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327 lines
10 KiB
C
327 lines
10 KiB
C
/* Copyright (c) 2001 Matej Pfajfar.
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* Copyright (c) 2001-2004, Roger Dingledine.
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* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
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* Copyright (c) 2007-2018, The Tor Project, Inc. */
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/* See LICENSE for licensing information */
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#include "or.h"
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#include "config.h"
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#include "hs_ntor.h" // for HS_NTOR_KEY_EXPANSION_KDF_OUT_LEN
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#include "relay_crypto.h"
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#include "relay.h"
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/** Update digest from the payload of cell. Assign integrity part to
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* cell.
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*/
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static void
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relay_set_digest(crypto_digest_t *digest, cell_t *cell)
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{
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char integrity[4];
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relay_header_t rh;
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crypto_digest_add_bytes(digest, (char*)cell->payload, CELL_PAYLOAD_SIZE);
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crypto_digest_get_digest(digest, integrity, 4);
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// log_fn(LOG_DEBUG,"Putting digest of %u %u %u %u into relay cell.",
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// integrity[0], integrity[1], integrity[2], integrity[3]);
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relay_header_unpack(&rh, cell->payload);
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memcpy(rh.integrity, integrity, 4);
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relay_header_pack(cell->payload, &rh);
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}
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/** Does the digest for this circuit indicate that this cell is for us?
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*
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* Update digest from the payload of cell (with the integrity part set
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* to 0). If the integrity part is valid, return 1, else restore digest
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* and cell to their original state and return 0.
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*/
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static int
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relay_digest_matches(crypto_digest_t *digest, cell_t *cell)
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{
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uint32_t received_integrity, calculated_integrity;
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relay_header_t rh;
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crypto_digest_checkpoint_t backup_digest;
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crypto_digest_checkpoint(&backup_digest, digest);
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relay_header_unpack(&rh, cell->payload);
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memcpy(&received_integrity, rh.integrity, 4);
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memset(rh.integrity, 0, 4);
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relay_header_pack(cell->payload, &rh);
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// log_fn(LOG_DEBUG,"Reading digest of %u %u %u %u from relay cell.",
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// received_integrity[0], received_integrity[1],
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// received_integrity[2], received_integrity[3]);
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crypto_digest_add_bytes(digest, (char*) cell->payload, CELL_PAYLOAD_SIZE);
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crypto_digest_get_digest(digest, (char*) &calculated_integrity, 4);
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int rv = 1;
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if (calculated_integrity != received_integrity) {
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// log_fn(LOG_INFO,"Recognized=0 but bad digest. Not recognizing.");
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// (%d vs %d).", received_integrity, calculated_integrity);
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/* restore digest to its old form */
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crypto_digest_restore(digest, &backup_digest);
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/* restore the relay header */
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memcpy(rh.integrity, &received_integrity, 4);
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relay_header_pack(cell->payload, &rh);
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rv = 0;
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}
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memwipe(&backup_digest, 0, sizeof(backup_digest));
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return rv;
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}
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/** Apply <b>cipher</b> to CELL_PAYLOAD_SIZE bytes of <b>in</b>
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* (in place).
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*
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* Note that we use the same operation for encrypting and for decrypting.
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*/
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static void
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relay_crypt_one_payload(crypto_cipher_t *cipher, uint8_t *in)
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{
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crypto_cipher_crypt_inplace(cipher, (char*) in, CELL_PAYLOAD_SIZE);
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}
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/** Do the appropriate en/decryptions for <b>cell</b> arriving on
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* <b>circ</b> in direction <b>cell_direction</b>.
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*
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* If cell_direction == CELL_DIRECTION_IN:
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* - If we're at the origin (we're the OP), for hops 1..N,
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* decrypt cell. If recognized, stop.
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* - Else (we're not the OP), encrypt one hop. Cell is not recognized.
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*
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* If cell_direction == CELL_DIRECTION_OUT:
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* - decrypt one hop. Check if recognized.
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*
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* If cell is recognized, set *recognized to 1, and set
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* *layer_hint to the hop that recognized it.
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*
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* Return -1 to indicate that we should mark the circuit for close,
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* else return 0.
