263 lines
7.7 KiB
Go
263 lines
7.7 KiB
Go
// Copyright (c) 2013-2014 The btcsuite developers
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// Copyright (c) 2015-2020 The Decred developers
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// Use of this source code is governed by an ISC
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// license that can be found in the LICENSE file.
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package secp256k1
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import (
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"bytes"
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"crypto/sha256"
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"hash"
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)
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// References:
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// [GECC]: Guide to Elliptic Curve Cryptography (Hankerson, Menezes, Vanstone)
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//
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// [ISO/IEC 8825-1]: Information technology — ASN.1 encoding rules:
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// Specification of Basic Encoding Rules (BER), Canonical Encoding Rules
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// (CER) and Distinguished Encoding Rules (DER)
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//
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// [SEC1]: Elliptic Curve Cryptography (May 31, 2009, Version 2.0)
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// https://www.secg.org/sec1-v2.pdf
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var (
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// singleZero is used during RFC6979 nonce generation. It is provided
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// here to avoid the need to create it multiple times.
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singleZero = []byte{0x00}
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// zeroInitializer is used during RFC6979 nonce generation. It is provided
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// here to avoid the need to create it multiple times.
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zeroInitializer = bytes.Repeat([]byte{0x00}, sha256.BlockSize)
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// singleOne is used during RFC6979 nonce generation. It is provided
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// here to avoid the need to create it multiple times.
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singleOne = []byte{0x01}
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// oneInitializer is used during RFC6979 nonce generation. It is provided
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// here to avoid the need to create it multiple times.
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oneInitializer = bytes.Repeat([]byte{0x01}, sha256.Size)
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)
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// hmacsha256 implements a resettable version of HMAC-SHA256.
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type hmacsha256 struct {
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inner, outer hash.Hash
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ipad, opad [sha256.BlockSize]byte
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}
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// Write adds data to the running hash.
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func (h *hmacsha256) Write(p []byte) {
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h.inner.Write(p)
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}
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// initKey initializes the HMAC-SHA256 instance to the provided key.
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func (h *hmacsha256) initKey(key []byte) {
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// Hash the key if it is too large.
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if len(key) > sha256.BlockSize {
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h.outer.Write(key)
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key = h.outer.Sum(nil)
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}
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copy(h.ipad[:], key)
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copy(h.opad[:], key)
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for i := range h.ipad {
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h.ipad[i] ^= 0x36
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}
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for i := range h.opad {
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h.opad[i] ^= 0x5c
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}
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h.inner.Write(h.ipad[:])
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}
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// ResetKey resets the HMAC-SHA256 to its initial state and then initializes it
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// with the provided key. It is equivalent to creating a new instance with the
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// provided key without allocating more memory.
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func (h *hmacsha256) ResetKey(key []byte) {
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h.inner.Reset()
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h.outer.Reset()
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copy(h.ipad[:], zeroInitializer)
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copy(h.opad[:], zeroInitializer)
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h.initKey(key)
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}
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// Resets the HMAC-SHA256 to its initial state using the current key.
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func (h *hmacsha256) Reset() {
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h.inner.Reset()
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h.inner.Write(h.ipad[:])
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}
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// Sum returns the hash of the written data.
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func (h *hmacsha256) Sum() []byte {
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h.outer.Reset()
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h.outer.Write(h.opad[:])
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h.outer.Write(h.inner.Sum(nil))
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return h.outer.Sum(nil)
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}
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// newHMACSHA256 returns a new HMAC-SHA256 hasher using the provided key.
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func newHMACSHA256(key []byte) *hmacsha256 {
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h := new(hmacsha256)
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h.inner = sha256.New()
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h.outer = sha256.New()
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h.initKey(key)
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return h
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}
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// NonceRFC6979 generates a nonce deterministically according to RFC 6979 using
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// HMAC-SHA256 for the hashing function. It takes a 32-byte hash as an input
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// and returns a 32-byte nonce to be used for deterministic signing. The extra
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// and version arguments are optional, but allow additional data to be added to
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// the input of the HMAC. When provided, the extra data must be 32-bytes and
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// version must be 16 bytes or they will be ignored.
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//
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// Finally, the extraIterations parameter provides a method to produce a stream
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// of deterministic nonces to ensure the signing code is able to produce a nonce
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// that results in a valid signature in the extremely unlikely event the
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// original nonce produced results in an invalid signature (e.g. R == 0).
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// Signing code should start with 0 and increment it if necessary.
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func NonceRFC6979(privKey []byte, hash []byte, extra []byte, version []byte, extraIterations uint32) *ModNScalar {
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// Input to HMAC is the 32-byte private key and the 32-byte hash. In
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// addition, it may include the optional 32-byte extra data and 16-byte
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// version. Create a fixed-size array to avoid extra allocs and slice it
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// properly.
