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https://github.com/ElementsProject/lightning.git
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adb984dd45
Since we might soon be changing the payload it is a good idea to not just expose the v0 payload, but also the raw payload for the plugin to interpret. This might also include payloads that `lightningd` itself cannot understand, but the plugin might. Signed-off-by: Christian Decker <decker.christian@gmail.com> Suggested-by: Corné Plooy <@bitonic-cjp>
578 lines
15 KiB
C
578 lines
15 KiB
C
#include <assert.h>
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#include <ccan/array_size/array_size.h>
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#include <ccan/crypto/ripemd160/ripemd160.h>
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#include <ccan/crypto/sha256/sha256.h>
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#include <ccan/mem/mem.h>
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#include <common/sphinx.h>
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#include <common/utils.h>
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#include <err.h>
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#include <secp256k1_ecdh.h>
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#include <sodium/crypto_auth_hmacsha256.h>
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#include <sodium/crypto_stream_chacha20.h>
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#define BLINDING_FACTOR_SIZE 32
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#define SHARED_SECRET_SIZE 32
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#define HMAC_SIZE 32
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#define NUM_STREAM_BYTES ((NUM_MAX_HOPS + 1) * HOP_DATA_SIZE)
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#define KEY_LEN 32
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#define ONION_REPLY_SIZE 256
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struct hop_params {
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u8 secret[SHARED_SECRET_SIZE];
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u8 blind[BLINDING_FACTOR_SIZE];
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struct pubkey ephemeralkey;
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};
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struct keyset {
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u8 pi[KEY_LEN];
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u8 mu[KEY_LEN];
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u8 rho[KEY_LEN];
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u8 gamma[KEY_LEN];
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};
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/* Small helper to append data to a buffer and update the position
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* into the buffer
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*/
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static void write_buffer(u8 *dst, const void *src, const size_t len, int *pos)
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{
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memcpy(dst + *pos, src, len);
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*pos += len;
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}
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/* Read len bytes from the source at position pos into dst and update
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* the position pos accordingly.
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*/
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static void read_buffer(void *dst, const u8 *src, const size_t len, int *pos)
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{
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memcpy(dst, src + *pos, len);
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*pos += len;
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}
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u8 *serialize_onionpacket(
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const tal_t *ctx,
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const struct onionpacket *m)
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{
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u8 *dst = tal_arr(ctx, u8, TOTAL_PACKET_SIZE);
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u8 der[PUBKEY_CMPR_LEN];
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int p = 0;
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pubkey_to_der(der, &m->ephemeralkey);
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write_buffer(dst, &m->version, 1, &p);
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write_buffer(dst, der, sizeof(der), &p);
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write_buffer(dst, m->routinginfo, ROUTING_INFO_SIZE, &p);
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write_buffer(dst, m->mac, sizeof(m->mac), &p);
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return dst;
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}
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struct onionpacket *parse_onionpacket(const tal_t *ctx,
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const void *src,
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const size_t srclen,
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enum onion_type *why_bad)
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{
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struct onionpacket *m;
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int p = 0;
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u8 rawEphemeralkey[PUBKEY_CMPR_LEN];
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assert(srclen == TOTAL_PACKET_SIZE);
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m = talz(ctx, struct onionpacket);
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read_buffer(&m->version, src, 1, &p);
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if (m->version != 0x00) {
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// FIXME add logging
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*why_bad = WIRE_INVALID_ONION_VERSION;
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return tal_free(m);
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}
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read_buffer(rawEphemeralkey, src, sizeof(rawEphemeralkey), &p);
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if (!pubkey_from_der(rawEphemeralkey, sizeof(rawEphemeralkey),
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&m->ephemeralkey)) {
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*why_bad = WIRE_INVALID_ONION_KEY;
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return tal_free(m);
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}
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read_buffer(&m->routinginfo, src, ROUTING_INFO_SIZE, &p);
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read_buffer(&m->mac, src, SECURITY_PARAMETER, &p);
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return m;
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}
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static void xorbytes(uint8_t *d, const uint8_t *a, const uint8_t *b, size_t len)
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{
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size_t i;
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for (i = 0; i < len; i++)
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d[i] = a[i] ^ b[i];
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}
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/*
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* Generate a pseudo-random byte stream of length `dstlen` from key `k` and
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* store it in `dst`. `dst must be at least `dstlen` bytes long.