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*/
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int
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relay_decrypt_cell(circuit_t *circ, cell_t *cell,
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cell_direction_t cell_direction,
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crypt_path_t **layer_hint, char *recognized)
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{
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relay_header_t rh;
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tor_assert(circ);
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tor_assert(cell);
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tor_assert(recognized);
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tor_assert(cell_direction == CELL_DIRECTION_IN ||
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cell_direction == CELL_DIRECTION_OUT);
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if (cell_direction == CELL_DIRECTION_IN) {
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if (CIRCUIT_IS_ORIGIN(circ)) { /* We're at the beginning of the circuit.
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* We'll want to do layered decrypts. */
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crypt_path_t *thishop, *cpath = TO_ORIGIN_CIRCUIT(circ)->cpath;
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thishop = cpath;
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if (thishop->state != CPATH_STATE_OPEN) {
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log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
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"Relay cell before first created cell? Closing.");
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return -1;
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}
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do { /* Remember: cpath is in forward order, that is, first hop first. */
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tor_assert(thishop);
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/* decrypt one layer */
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relay_crypt_one_payload(thishop->crypto.b_crypto, cell->payload);
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relay_header_unpack(&rh, cell->payload);
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if (rh.recognized == 0) {
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/* it's possibly recognized. have to check digest to be sure. */
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if (relay_digest_matches(thishop->crypto.b_digest, cell)) {
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*recognized = 1;
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*layer_hint = thishop;
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return 0;
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}
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}
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thishop = thishop->next;
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} while (thishop != cpath && thishop->state == CPATH_STATE_OPEN);
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log_fn(LOG_PROTOCOL_WARN, LD_OR,
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"Incoming cell at client not recognized. Closing.");
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return -1;
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} else {
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relay_crypto_t *crypto = &TO_OR_CIRCUIT(circ)->crypto;
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/* We're in the middle. Encrypt one layer. */
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relay_crypt_one_payload(crypto->b_crypto, cell->payload);
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}
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} else /* cell_direction == CELL_DIRECTION_OUT */ {
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/* We're in the middle. Decrypt one layer. */
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relay_crypto_t *crypto = &TO_OR_CIRCUIT(circ)->crypto;
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relay_crypt_one_payload(crypto->f_crypto, cell->payload);
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relay_header_unpack(&rh, cell->payload);
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if (rh.recognized == 0) {
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/* it's possibly recognized. have to check digest to be sure. */
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if (relay_digest_matches(crypto->f_digest, cell)) {
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*recognized = 1;
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return 0;
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}
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}
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}
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return 0;
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}
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/**
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* Encrypt a cell <b>cell</b> that we are creating, and sending outbound on
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* <b>circ</b> until the hop corresponding to <b>layer_hint</b>.
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*
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* The integrity field and recognized field of <b>cell</b>'s relay headers
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* must be set to zero.
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*/
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void
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relay_encrypt_cell_outbound(cell_t *cell,
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origin_circuit_t *circ,
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crypt_path_t *layer_hint)
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{
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crypt_path_t *thishop; /* counter for repeated crypts */
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relay_set_digest(layer_hint->crypto.f_digest, cell);
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thishop = layer_hint;
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/* moving from farthest to nearest hop */
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do {
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tor_assert(thishop);
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log_debug(LD_OR,"encrypting a layer of the relay cell.");
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relay_crypt_one_payload(thishop->crypto.f_crypto, cell->payload);
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thishop = thishop->prev;
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} while (thishop != circ->cpath->prev);
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}
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/**
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* Encrypt a cell <b>cell</b> that we are creating, and sending on
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* <b>circuit</b> to the origin.
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*
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* The integrity field and recognized field of <b>cell</b>'s relay headers
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* must be set to zero.
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*/
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void
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relay_encrypt_cell_inbound(cell_t *cell,
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or_circuit_t *or_circ)
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{
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relay_set_digest(or_circ->crypto.b_digest, cell);
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/* encrypt one layer */
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relay_crypt_one_payload(or_circ->crypto.b_crypto, cell->payload);
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}
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/**
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* Release all storage held inside <b>crypto</b>, but do not free
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* <b>crypto</b> itself: it lives inside another object.
