xs/vendor/golang.org/x/crypto/tea/cipher.go

// Copyright 2015 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 tea implements the TEA algorithm, as defined in Needham and
// Wheeler's 1994 technical report, “TEA, a Tiny Encryption Algorithm”. See
// http://www.cix.co.uk/~klockstone/tea.pdf for details.
//
// TEA is a legacy cipher and its short block size makes it vulnerable to
// birthday bound attacks (see https://sweet32.info). It should only be used
// where compatibility with legacy systems, not security, is the goal.
//
// Deprecated: any new system should use AES (from crypto/aes, if necessary in
// an AEAD mode like crypto/cipher.NewGCM) or XChaCha20-Poly1305 (from
// golang.org/x/crypto/chacha20poly1305).
package tea

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

const (
	// BlockSize is the size of a TEA block, in bytes.
	BlockSize = 8

	// KeySize is the size of a TEA key, in bytes.
	KeySize = 16

	// delta is the TEA key schedule constant.
	delta = 0x9e3779b9

	// numRounds is the standard number of rounds in TEA.
	numRounds = 64
)

// tea is an instance of the TEA cipher with a particular key.
type tea struct {
	key    [16]byte
	rounds int
}

// NewCipher returns an instance of the TEA cipher with the standard number of
// rounds. The key argument must be 16 bytes long.
func NewCipher(key []byte) (cipher.Block, error) {
	return NewCipherWithRounds(key, numRounds)
}

// NewCipherWithRounds returns an instance of the TEA cipher with a given
// number of rounds, which must be even. The key argument must be 16 bytes
// long.
func NewCipherWithRounds(key []byte, rounds int) (cipher.Block, error) {
	if len(key) != 16 {
		return nil, errors.New("tea: incorrect key size")
	}

	if rounds&1 != 0 {
		return nil, errors.New("tea: odd number of rounds specified")
	}

	c := &tea{
		rounds: rounds,
	}
	copy(c.key[:], key)

	return c, nil
}

// BlockSize returns the TEA block size, which is eight bytes. It is necessary
// to satisfy the Block interface in the package "crypto/cipher".
func (*tea) BlockSize() int {
	return BlockSize
}

// Encrypt encrypts the 8 byte buffer src using the key in t and stores the
// result in dst. Note that for amounts of data larger than a block, it is not
// safe to just call Encrypt on successive blocks; instead, use an encryption
// mode like CBC (see crypto/cipher/cbc.go).
func (t *tea) Encrypt(dst, src []byte) {
	e := binary.BigEndian
	v0, v1 := e.Uint32(src), e.Uint32(src[4:])
	k0, k1, k2, k3 := e.Uint32(t.key[0:]), e.Uint32(t.key[4:]), e.Uint32(t.key[8:]), e.Uint32(t.key[12:])

	sum := uint32(0)
	delta := uint32(delta)

	for i := 0; i < t.rounds/2; i++ {
		sum += delta
		v0 += ((v1 << 4) + k0) ^ (v1 + sum) ^ ((v1 >> 5) + k1)
		v1 += ((v0 << 4) + k2) ^ (v0 + sum) ^ ((v0 >> 5) + k3)
	}

	e.PutUint32(dst, v0)
	e.PutUint32(dst[4:], v1)
}

// Decrypt decrypts the 8 byte buffer src using the key in t and stores the
// result in dst.
func (t *tea) Decrypt(dst, src []byte) {
	e := binary.BigEndian
	v0, v1 := e.Uint32(src), e.Uint32(src[4:])
	k0, k1, k2, k3 := e.Uint32(t.key[0:]), e.Uint32(t.key[4:]), e.Uint32(t.key[8:]), e.Uint32(t.key[12:])

	delta := uint32(delta)
	sum := delta * uint32(t.rounds/2) // in general, sum = delta * n

	for i := 0; i < t.rounds/2; i++ {
		v1 -= ((v0 << 4) + k2) ^ (v0 + sum) ^ ((v0 >> 5) + k3)
		v0 -= ((v1 << 4) + k0) ^ (v1 + sum) ^ ((v1 >> 5) + k1)
		sum -= delta
	}