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*/
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static void generate_cipher_stream(void *dst, const u8 *k, size_t dstlen)
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{
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u8 nonce[8] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 };
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crypto_stream_chacha20(dst, dstlen, nonce, k);
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}
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static bool compute_hmac(
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void *dst,
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const void *src,
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size_t len,
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const void *key,
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size_t keylen)
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{
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crypto_auth_hmacsha256_state state;
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crypto_auth_hmacsha256_init(&state, key, keylen);
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crypto_auth_hmacsha256_update(&state, memcheck(src, len), len);
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crypto_auth_hmacsha256_final(&state, dst);
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return true;
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}
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static void compute_packet_hmac(const struct onionpacket *packet,
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const u8 *assocdata, const size_t assocdatalen,
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u8 *mukey, u8 *hmac)
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{
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u8 mactemp[ROUTING_INFO_SIZE + assocdatalen];
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u8 mac[32];
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int pos = 0;
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write_buffer(mactemp, packet->routinginfo, ROUTING_INFO_SIZE, &pos);
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write_buffer(mactemp, assocdata, assocdatalen, &pos);
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compute_hmac(mac, mactemp, sizeof(mactemp), mukey, KEY_LEN);
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memcpy(hmac, mac, SECURITY_PARAMETER);
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}
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static bool generate_key(void *k, const char *t, u8 tlen, const u8 *s)
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{
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return compute_hmac(k, s, KEY_LEN, t, tlen);
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}
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static bool generate_header_padding(
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void *dst, size_t dstlen,
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const size_t hopsize,
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const char *keytype,
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size_t keytypelen,
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const u8 numhops,
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struct hop_params *params
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)
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{
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int i;
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u8 cipher_stream[(NUM_MAX_HOPS + 1) * hopsize];
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u8 key[KEY_LEN];
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memset(dst, 0, dstlen);
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for (i = 1; i < numhops; i++) {
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if (!generate_key(&key, keytype, keytypelen, params[i - 1].secret))
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return false;
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generate_cipher_stream(cipher_stream, key, sizeof(cipher_stream));
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int pos = ((NUM_MAX_HOPS - i) + 1) * hopsize;
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xorbytes(dst, dst, cipher_stream + pos, sizeof(cipher_stream) - pos);
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}
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return true;
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}
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static void compute_blinding_factor(const struct pubkey *key,
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const u8 sharedsecret[SHARED_SECRET_SIZE],
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u8 res[BLINDING_FACTOR_SIZE])
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{
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struct sha256_ctx ctx;
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u8 der[PUBKEY_CMPR_LEN];
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struct sha256 temp;
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pubkey_to_der(der, key);
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sha256_init(&ctx);
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sha256_update(&ctx, der, sizeof(der));
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sha256_update(&ctx, sharedsecret, SHARED_SECRET_SIZE);
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sha256_done(&ctx, &temp);
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memcpy(res, &temp, 32);
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}
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static bool blind_group_element(
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struct pubkey *blindedelement,
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const struct pubkey *pubkey,
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const u8 blind[BLINDING_FACTOR_SIZE])
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{
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/* tweak_mul is inplace so copy first. */
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if (pubkey != blindedelement)
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*blindedelement = *pubkey;
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if (secp256k1_ec_pubkey_tweak_mul(secp256k1_ctx, &blindedelement->pubkey, blind) != 1)
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return false;
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return true;
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}
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static bool create_shared_secret(
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u8 *secret,
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const struct pubkey *pubkey,
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const u8 *sessionkey)
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{
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if (secp256k1_ecdh(secp256k1_ctx, secret, &pubkey->pubkey, sessionkey,
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NULL, NULL)
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!= 1)
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return false;
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return true;
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}
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bool onion_shared_secret(
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u8 *secret,
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const struct onionpacket *packet,
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const struct privkey *privkey)
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{
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return create_shared_secret(secret, &packet->ephemeralkey,
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privkey->secret.data);
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}
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static void generate_key_set(const u8 secret[SHARED_SECRET_SIZE],
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struct keyset *keys)
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{
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generate_key(keys->rho, "rho", 3, secret);
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generate_key(keys->pi, "pi", 2, secret);
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generate_key(keys->mu, "mu", 2, secret);
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generate_key(keys->gamma, "gamma", 5, secret);
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}
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static struct hop_params *generate_hop_params(
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const tal_t *ctx,
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const u8 *sessionkey,
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struct pubkey path[])
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{
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int i, j, num_hops = tal_count(path);
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struct pubkey temp;
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u8 blind[BLINDING_FACTOR_SIZE];
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struct hop_params *params = tal_arr(ctx, struct hop_params, num_hops);
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/* Initialize the first hop with the raw information */
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if (secp256k1_ec_pubkey_create(
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secp256k1_ctx, ¶ms[0].ephemeralkey.pubkey, sessionkey) != 1)
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return NULL;
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if (!create_shared_secret(params[0].secret, &path[0], sessionkey))
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return NULL;
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compute_blinding_factor(
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¶ms[0].ephemeralkey, params[0].secret,
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params[0].blind);
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/* Recursively compute all following ephemeral public keys,
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* secrets and blinding factors
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*/
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for (i = 1; i < num_hops; i++) {
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if (!blind_group_element(
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¶ms[i].ephemeralkey,
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¶ms[i - 1].ephemeralkey,
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params[i - 1].blind))
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return NULL;
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/* Blind this hop's point with all previous blinding factors
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* Order is indifferent, multiplication is commutative.