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*/
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void
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relay_crypto_clear(relay_crypto_t *crypto)
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{
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if (BUG(!crypto))
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return;
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crypto_cipher_free(crypto->f_crypto);
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crypto_cipher_free(crypto->b_crypto);
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crypto_digest_free(crypto->f_digest);
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crypto_digest_free(crypto->b_digest);
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}
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/** Initialize <b>crypto</b> from the key material in key_data.
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*
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* If <b>is_hs_v3</b> is set, this cpath will be used for next gen hidden
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* service circuits and <b>key_data</b> must be at least
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* HS_NTOR_KEY_EXPANSION_KDF_OUT_LEN bytes in length.
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*
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* If <b>is_hs_v3</b> is not set, key_data must contain CPATH_KEY_MATERIAL_LEN
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* bytes, which are used as follows:
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* - 20 to initialize f_digest
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* - 20 to initialize b_digest
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* - 16 to key f_crypto
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* - 16 to key b_crypto
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*
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* (If 'reverse' is true, then f_XX and b_XX are swapped.)
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*
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* Return 0 if init was successful, else -1 if it failed.
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*/
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int
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relay_crypto_init(relay_crypto_t *crypto,
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const char *key_data, size_t key_data_len,
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int reverse, int is_hs_v3)
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{
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crypto_digest_t *tmp_digest;
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crypto_cipher_t *tmp_crypto;
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size_t digest_len = 0;
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size_t cipher_key_len = 0;
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tor_assert(crypto);
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tor_assert(key_data);
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tor_assert(!(crypto->f_crypto || crypto->b_crypto ||
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crypto->f_digest || crypto->b_digest));
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/* Basic key size validation */
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if (is_hs_v3 && BUG(key_data_len != HS_NTOR_KEY_EXPANSION_KDF_OUT_LEN)) {
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goto err;
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} else if (!is_hs_v3 && BUG(key_data_len != CPATH_KEY_MATERIAL_LEN)) {
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goto err;
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}
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/* If we are using this crypto for next gen onion services use SHA3-256,
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otherwise use good ol' SHA1 */
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if (is_hs_v3) {
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digest_len = DIGEST256_LEN;
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cipher_key_len = CIPHER256_KEY_LEN;
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crypto->f_digest = crypto_digest256_new(DIGEST_SHA3_256);
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crypto->b_digest = crypto_digest256_new(DIGEST_SHA3_256);
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} else {
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digest_len = DIGEST_LEN;
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cipher_key_len = CIPHER_KEY_LEN;
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crypto->f_digest = crypto_digest_new();
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crypto->b_digest = crypto_digest_new();
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}
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tor_assert(digest_len != 0);
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tor_assert(cipher_key_len != 0);
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const int cipher_key_bits = (int) cipher_key_len * 8;
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crypto_digest_add_bytes(crypto->f_digest, key_data, digest_len);
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crypto_digest_add_bytes(crypto->b_digest, key_data+digest_len, digest_len);
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crypto->f_crypto = crypto_cipher_new_with_bits(key_data+(2*digest_len),
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cipher_key_bits);
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if (!crypto->f_crypto) {
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log_warn(LD_BUG,"Forward cipher initialization failed.");
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goto err;
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}
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crypto->b_crypto = crypto_cipher_new_with_bits(
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key_data+(2*digest_len)+cipher_key_len,
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cipher_key_bits);
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if (!crypto->b_crypto) {
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log_warn(LD_BUG,"Backward cipher initialization failed.");
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goto err;
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}
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if (reverse) {
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tmp_digest = crypto->f_digest;
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crypto->f_digest = crypto->b_digest;
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crypto->b_digest = tmp_digest;
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tmp_crypto = crypto->f_crypto;
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crypto->f_crypto = crypto->b_crypto;
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crypto->b_crypto = tmp_crypto;
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}
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return 0;
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err:
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relay_crypto_clear(crypto);
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return -1;
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}
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/** Assert that <b>crypto</b> is valid and set. */
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void
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relay_crypto_assert_ok(const relay_crypto_t *crypto)
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{
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tor_assert(crypto->f_crypto);
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tor_assert(crypto->b_crypto);
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tor_assert(crypto->f_digest);
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tor_assert(crypto->b_digest);
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}
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