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182 lines
5.1 KiB
V
182 lines
5.1 KiB
V
module ed25519
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import crypto.rand
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import crypto.sha512
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import crypto.internal.subtle
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import crypto.ed25519.internal.edwards25519
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// public_key_size is the sizeof public keys in bytes
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pub const public_key_size = 32
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// private_key_size is the sizeof private keys in bytes
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pub const private_key_size = 64
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// signature_size is the size of signatures generated and verified by this modules, in bytes.
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pub const signature_size = 64
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// seed_size is the size of private key seeds in bytes
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pub const seed_size = 32
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// `PublicKey` is Ed25519 public keys.
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pub type PublicKey = []byte
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// equal reports whether p and x have the same value.
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pub fn (p PublicKey) equal(x []byte) bool {
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return subtle.constant_time_compare(p, PublicKey(x)) == 1
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}
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// PrivateKey is Ed25519 private keys
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pub type PrivateKey = []byte
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// seed returns the private key seed corresponding to priv.
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// RFC 8032's private keys correspond to seeds in this module.
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pub fn (priv PrivateKey) seed() []byte {
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mut seed := []byte{len: ed25519.seed_size}
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copy(mut seed, priv[..32])
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return seed
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}
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// public_key returns the []byte corresponding to priv.
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pub fn (priv PrivateKey) public_key() PublicKey {
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assert priv.len == ed25519.private_key_size
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mut publickey := []byte{len: ed25519.public_key_size}
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copy(mut publickey, priv[32..])
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return PublicKey(publickey)
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}
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// currentyly x not `crypto.PrivateKey`
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pub fn (priv PrivateKey) equal(x []byte) bool {
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return subtle.constant_time_compare(priv, PrivateKey(x)) == 1
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}
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// sign signs the given message with priv.
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pub fn (priv PrivateKey) sign(message []byte) ?[]byte {
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/*
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if opts.HashFunc() != crypto.Hash(0) {
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return nil, errors.New("ed25519: cannot sign hashed message")
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}*/
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return sign(priv, message)
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}
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// sign`signs the message with privatekey and returns a signature
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pub fn sign(privatekey PrivateKey, message []byte) ?[]byte {
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mut signature := []byte{len: ed25519.signature_size}
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sign_generic(mut signature, privatekey, message) ?
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return signature
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}
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fn sign_generic(mut signature []byte, privatekey []byte, message []byte) ? {
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if privatekey.len != ed25519.private_key_size {
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panic('ed25519: bad private key length: $privatekey.len')
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}
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seed, publickey := privatekey[..ed25519.seed_size], privatekey[ed25519.seed_size..]
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mut h := sha512.sum512(seed)
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mut s := edwards25519.new_scalar()
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s.set_bytes_with_clamping(h[..32]) ?
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mut prefix := h[32..]
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mut mh := sha512.new()
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mh.write(prefix) ?
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mh.write(message) ?
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mut msg_digest := []byte{cap: sha512.size}
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msg_digest = mh.sum(msg_digest)
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mut r := edwards25519.new_scalar()
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r.set_uniform_bytes(msg_digest) ?
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mut rr := edwards25519.Point{}
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rr.scalar_base_mult(mut r)
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mut kh := sha512.new()
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kh.write(rr.bytes()) ?
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kh.write(publickey) ?
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kh.write(message) ?
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mut hram_digest := []byte{cap: sha512.size}
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hram_digest = kh.sum(hram_digest)
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mut k := edwards25519.new_scalar()
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k.set_uniform_bytes(hram_digest) ?
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mut ss := edwards25519.new_scalar()
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ss.multiply_add(k, s, r)
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copy(mut signature[..32], rr.bytes())
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copy(mut signature[32..], ss.bytes())
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}
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// verify reports whether sig is a valid signature of message by publickey.
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pub fn verify(publickey PublicKey, message []byte, sig []byte) ?bool {
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if publickey.len != ed25519.public_key_size {
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return error('ed25519: bad public key length: $publickey.len')
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}
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if sig.len != ed25519.signature_size || sig[63] & 224 != 0 {
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return false
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}
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mut aa := edwards25519.Point{}
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aa.set_bytes(publickey) ?
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mut kh := sha512.new()
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kh.write(sig[..32]) ?
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kh.write(publickey) ?
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kh.write(message) ?
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mut hram_digest := []byte{cap: sha512.size}
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hram_digest = kh.sum(hram_digest)
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mut k := edwards25519.new_scalar()
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k.set_uniform_bytes(hram_digest) ?
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mut ss := edwards25519.new_scalar()
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ss.set_canonical_bytes(sig[32..]) ?
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// [S]B = R + [k]A --> [k](-A) + [S]B = R
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mut minus_a := edwards25519.Point{}
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minus_a.negate(aa)
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mut rr := edwards25519.Point{}
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rr.vartime_double_scalar_base_mult(k, minus_a, ss)
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return subtle.constant_time_compare(sig[..32], rr.bytes()) == 1
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}
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// generate_key generates a public/private key pair entropy using `crypto.rand`.
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pub fn generate_key() ?(PublicKey, PrivateKey) {
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mut seed := rand.bytes(ed25519.seed_size) ?
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privatekey := new_key_from_seed(seed)
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mut publickey := []byte{len: ed25519.public_key_size}
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copy(mut publickey, privatekey[32..])
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return publickey, privatekey
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}
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// new_key_from_seed calculates a private key from a seed. private keys of RFC 8032
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// correspond to seeds in this module
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pub fn new_key_from_seed(seed []byte) PrivateKey {
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// Outline the function body so that the returned key can be stack-allocated.
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mut privatekey := []byte{len: ed25519.private_key_size}
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new_key_from_seed_generic(mut privatekey, seed)
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return PrivateKey(privatekey)
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}
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fn new_key_from_seed_generic(mut privatekey []byte, seed []byte) {
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if seed.len != ed25519.seed_size {
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panic('ed25519: bad seed length: $seed.len')
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}
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mut h := sha512.sum512(seed)
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mut s := edwards25519.new_scalar()
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s.set_bytes_with_clamping(h[..32]) or { panic(err.msg) }
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mut aa := edwards25519.Point{}
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aa.scalar_base_mult(mut s)
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mut publickey := aa.bytes()
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copy(mut privatekey, seed)
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copy(mut privatekey[32..], publickey)
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}
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