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*/
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memcpy(&blind, sessionkey, 32);
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temp = path[i];
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if (!blind_group_element(&temp, &temp, blind))
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return NULL;
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for (j = 0; j < i; j++)
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if (!blind_group_element(
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&temp,
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&temp,
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params[j].blind))
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return NULL;
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/* Now hash temp and store it. This requires us to
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* DER-serialize first and then skip the sign byte.
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*/
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u8 der[PUBKEY_CMPR_LEN];
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pubkey_to_der(der, &temp);
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struct sha256 h;
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sha256(&h, der, sizeof(der));
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memcpy(¶ms[i].secret, &h, sizeof(h));
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compute_blinding_factor(
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¶ms[i].ephemeralkey,
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params[i].secret, params[i].blind);
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}
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return params;
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}
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static void serialize_hop_data(tal_t *ctx, u8 *dst, const struct hop_data *data)
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{
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u8 *buf = tal_arr(ctx, u8, 0);
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towire_u8(&buf, data->realm);
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towire_short_channel_id(&buf, &data->channel_id);
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towire_amount_msat(&buf, data->amt_forward);
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towire_u32(&buf, data->outgoing_cltv);
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towire_pad(&buf, 12);
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towire(&buf, data->hmac, SECURITY_PARAMETER);
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memcpy(dst, buf, tal_count(buf));
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tal_free(buf);
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}
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static void deserialize_hop_data(struct hop_data *data, const u8 *src)
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{
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const u8 *cursor = src;
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size_t max = HOP_DATA_SIZE;
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data->realm = fromwire_u8(&cursor, &max);
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fromwire_short_channel_id(&cursor, &max, &data->channel_id);
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data->amt_forward = fromwire_amount_msat(&cursor, &max);
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data->outgoing_cltv = fromwire_u32(&cursor, &max);
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fromwire_pad(&cursor, &max, 12);
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fromwire(&cursor, &max, &data->hmac, SECURITY_PARAMETER);
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}
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struct onionpacket *create_onionpacket(
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const tal_t *ctx,
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struct pubkey *path,
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struct hop_data hops_data[],
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const u8 *sessionkey,
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const u8 *assocdata,
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const size_t assocdatalen,
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struct secret **path_secrets
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)
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{
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struct onionpacket *packet = talz(ctx, struct onionpacket);
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int i, num_hops = tal_count(path);
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u8 filler[(num_hops - 1) * HOP_DATA_SIZE];
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struct keyset keys;
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u8 nexthmac[SECURITY_PARAMETER];
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u8 stream[ROUTING_INFO_SIZE];
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struct hop_params *params = generate_hop_params(ctx, sessionkey, path);
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struct secret *secrets = tal_arr(ctx, struct secret, num_hops);
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if (!params) {
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tal_free(packet);
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tal_free(secrets);
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return NULL;
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}
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packet->version = 0;
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memset(nexthmac, 0, SECURITY_PARAMETER);
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memset(packet->routinginfo, 0, ROUTING_INFO_SIZE);
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generate_header_padding(filler, sizeof(filler), HOP_DATA_SIZE,
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"rho", 3, num_hops, params);
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for (i = num_hops - 1; i >= 0; i--) {
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memcpy(hops_data[i].hmac, nexthmac, SECURITY_PARAMETER);
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hops_data[i].realm = 0;
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generate_key_set(params[i].secret, &keys);
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generate_cipher_stream(stream, keys.rho, ROUTING_INFO_SIZE);
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/* Rightshift mix-header by 2*SECURITY_PARAMETER */
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memmove(packet->routinginfo + HOP_DATA_SIZE, packet->routinginfo,
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ROUTING_INFO_SIZE - HOP_DATA_SIZE);
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serialize_hop_data(packet, packet->routinginfo, &hops_data[i]);
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xorbytes(packet->routinginfo, packet->routinginfo, stream, ROUTING_INFO_SIZE);
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if (i == num_hops - 1) {
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size_t len = (NUM_MAX_HOPS - num_hops + 1) * HOP_DATA_SIZE;
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memcpy(packet->routinginfo + len, filler, sizeof(filler));
