287 lines
7.0 KiB
Go
287 lines
7.0 KiB
Go
// Package blake3 implements the BLAKE3 cryptographic hash function.
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package blake3 // import "lukechampine.com/blake3"
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import (
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"encoding/binary"
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"errors"
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"hash"
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"io"
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"math"
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"math/bits"
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)
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const (
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flagChunkStart = 1 << iota
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flagChunkEnd
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flagParent
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flagRoot
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flagKeyedHash
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flagDeriveKeyContext
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flagDeriveKeyMaterial
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blockSize = 64
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chunkSize = 1024
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)
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var iv = [8]uint32{
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0x6A09E667, 0xBB67AE85, 0x3C6EF372, 0xA54FF53A,
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0x510E527F, 0x9B05688C, 0x1F83D9AB, 0x5BE0CD19,
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}
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// A node represents a chunk or parent in the BLAKE3 Merkle tree.
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type node struct {
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cv [8]uint32 // chaining value from previous node
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block [16]uint32
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counter uint64
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blockLen uint32
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flags uint32
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}
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// parentNode returns a node that incorporates the chaining values of two child
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// nodes.
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func parentNode(left, right [8]uint32, key [8]uint32, flags uint32) node {
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n := node{
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cv: key,
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counter: 0, // counter is reset for parents
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blockLen: blockSize, // block is full
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flags: flags | flagParent,
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}
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copy(n.block[:8], left[:])
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copy(n.block[8:], right[:])
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return n
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}
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// Hasher implements hash.Hash.
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type Hasher struct {
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key [8]uint32
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flags uint32
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size int // output size, for Sum
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// log(n) set of Merkle subtree roots, at most one per height.
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stack [51][8]uint32 // 2^51 * 8 * chunkSize = 2^64
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counter uint64 // number of buffers hashed; also serves as a bit vector indicating which stack elems are occupied
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buf [8 * chunkSize]byte
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buflen int
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}
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func (h *Hasher) hasSubtreeAtHeight(i int) bool {
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return h.counter&(1<<i) != 0
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}
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func (h *Hasher) pushSubtree(cv [8]uint32) {
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// seek to first open stack slot, merging subtrees as we go
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i := 0
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for h.hasSubtreeAtHeight(i) {
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cv = chainingValue(parentNode(h.stack[i], cv, h.key, h.flags))
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i++
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}
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h.stack[i] = cv
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h.counter++
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}
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// rootNode computes the root of the Merkle tree. It does not modify the
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// stack.
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func (h *Hasher) rootNode() node {
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n := compressBuffer(&h.buf, h.buflen, &h.key, h.counter*8, h.flags)
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for i := bits.TrailingZeros64(h.counter); i < bits.Len64(h.counter); i++ {
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if h.hasSubtreeAtHeight(i) {
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n = parentNode(h.stack[i], chainingValue(n), h.key, h.flags)
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}
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}
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n.flags |= flagRoot
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return n
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}
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// Write implements hash.Hash.
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func (h *Hasher) Write(p []byte) (int, error) {
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lenp := len(p)
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for len(p) > 0 {
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if h.buflen == len(h.buf) {
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n := compressBuffer(&h.buf, h.buflen, &h.key, h.counter*8, h.flags)
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h.pushSubtree(chainingValue(n))
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h.buflen = 0
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}
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n := copy(h.buf[h.buflen:], p)
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h.buflen += n
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p = p[n:]
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}
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return lenp, nil
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}
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// Sum implements hash.Hash.
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func (h *Hasher) Sum(b []byte) (sum []byte) {
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// We need to append h.Size() bytes to b. Reuse b's capacity if possible;
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// otherwise, allocate a new slice.
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if total := len(b) + h.Size(); cap(b) >= total {
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sum = b[:total]
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} else {
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sum = make([]byte, total)
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copy(sum, b)
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}
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// Read into the appended portion of sum
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h.XOF().Read(sum[len(b):])
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return
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}
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// Reset implements hash.Hash.
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func (h *Hasher) Reset() {
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h.counter = 0
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h.buflen = 0
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}
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// BlockSize implements hash.Hash.
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func (h *Hasher) BlockSize() int { return 64 }
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// Size implements hash.Hash.
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func (h *Hasher) Size() int { return h.size }
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// XOF returns an OutputReader initialized with the current hash state.
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func (h *Hasher) XOF() *OutputReader {
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return &OutputReader{
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n: h.rootNode(),
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}
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}
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func newHasher(key [8]uint32, flags uint32, size int) *Hasher {
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return &Hasher{
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key: key,
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flags: flags,
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size: size,
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}
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}
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// New returns a Hasher for the specified size and key. If key is nil, the hash
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// is unkeyed. Otherwise, len(key) must be 32.