	e.PutUint32(dst, v0)
	e.PutUint32(dst[4:], v1)
}
1/3 Updated Makefile to allow VENDOR flag (adds -vendor to version string) 2/3 Added vendor/ dir to lock down dependent pkg versions. The author of git.schwanenlied.me/yawning/{chacha20,newhope,kyber}.git has copied their repos to gitlab.com/yawning/ but some imports of chacha20 from newhope still inconsistently refer to git.schwanenlied.me/, breaking build. Licenses for chacha20 also changed from CC0 to AGPL, which may or may not be an issue. Until the two aforementioned issues are resolved, locking to last-good versions is probably the best way forward for now. To build with vendored deps, use make VENDOR=1 clean all 3/3 Moved body of CI push script into bacillus/ 2020-01-29 21:25:14 +00:00			`// Copyright 2015 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 tea implements the TEA algorithm, as defined in Needham and`
			`// Wheeler's 1994 technical report, “TEA, a Tiny Encryption Algorithm”. See`
			`// http://www.cix.co.uk/~klockstone/tea.pdf for details.`
			`//`
			`// TEA is a legacy cipher and its short block size makes it vulnerable to`
			`// birthday bound attacks (see https://sweet32.info). It should only be used`
			`// where compatibility with legacy systems, not security, is the goal.`
			`//`
			`// Deprecated: any new system should use AES (from crypto/aes, if necessary in`
			`// an AEAD mode like crypto/cipher.NewGCM) or XChaCha20-Poly1305 (from`
			`// golang.org/x/crypto/chacha20poly1305).`
			`package tea`

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

			`const (`
			`// BlockSize is the size of a TEA block, in bytes.`
			`BlockSize = 8`

			`// KeySize is the size of a TEA key, in bytes.`
			`KeySize = 16`

			`// delta is the TEA key schedule constant.`
			`delta = 0x9e3779b9`

			`// numRounds is the standard number of rounds in TEA.`
			`numRounds = 64`
			`)`

			`// tea is an instance of the TEA cipher with a particular key.`
			`type tea struct {`
			`key [16]byte`
			`rounds int`
			`}`

			`// NewCipher returns an instance of the TEA cipher with the standard number of`
			`// rounds. The key argument must be 16 bytes long.`
			`func NewCipher(key []byte) (cipher.Block, error) {`
			`return NewCipherWithRounds(key, numRounds)`
			`}`

			`// NewCipherWithRounds returns an instance of the TEA cipher with a given`
			`// number of rounds, which must be even. The key argument must be 16 bytes`
			`// long.`
			`func NewCipherWithRounds(key []byte, rounds int) (cipher.Block, error) {`
			`if len(key) != 16 {`
			`return nil, errors.New("tea: incorrect key size")`
			`}`

			`if rounds&1 != 0 {`
			`return nil, errors.New("tea: odd number of rounds specified")`
			`}`

			`c := &tea{`
			`rounds: rounds,`
			`}`
			`copy(c.key[:], key)`

			`return c, nil`
			`}`

			`// BlockSize returns the TEA block size, which is eight bytes. It is necessary`
			`// to satisfy the Block interface in the package "crypto/cipher".`
			`func (*tea) BlockSize() int {`
			`return BlockSize`
			`}`

			`// Encrypt encrypts the 8 byte buffer src using the key in t and stores the`
			`// result in dst. Note that for amounts of data larger than a block, it is not`
			`// safe to just call Encrypt on successive blocks; instead, use an encryption`
			`// mode like CBC (see crypto/cipher/cbc.go).`
			`func (t *tea) Encrypt(dst, src []byte) {`
			`e := binary.BigEndian`
			`v0, v1 := e.Uint32(src), e.Uint32(src[4:])`
			`k0, k1, k2, k3 := e.Uint32(t.key[0:]), e.Uint32(t.key[4:]), e.Uint32(t.key[8:]), e.Uint32(t.key[12:])`

			`sum := uint32(0)`
			`delta := uint32(delta)`

			`for i := 0; i < t.rounds/2; i++ {`
			`sum += delta`
			`v0 += ((v1 << 4) + k0) ^ (v1 + sum) ^ ((v1 >> 5) + k1)`
			`v1 += ((v0 << 4) + k2) ^ (v0 + sum) ^ ((v0 >> 5) + k3)`
			`}`

			`e.PutUint32(dst, v0)`
			`e.PutUint32(dst[4:], v1)`
			`}`

			`// Decrypt decrypts the 8 byte buffer src using the key in t and stores the`
			`// result in dst.`
			`func (t *tea) Decrypt(dst, src []byte) {`
			`e := binary.BigEndian`
			`v0, v1 := e.Uint32(src), e.Uint32(src[4:])`
			`k0, k1, k2, k3 := e.Uint32(t.key[0:]), e.Uint32(t.key[4:]), e.Uint32(t.key[8:]), e.Uint32(t.key[12:])`

			`delta := uint32(delta)`
			`sum := delta * uint32(t.rounds/2) // in general, sum = delta * n`

			`for i := 0; i < t.rounds/2; i++ {`
			`v1 -= ((v0 << 4) + k2) ^ (v0 + sum) ^ ((v0 >> 5) + k3)`
			`v0 -= ((v1 << 4) + k0) ^ (v1 + sum) ^ ((v1 >> 5) + k1)`
			`sum -= delta`
			`}`

			`e.PutUint32(dst, v0)`
			`e.PutUint32(dst[4:], v1)`
			`}`