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const (
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privKeyLen = 32
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hashLen = 32
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extraLen = 32
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versionLen = 16
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)
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var keyBuf [privKeyLen + hashLen + extraLen + versionLen]byte
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// Truncate rightmost bytes of private key and hash if they are too long and
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// leave left padding of zeros when they're too short.
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if len(privKey) > privKeyLen {
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privKey = privKey[:privKeyLen]
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}
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if len(hash) > hashLen {
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hash = hash[:hashLen]
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}
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offset := privKeyLen - len(privKey) // Zero left padding if needed.
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offset += copy(keyBuf[offset:], privKey)
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offset += hashLen - len(hash) // Zero left padding if needed.
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offset += copy(keyBuf[offset:], hash)
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if len(extra) == extraLen {
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offset += copy(keyBuf[offset:], extra)
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if len(version) == versionLen {
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offset += copy(keyBuf[offset:], version)
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}
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} else if len(version) == versionLen {
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// When the version was specified, but not the extra data, leave the
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// extra data portion all zero.
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offset += privKeyLen
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offset += copy(keyBuf[offset:], version)
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}
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key := keyBuf[:offset]
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// Step B.
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//
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// V = 0x01 0x01 0x01 ... 0x01 such that the length of V, in bits, is
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// equal to 8*ceil(hashLen/8).
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//
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// Note that since the hash length is a multiple of 8 for the chosen hash
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// function in this optimized implementation, the result is just the hash
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// length, so avoid the extra calculations. Also, since it isn't modified,
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// start with a global value.
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v := oneInitializer
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// Step C (Go zeroes all allocated memory).
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//
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// K = 0x00 0x00 0x00 ... 0x00 such that the length of K, in bits, is
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// equal to 8*ceil(hashLen/8).
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//
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// As above, since the hash length is a multiple of 8 for the chosen hash
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// function in this optimized implementation, the result is just the hash
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// length, so avoid the extra calculations.
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k := zeroInitializer[:hashLen]
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// Step D.
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//
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// K = HMAC_K(V || 0x00 || int2octets(x) || bits2octets(h1))
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//
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// Note that key is the "int2octets(x) || bits2octets(h1)" portion along
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// with potential additional data as described by section 3.6 of the RFC.
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hasher := newHMACSHA256(k)
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hasher.Write(oneInitializer)
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hasher.Write(singleZero[:])
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hasher.Write(key)
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k = hasher.Sum()
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// Step E.
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//
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// V = HMAC_K(V)
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hasher.ResetKey(k)
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hasher.Write(v)
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v = hasher.Sum()
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// Step F.
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//
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// K = HMAC_K(V || 0x01 || int2octets(x) || bits2octets(h1))
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//
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// Note that key is the "int2octets(x) || bits2octets(h1)" portion along
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// with potential additional data as described by section 3.6 of the RFC.
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hasher.Reset()
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hasher.Write(v)
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hasher.Write(singleOne[:])
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hasher.Write(key[:])
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k = hasher.Sum()
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// Step G.
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//
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// V = HMAC_K(V)
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hasher.ResetKey(k)
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hasher.Write(v)
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v = hasher.Sum()
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// Step H.
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//
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// Repeat until the value is nonzero and less than the curve order.
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var generated uint32
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for {
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// Step H1 and H2.
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//
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// Set T to the empty sequence. The length of T (in bits) is denoted
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// tlen; thus, at that point, tlen = 0.
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//
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// While tlen < qlen, do the following:
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// V = HMAC_K(V)
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// T = T || V
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//
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// Note that because the hash function output is the same length as the
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// private key in this optimized implementation, there is no need to
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// loop or create an intermediate T.
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hasher.Reset()
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hasher.Write(v)
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v = hasher.Sum()
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// Step H3.
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//
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// k = bits2int(T)
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// If k is within the range [1,q-1], return it.
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//
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// Otherwise, compute:
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// K = HMAC_K(V || 0x00)
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// V = HMAC_K(V)
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var secret ModNScalar
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overflow := secret.SetByteSlice(v)
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if !overflow && !secret.IsZero() {
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generated++
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if generated > extraIterations {
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return &secret
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}
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}
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// K = HMAC_K(V || 0x00)
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hasher.Reset()
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hasher.Write(v)
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hasher.Write(singleZero[:])
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k = hasher.Sum()
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// V = HMAC_K(V)
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hasher.ResetKey(k)
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hasher.Write(v)
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v = hasher.Sum()
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}
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}
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