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func New(size int, key []byte) *Hasher {
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if key == nil {
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return newHasher(iv, 0, size)
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}
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var keyWords [8]uint32
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for i := range keyWords {
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keyWords[i] = binary.LittleEndian.Uint32(key[i*4:])
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}
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return newHasher(keyWords, flagKeyedHash, size)
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}
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// Sum256 and Sum512 always use the same hasher state, so we can save some time
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// when hashing small inputs by constructing the hasher ahead of time.
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var defaultHasher = New(0, nil)
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// Sum256 returns the unkeyed BLAKE3 hash of b, truncated to 256 bits.
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func Sum256(b []byte) (out [32]byte) {
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out512 := Sum512(b)
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copy(out[:], out512[:])
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return
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}
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// Sum512 returns the unkeyed BLAKE3 hash of b, truncated to 512 bits.
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func Sum512(b []byte) (out [64]byte) {
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var n node
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if len(b) <= blockSize {
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hashBlock(&out, b)
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return
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} else if len(b) <= chunkSize {
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n = compressChunk(b, &iv, 0, 0)
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n.flags |= flagRoot
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} else {
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h := *defaultHasher
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h.Write(b)
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n = h.rootNode()
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}
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wordsToBytes(compressNode(n), &out)
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return
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}
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// DeriveKey derives a subkey from ctx and srcKey. ctx should be hardcoded,
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// globally unique, and application-specific. A good format for ctx strings is:
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//
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// [application] [commit timestamp] [purpose]
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//
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// e.g.:
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//
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// example.com 2019-12-25 16:18:03 session tokens v1
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//
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// The purpose of these requirements is to ensure that an attacker cannot trick
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// two different applications into using the same context string.
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func DeriveKey(subKey []byte, ctx string, srcKey []byte) {
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// construct the derivation Hasher
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const derivationIVLen = 32
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h := newHasher(iv, flagDeriveKeyContext, 32)
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h.Write([]byte(ctx))
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derivationIV := h.Sum(make([]byte, 0, derivationIVLen))
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var ivWords [8]uint32
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for i := range ivWords {
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ivWords[i] = binary.LittleEndian.Uint32(derivationIV[i*4:])
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}
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h = newHasher(ivWords, flagDeriveKeyMaterial, 0)
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// derive the subKey
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h.Write(srcKey)
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h.XOF().Read(subKey)
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}
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// An OutputReader produces an seekable stream of 2^64 - 1 pseudorandom output
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// bytes.
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type OutputReader struct {
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n node
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block [blockSize]byte
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off uint64
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}
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// Read implements io.Reader. Callers may assume that Read returns len(p), nil
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// unless the read would extend beyond the end of the stream.
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func (or *OutputReader) Read(p []byte) (int, error) {
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if or.off == math.MaxUint64 {
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return 0, io.EOF
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} else if rem := math.MaxUint64 - or.off; uint64(len(p)) > rem {
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p = p[:rem]
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}
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lenp := len(p)
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for len(p) > 0 {
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if or.off%blockSize == 0 {
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or.n.counter = or.off / blockSize
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wordsToBytes(compressNode(or.n), &or.block)
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}
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n := copy(p, or.block[or.off%blockSize:])
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p = p[n:]
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or.off += uint64(n)
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}
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return lenp, nil
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}
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// Seek implements io.Seeker.
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func (or *OutputReader) Seek(offset int64, whence int) (int64, error) {
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off := or.off
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switch whence {
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case io.SeekStart:
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if offset < 0 {
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return 0, errors.New("seek position cannot be negative")
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}
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off = uint64(offset)
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case io.SeekCurrent:
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if offset < 0 {
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if uint64(-offset) > off {
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return 0, errors.New("seek position cannot be negative")
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}
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off -= uint64(-offset)
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} else {
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off += uint64(offset)
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}
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case io.SeekEnd:
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off = uint64(offset) - 1
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default:
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panic("invalid whence")
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}
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or.off = off
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or.n.counter = uint64(off) / blockSize
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if or.off%blockSize != 0 {
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wordsToBytes(compressNode(or.n), &or.block)
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}
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// NOTE: or.off >= 2^63 will result in a negative return value.
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// Nothing we can do about this.
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return int64(or.off), nil
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}
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// ensure that Hasher implements hash.Hash
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var _ hash.Hash = (*Hasher)(nil)
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