mirror of
https://github.com/ceph/ceph-csi.git
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7b663279bf
Bumps [k8s.io/kubernetes](https://github.com/kubernetes/kubernetes) from 1.25.0 to 1.25.3. - [Release notes](https://github.com/kubernetes/kubernetes/releases) - [Commits](https://github.com/kubernetes/kubernetes/compare/v1.25.0...v1.25.3) --- updated-dependencies: - dependency-name: k8s.io/kubernetes dependency-type: direct:production update-type: version-update:semver-patch ... Signed-off-by: dependabot[bot] <support@github.com>
284 lines
9.2 KiB
Go
284 lines
9.2 KiB
Go
// Copyright 2017 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Package argon2 implements the key derivation function Argon2.
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// Argon2 was selected as the winner of the Password Hashing Competition and can
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// be used to derive cryptographic keys from passwords.
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//
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// For a detailed specification of Argon2 see [1].
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//
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// If you aren't sure which function you need, use Argon2id (IDKey) and
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// the parameter recommendations for your scenario.
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//
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// # Argon2i
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//
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// Argon2i (implemented by Key) is the side-channel resistant version of Argon2.
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// It uses data-independent memory access, which is preferred for password
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// hashing and password-based key derivation. Argon2i requires more passes over
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// memory than Argon2id to protect from trade-off attacks. The recommended
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// parameters (taken from [2]) for non-interactive operations are time=3 and to
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// use the maximum available memory.
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//
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// # Argon2id
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//
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// Argon2id (implemented by IDKey) is a hybrid version of Argon2 combining
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// Argon2i and Argon2d. It uses data-independent memory access for the first
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// half of the first iteration over the memory and data-dependent memory access
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// for the rest. Argon2id is side-channel resistant and provides better brute-
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// force cost savings due to time-memory tradeoffs than Argon2i. The recommended
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// parameters for non-interactive operations (taken from [2]) are time=1 and to
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// use the maximum available memory.
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//
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// [1] https://github.com/P-H-C/phc-winner-argon2/blob/master/argon2-specs.pdf
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// [2] https://tools.ietf.org/html/draft-irtf-cfrg-argon2-03#section-9.3
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package argon2
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import (
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"encoding/binary"
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"sync"
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"golang.org/x/crypto/blake2b"
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)
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// The Argon2 version implemented by this package.
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const Version = 0x13
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const (
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argon2d = iota
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argon2i
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argon2id
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)
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// Key derives a key from the password, salt, and cost parameters using Argon2i
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// returning a byte slice of length keyLen that can be used as cryptographic
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// key. The CPU cost and parallelism degree must be greater than zero.
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//
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// For example, you can get a derived key for e.g. AES-256 (which needs a
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// 32-byte key) by doing:
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//
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// key := argon2.Key([]byte("some password"), salt, 3, 32*1024, 4, 32)
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//
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// The draft RFC recommends[2] time=3, and memory=32*1024 is a sensible number.
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// If using that amount of memory (32 MB) is not possible in some contexts then
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// the time parameter can be increased to compensate.
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//
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// The time parameter specifies the number of passes over the memory and the
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// memory parameter specifies the size of the memory in KiB. For example
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// memory=32*1024 sets the memory cost to ~32 MB. The number of threads can be
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// adjusted to the number of available CPUs. The cost parameters should be
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// increased as memory latency and CPU parallelism increases. Remember to get a
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// good random salt.
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func Key(password, salt []byte, time, memory uint32, threads uint8, keyLen uint32) []byte {
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return deriveKey(argon2i, password, salt, nil, nil, time, memory, threads, keyLen)
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}
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// IDKey derives a key from the password, salt, and cost parameters using
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// Argon2id returning a byte slice of length keyLen that can be used as
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// cryptographic key. The CPU cost and parallelism degree must be greater than
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// zero.
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//
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// For example, you can get a derived key for e.g. AES-256 (which needs a
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// 32-byte key) by doing:
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//
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// key := argon2.IDKey([]byte("some password"), salt, 1, 64*1024, 4, 32)
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//
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// The draft RFC recommends[2] time=1, and memory=64*1024 is a sensible number.
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// If using that amount of memory (64 MB) is not possible in some contexts then
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// the time parameter can be increased to compensate.
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//
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// The time parameter specifies the number of passes over the memory and the
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// memory parameter specifies the size of the memory in KiB. For example
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// memory=64*1024 sets the memory cost to ~64 MB. The number of threads can be
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// adjusted to the numbers of available CPUs. The cost parameters should be
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// increased as memory latency and CPU parallelism increases. Remember to get a
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// good random salt.
