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71029cea2d
This updates all source files to use a new standard header for copyright and license declaration. Notably, copyright no longer includes a date, and we now use the standard SPDX-License-Identifier header. This commit was done almost entirely mechanically with perl, and then some minimal manual fixes. Updates #6865 Signed-off-by: Will Norris <will@tailscale.com>
117 lines
3.5 KiB
Go
117 lines
3.5 KiB
Go
// Copyright (c) Tailscale Inc & AUTHORS
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// SPDX-License-Identifier: BSD-3-Clause
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package key
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import (
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crand "crypto/rand"
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"encoding/base64"
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"encoding/hex"
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"errors"
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"fmt"
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"io"
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"go4.org/mem"
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)
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// rand fills b with cryptographically strong random bytes. Panics if
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// no random bytes are available.
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func rand(b []byte) {
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if _, err := io.ReadFull(crand.Reader, b[:]); err != nil {
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panic(fmt.Sprintf("unable to read random bytes from OS: %v", err))
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}
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}
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// clamp25519 clamps b, which must be a 32-byte Curve25519 private
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// key, to a safe value.
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//
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// The clamping effectively constrains the key to a number between
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// 2^251 and 2^252-1, which is then multiplied by 8 (the cofactor of
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// Curve25519). This produces a value that doesn't have any unsafe
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// properties when doing operations like ScalarMult.
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//
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// See
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// https://web.archive.org/web/20210228105330/https://neilmadden.blog/2020/05/28/whats-the-curve25519-clamping-all-about/
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// for a more in-depth explanation of the constraints that led to this
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// clamping requirement.
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//
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// PLEASE NOTE that not all Curve25519 values require clamping. When
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// implementing a new key type that uses Curve25519, you must evaluate
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// whether that particular key's use requires clamping. Here are some
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// existing uses and whether you should clamp private keys at
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// creation.
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//
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// - NaCl box: yes, clamp at creation.
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// - WireGuard (userspace uapi or kernel): no, do not clamp.
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// - Noise protocols: no, do not clamp.
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func clamp25519Private(b []byte) {
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b[0] &= 248
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b[31] = (b[31] & 127) | 64
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}
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func toHex(k []byte, prefix string) []byte {
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ret := make([]byte, len(prefix)+len(k)*2)
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copy(ret, prefix)
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hex.Encode(ret[len(prefix):], k)
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return ret
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}
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// parseHex decodes a key string of the form "<prefix><hex string>"
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// into out. The prefix must match, and the decoded base64 must fit
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// exactly into out.
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//
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// Note the errors in this function deliberately do not echo the
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// contents of in, because it might be a private key or part of a
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// private key.
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func parseHex(out []byte, in, prefix mem.RO) error {
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if !mem.HasPrefix(in, prefix) {
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return fmt.Errorf("key hex string doesn't have expected type prefix %s", prefix.StringCopy())
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}
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in = in.SliceFrom(prefix.Len())
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if want := len(out) * 2; in.Len() != want {
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return fmt.Errorf("key hex has the wrong size, got %d want %d", in.Len(), want)
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}
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for i := range out {
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a, ok1 := fromHexChar(in.At(i*2 + 0))
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b, ok2 := fromHexChar(in.At(i*2 + 1))
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if !ok1 || !ok2 {
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return errors.New("invalid hex character in key")
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}
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out[i] = (a << 4) | b
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}
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return nil
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}
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// fromHexChar converts a hex character into its value and a success flag.
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func fromHexChar(c byte) (byte, bool) {
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switch {
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case '0' <= c && c <= '9':
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return c - '0', true
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case 'a' <= c && c <= 'f':
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return c - 'a' + 10, true
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case 'A' <= c && c <= 'F':
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return c - 'A' + 10, true
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}
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return 0, false
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}
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// debug32 returns the Tailscale conventional debug representation of
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// a key: the first five base64 digits of the key, in square brackets.
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func debug32(k [32]byte) string {
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if k == [32]byte{} {
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return ""
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}
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// The goal here is to generate "[" + base64.StdEncoding.EncodeToString(k[:])[:5] + "]".
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// Since we only care about the first 5 characters, it suffices to encode the first 4 bytes of k.
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// Encoding those 4 bytes requires 8 bytes.
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// Make dst have size 9, to fit the leading '[' plus those 8 bytes.
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// We slice the unused ones away at the end.
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dst := make([]byte, 9)
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dst[0] = '['
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base64.StdEncoding.Encode(dst[1:], k[:4])
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dst[6] = ']'
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return string(dst[:7])
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}
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