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}
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compute_packet_hmac(packet, assocdata, assocdatalen, keys.mu,
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nexthmac);
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}
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memcpy(packet->mac, nexthmac, sizeof(nexthmac));
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memcpy(&packet->ephemeralkey, ¶ms[0].ephemeralkey, sizeof(secp256k1_pubkey));
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for (i=0; i<num_hops; i++) {
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memcpy(&secrets[i], params[i].secret, SHARED_SECRET_SIZE);
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}
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*path_secrets = secrets;
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return packet;
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}
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/*
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* Given an onionpacket msg extract the information for the current
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* node and unwrap the remainder so that the node can forward it.
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*/
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struct route_step *process_onionpacket(
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const tal_t *ctx,
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const struct onionpacket *msg,
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const u8 *shared_secret,
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const u8 *assocdata,
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const size_t assocdatalen
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)
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{
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struct route_step *step = talz(ctx, struct route_step);
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u8 hmac[SECURITY_PARAMETER];
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struct keyset keys;
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u8 blind[BLINDING_FACTOR_SIZE];
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u8 stream[NUM_STREAM_BYTES];
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u8 paddedheader[ROUTING_INFO_SIZE + HOP_DATA_SIZE];
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step->next = talz(step, struct onionpacket);
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step->next->version = msg->version;
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generate_key_set(shared_secret, &keys);
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compute_packet_hmac(msg, assocdata, assocdatalen, keys.mu, hmac);
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if (memcmp(msg->mac, hmac, sizeof(hmac)) != 0) {
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/* Computed MAC does not match expected MAC, the message was modified. */
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return tal_free(step);
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}
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//FIXME:store seen secrets to avoid replay attacks
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generate_cipher_stream(stream, keys.rho, sizeof(stream));
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memset(paddedheader, 0, sizeof(paddedheader));
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memcpy(paddedheader, msg->routinginfo, ROUTING_INFO_SIZE);
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xorbytes(paddedheader, paddedheader, stream, sizeof(stream));
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compute_blinding_factor(&msg->ephemeralkey, shared_secret, blind);
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if (!blind_group_element(&step->next->ephemeralkey, &msg->ephemeralkey, blind))
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return tal_free(step);
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deserialize_hop_data(&step->hop_data, paddedheader);
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memcpy(&step->next->mac, step->hop_data.hmac, SECURITY_PARAMETER);
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step->raw_payload = tal_dup_arr(step, u8, paddedheader + 1,
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HOP_DATA_SIZE - 1 - HMAC_SIZE, 0);
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memcpy(&step->next->routinginfo, paddedheader + HOP_DATA_SIZE, ROUTING_INFO_SIZE);
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if (memeqzero(step->next->mac, sizeof(step->next->mac))) {
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step->nextcase = ONION_END;
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} else {
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step->nextcase = ONION_FORWARD;
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}
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return step;
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}
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u8 *create_onionreply(const tal_t *ctx, const struct secret *shared_secret,
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const u8 *failure_msg)
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{
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size_t msglen = tal_count(failure_msg);
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size_t padlen = ONION_REPLY_SIZE - msglen;
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u8 *reply = tal_arr(ctx, u8, 0), *payload = tal_arr(ctx, u8, 0);
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u8 key[KEY_LEN];
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u8 hmac[HMAC_SIZE];
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/* BOLT #4:
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*
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* The node generating the error message (_erring node_) builds a return
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* packet consisting of
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* the following fields:
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*
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* 1. data:
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* * [`32`:`hmac`]
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* * [`2`:`failure_len`]
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* * [`failure_len`:`failuremsg`]
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* * [`2`:`pad_len`]
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* * [`pad_len`:`pad`]
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*/
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towire_u16(&payload, msglen);
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towire(&payload, failure_msg, msglen);
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towire_u16(&payload, padlen);
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towire_pad(&payload, padlen);
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/* BOLT #4:
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*
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* The _erring node_:
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* - SHOULD set `pad` such that the `failure_len` plus `pad_len` is
|
|
* equal to 256.