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func IDKey(password, salt []byte, time, memory uint32, threads uint8, keyLen uint32) []byte {
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return deriveKey(argon2id, password, salt, nil, nil, time, memory, threads, keyLen)
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}
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func deriveKey(mode int, password, salt, secret, data []byte, time, memory uint32, threads uint8, keyLen uint32) []byte {
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if time < 1 {
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panic("argon2: number of rounds too small")
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}
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if threads < 1 {
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panic("argon2: parallelism degree too low")
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}
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h0 := initHash(password, salt, secret, data, time, memory, uint32(threads), keyLen, mode)
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memory = memory / (syncPoints * uint32(threads)) * (syncPoints * uint32(threads))
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if memory < 2*syncPoints*uint32(threads) {
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memory = 2 * syncPoints * uint32(threads)
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}
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B := initBlocks(&h0, memory, uint32(threads))
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processBlocks(B, time, memory, uint32(threads), mode)
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return extractKey(B, memory, uint32(threads), keyLen)
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}
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const (
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blockLength = 128
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syncPoints = 4
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)
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type block [blockLength]uint64
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func initHash(password, salt, key, data []byte, time, memory, threads, keyLen uint32, mode int) [blake2b.Size + 8]byte {
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var (
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h0 [blake2b.Size + 8]byte
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params [24]byte
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tmp [4]byte
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)
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b2, _ := blake2b.New512(nil)
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binary.LittleEndian.PutUint32(params[0:4], threads)
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binary.LittleEndian.PutUint32(params[4:8], keyLen)
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binary.LittleEndian.PutUint32(params[8:12], memory)
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binary.LittleEndian.PutUint32(params[12:16], time)
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binary.LittleEndian.PutUint32(params[16:20], uint32(Version))
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binary.LittleEndian.PutUint32(params[20:24], uint32(mode))
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b2.Write(params[:])
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binary.LittleEndian.PutUint32(tmp[:], uint32(len(password)))
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b2.Write(tmp[:])
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b2.Write(password)
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binary.LittleEndian.PutUint32(tmp[:], uint32(len(salt)))
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b2.Write(tmp[:])
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b2.Write(salt)
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binary.LittleEndian.PutUint32(tmp[:], uint32(len(key)))
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b2.Write(tmp[:])
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b2.Write(key)
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binary.LittleEndian.PutUint32(tmp[:], uint32(len(data)))
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b2.Write(tmp[:])
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b2.Write(data)
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b2.Sum(h0[:0])
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return h0
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}
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func initBlocks(h0 *[blake2b.Size + 8]byte, memory, threads uint32) []block {
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var block0 [1024]byte
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B := make([]block, memory)
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for lane := uint32(0); lane < threads; lane++ {
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j := lane * (memory / threads)
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binary.LittleEndian.PutUint32(h0[blake2b.Size+4:], lane)
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binary.LittleEndian.PutUint32(h0[blake2b.Size:], 0)
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blake2bHash(block0[:], h0[:])
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for i := range B[j+0] {
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B[j+0][i] = binary.LittleEndian.Uint64(block0[i*8:])
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}
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binary.LittleEndian.PutUint32(h0[blake2b.Size:], 1)
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blake2bHash(block0[:], h0[:])
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for i := range B[j+1] {
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B[j+1][i] = binary.LittleEndian.Uint64(block0[i*8:])
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}
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}
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return B
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}
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func processBlocks(B []block, time, memory, threads uint32, mode int) {
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lanes := memory / threads
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segments := lanes / syncPoints
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processSegment := func(n, slice, lane uint32, wg *sync.WaitGroup) {
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var addresses, in, zero block
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if mode == argon2i || (mode == argon2id && n == 0 && slice < syncPoints/2) {
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in[0] = uint64(n)
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in[1] = uint64(lane)
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in[2] = uint64(slice)
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in[3] = uint64(memory)
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in[4] = uint64(time)
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in[5] = uint64(mode)
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}
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index := uint32(0)
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if n == 0 && slice == 0 {
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index = 2 // we have already generated the first two blocks
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if mode == argon2i || mode == argon2id {
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in[6]++
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processBlock(&addresses, &in, &zero)
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processBlock(&addresses, &addresses, &zero)
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}
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}
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offset := lane*lanes + slice*segments + index
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var random uint64
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for index < segments {
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prev := offset - 1
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if index == 0 && slice == 0 {
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prev += lanes // last block in lane
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}
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if mode == argon2i || (mode == argon2id && n == 0 && slice < syncPoints/2) {
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if index%blockLength == 0 {
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in[6]++
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processBlock(&addresses, &in, &zero)
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processBlock(&addresses, &addresses, &zero)
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}
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random = addresses[index%blockLength]
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} else {
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random = B[prev][0]
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}
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newOffset := indexAlpha(random, lanes, segments, threads, n, slice, lane, index)
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processBlockXOR(&B[offset], &B[prev], &B[newOffset])
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index, offset = index+1, offset+1
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}
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wg.Done()
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}
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for n := uint32(0); n < time; n++ {
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for slice := uint32(0); slice < syncPoints; slice++ {
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var wg sync.WaitGroup
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for lane := uint32(0); lane < threads; lane++ {
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wg.Add(1)
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go processSegment(n, slice, lane, &wg)
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}
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wg.Wait()
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}
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}
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}
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func extractKey(B []block, memory, threads, keyLen uint32) []byte {
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lanes := memory / threads
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for lane := uint32(0); lane < threads-1; lane++ {
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for i, v := range B[(lane*lanes)+lanes-1] {
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B[memory-1][i] ^= v
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}
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}
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var block [1024]byte
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for i, v := range B[memory-1] {
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binary.LittleEndian.PutUint64(block[i*8:], v)
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}
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key := make([]byte, keyLen)
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blake2bHash(key, block[:])
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return key
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}
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func indexAlpha(rand uint64, lanes, segments, threads, n, slice, lane, index uint32) uint32 {
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refLane := uint32(rand>>32) % threads
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if n == 0 && slice == 0 {
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refLane = lane
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}
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m, s := 3*segments, ((slice+1)%syncPoints)*segments
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if lane == refLane {
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m += index
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}
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if n == 0 {
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m, s = slice*segments, 0
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if slice == 0 || lane == refLane {
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m += index
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}
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}
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if index == 0 || lane == refLane {
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m--
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}
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return phi(rand, uint64(m), uint64(s), refLane, lanes)
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}
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func phi(rand, m, s uint64, lane, lanes uint32) uint32 {
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p := rand & 0xFFFFFFFF
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p = (p * p) >> 32
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p = (p * m) >> 32
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return lane*lanes + uint32((s+m-(p+1))%uint64(lanes))
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}
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