesMut(sum, chunk)
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}
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//
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// Process any final partial block; compute final hash value
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//
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if len(A)%blockSize != 0 {
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byteutil.XorBytesMut(offset, o.mask.lAst)
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// Pad block with 1 || 0 ^ 127 - bitlength(a)
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ending := make([]byte, blockSize-len(A)%blockSize)
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ending[0] = 0x80
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encrypted := append(A[blockSize*m:], ending...)
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byteutil.XorBytesMut(encrypted, offset)
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o.block.Encrypt(encrypted, encrypted)
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byteutil.XorBytesMut(sum, encrypted)
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}
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return sum
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}
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func initializeMaskTable(block cipher.Block) mask {
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//
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// Key-dependent variables
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//
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lAst := make([]byte, block.BlockSize())
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block.Encrypt(lAst, lAst)
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lDol := byteutil.GfnDouble(lAst)
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L := make([][]byte, 1)
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L[0] = byteutil.GfnDouble(lDol)
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return mask{
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lAst: lAst,
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lDol: lDol,
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L: L,
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}
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}
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// Extends the L array of mask m up to L[limit], with L[i] = GfnDouble(L[i-1])
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func (m *mask) extendTable(limit int) {
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for i := len(m.L); i <= limit; i++ {
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m.L = append(m.L, byteutil.GfnDouble(m.L[i-1]))
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}
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}
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func ocbError(err string) error {
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return errors.New("crypto/ocb: " + err)
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}
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