|
|
* - Note: this value is 118 bytes longer than the longest
|
|
* currently-defined message.
|
|
*/
|
|
assert(tal_count(payload) == ONION_REPLY_SIZE + 4);
|
|
|
|
/* BOLT #4:
|
|
*
|
|
* Where `hmac` is an HMAC authenticating the remainder of the packet,
|
|
* with a key generated using the above process, with key type `um`
|
|
*/
|
|
generate_key(key, "um", 2, shared_secret->data);
|
|
|
|
compute_hmac(hmac, payload, tal_count(payload), key, KEY_LEN);
|
|
towire(&reply, hmac, sizeof(hmac));
|
|
|
|
towire(&reply, payload, tal_count(payload));
|
|
tal_free(payload);
|
|
|
|
return reply;
|
|
}
|
|
|
|
u8 *wrap_onionreply(const tal_t *ctx,
|
|
const struct secret *shared_secret, const u8 *reply)
|
|
{
|
|
u8 key[KEY_LEN];
|
|
size_t streamlen = tal_count(reply);
|
|
u8 stream[streamlen];
|
|
u8 *result = tal_arr(ctx, u8, streamlen);
|
|
|
|
/* BOLT #4:
|
|
*
|
|
* The erring node then generates a new key, using the key type `ammag`.
|
|
* This key is then used to generate a pseudo-random stream, which is
|
|
* in turn applied to the packet using `XOR`.
|
|
*
|
|
* The obfuscation step is repeated by every hop along the return path.
|
|
*/
|
|
generate_key(key, "ammag", 5, shared_secret->data);
|
|
generate_cipher_stream(stream, key, streamlen);
|
|
xorbytes(result, stream, reply, streamlen);
|
|
return result;
|
|
}
|
|
|
|
struct onionreply *unwrap_onionreply(const tal_t *ctx,
|
|
const struct secret *shared_secrets,
|
|
const int numhops, const u8 *reply)
|
|
{
|
|
struct onionreply *oreply = tal(tmpctx, struct onionreply);
|
|
u8 *msg = tal_arr(oreply, u8, tal_count(reply));
|
|
u8 key[KEY_LEN], hmac[HMAC_SIZE];
|
|
const u8 *cursor;
|
|
size_t max;
|
|
u16 msglen;
|
|
|
|
if (tal_count(reply) != ONION_REPLY_SIZE + sizeof(hmac) + 4) {
|
|
return NULL;
|
|
}
|
|
|
|
memcpy(msg, reply, tal_count(reply));
|
|
oreply->origin_index = -1;
|
|
|
|
for (int i = 0; i < numhops; i++) {
|
|
/* Since the encryption is just XORing with the cipher
|
|
* stream encryption is identical to decryption */
|
|
msg = wrap_onionreply(tmpctx, &shared_secrets[i], msg);
|
|
|
|
/* Check if the HMAC matches, this means that this is
|
|
* the origin */
|
|
generate_key(key, "um", 2, shared_secrets[i].data);
|
|
compute_hmac(hmac, msg + sizeof(hmac),
|
|
tal_count(msg) - sizeof(hmac), key, KEY_LEN);
|
|
if (memcmp(hmac, msg, sizeof(hmac)) == 0) {
|
|
oreply->origin_index = i;
|
|
break;
|
|
}
|
|
}
|
|
if (oreply->origin_index == -1) {
|
|
return NULL;
|
|
}
|
|
|
|
cursor = msg + sizeof(hmac);
|
|
max = tal_count(msg) - sizeof(hmac);
|
|
msglen = fromwire_u16(&cursor, &max);
|
|
|
|
if (msglen > ONION_REPLY_SIZE) {
|
|
return NULL;
|
|
}
|
|
|
|
oreply->msg = tal_arr(oreply, u8, msglen);
|
|
fromwire(&cursor, &max, oreply->msg, msglen);
|
|
|
|
tal_steal(ctx, oreply);
|
|
return oreply;
|
|
|
|
}
|