mirror of
https://github.com/zerotier/ZeroTierOne.git
synced 2024-12-25 15:41:05 +00:00
229 lines
7.4 KiB
C++
229 lines
7.4 KiB
C++
/*
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* ZeroTier One - Global Peer to Peer Ethernet
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* Copyright (C) 2012-2013 ZeroTier Networks LLC
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*
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* --
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*
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* ZeroTier may be used and distributed under the terms of the GPLv3, which
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* are available at: http://www.gnu.org/licenses/gpl-3.0.html
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*
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* If you would like to embed ZeroTier into a commercial application or
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* redistribute it in a modified binary form, please contact ZeroTier Networks
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* LLC. Start here: http://www.zerotier.com/
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*/
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <stdint.h>
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#include <openssl/sha.h>
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#include "Identity.hpp"
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#include "Salsa20.hpp"
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#include "HMAC.hpp"
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#include "Utils.hpp"
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namespace ZeroTier {
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void Identity::generate()
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{
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delete [] _keyPair;
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// Generate key pair and derive address
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do {
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_keyPair = new EllipticCurveKeyPair();
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_keyPair->generate();
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_address = deriveAddress(_keyPair->pub().data(),_keyPair->pub().size());
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} while (_address.isReserved());
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_publicKey = _keyPair->pub();
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// Sign address, key type, and public key with private key (with a zero
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// byte between each field). Including this extra data means simply editing
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// the address of an identity will be detected as its signature will be
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// invalid. Of course, deep verification of address/key relationship is
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// required to cover the more elaborate address claim jump attempt case.
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unsigned char atmp[ZT_ADDRESS_LENGTH];
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_address.copyTo(atmp,ZT_ADDRESS_LENGTH);
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SHA256_CTX sha;
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unsigned char dig[32];
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unsigned char idtype = IDENTITY_TYPE_NIST_P_521,zero = 0;
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SHA256_Init(&sha);
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SHA256_Update(&sha,atmp,ZT_ADDRESS_LENGTH);
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SHA256_Update(&sha,&zero,1);
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SHA256_Update(&sha,&idtype,1);
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SHA256_Update(&sha,&zero,1);
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SHA256_Update(&sha,_publicKey.data(),_publicKey.size());
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SHA256_Update(&sha,&zero,1);
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SHA256_Final(dig,&sha);
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_signature = _keyPair->sign(dig);
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}
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bool Identity::locallyValidate(bool doAddressDerivationCheck) const
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{
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unsigned char atmp[ZT_ADDRESS_LENGTH];
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_address.copyTo(atmp,ZT_ADDRESS_LENGTH);
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SHA256_CTX sha;
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unsigned char dig[32];
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unsigned char idtype = IDENTITY_TYPE_NIST_P_521,zero = 0;
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SHA256_Init(&sha);
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SHA256_Update(&sha,atmp,ZT_ADDRESS_LENGTH);
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SHA256_Update(&sha,&zero,1);
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SHA256_Update(&sha,&idtype,1);
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SHA256_Update(&sha,&zero,1);
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SHA256_Update(&sha,_publicKey.data(),_publicKey.size());
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SHA256_Update(&sha,&zero,1);
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SHA256_Final(dig,&sha);
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return ((EllipticCurveKeyPair::verify(dig,_publicKey,_signature.data(),_signature.length()))&&((!doAddressDerivationCheck)||(deriveAddress(_publicKey.data(),_publicKey.size()) == _address)));
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}
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std::string Identity::toString(bool includePrivate) const
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{
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std::string r;
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r.append(_address.toString());
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r.append(":1:"); // 1 == IDENTITY_TYPE_NIST_P_521
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r.append(Utils::base64Encode(_publicKey.data(),_publicKey.size()));
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r.push_back(':');
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r.append(Utils::base64Encode(_signature.data(),_signature.length()));
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if ((includePrivate)&&(_keyPair)) {
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r.push_back(':');
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r.append(Utils::base64Encode(_keyPair->priv().data(),_keyPair->priv().size()));
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}
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return r;
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}
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bool Identity::fromString(const char *str)
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{
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delete _keyPair;
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_keyPair = (EllipticCurveKeyPair *)0;
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std::vector<std::string> fields(Utils::split(Utils::trim(std::string(str)).c_str(),":","",""));
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if (fields.size() < 4)
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return false;
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if (fields[1] != "1")
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return false; // version mismatch
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std::string b(Utils::unhex(fields[0]));
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if (b.length() != ZT_ADDRESS_LENGTH)
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return false;
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_address.setTo(b.data(),ZT_ADDRESS_LENGTH);
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b = Utils::base64Decode(fields[2]);
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if ((!b.length())||(b.length() > ZT_EC_MAX_BYTES))
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return false;
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_publicKey.set(b.data(),b.length());
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_signature = Utils::base64Decode(fields[3]);
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if (!_signature.length())
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return false;
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if (fields.size() >= 5) {
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b = Utils::base64Decode(fields[4]);
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if ((!b.length())||(b.length() > ZT_EC_MAX_BYTES))
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return false;
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_keyPair = new EllipticCurveKeyPair(_publicKey,EllipticCurveKey(b.data(),b.length()));
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}
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return true;
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}
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// These are core protocol parameters and can't be changed without a new
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// identity type.
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#define ZT_IDENTITY_DERIVEADDRESS_ROUNDS 4
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#define ZT_IDENTITY_DERIVEADDRESS_MEMORY 33554432
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Address Identity::deriveAddress(const void *keyBytes,unsigned int keyLen)
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{
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unsigned char dig[32];
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Salsa20 s20a,s20b;
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SHA256_CTX sha;
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/*
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* Sequential memory-hard algorithm wedding address to public key
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*
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* Conventional hashcash with long computations and quick verifications
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* unfortunately cannot be used here. If that were used, it would be
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* equivalently costly to simply increment/vary the public key and find
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* a collision as it would be to find the address. We need something
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* that creates a costly 1:~1 mapping from key to address, hence this odd
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* algorithm.
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*
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* This is designed not to be parallelizable and to be resistant to
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* implementation on things like GPUs with tiny-memory nodes and poor
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* branching capability. Toward that end it throws branching and a large
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* memory buffer into the mix. It can only be efficiently computed by a
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* single core with at least ~32MB RAM.
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*
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* Search for "sequential memory hard algorithm" for academic references
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* to similar concepts.
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*
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* Right now this takes ~1700ms on a 2.4ghz Intel Core i5. If this could
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* be reduced to 1ms per derivation, it would take about 34 years to search
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* the entire 40-bit address space for an average of ~17 years to generate
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* a key colliding with a known existing address.
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*/
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// Initial starting digest
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SHA256_Init(&sha);
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SHA256_Update(&sha,(const unsigned char *)keyBytes,keyLen); // key
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SHA256_Final(dig,&sha);
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s20a.init(dig,256,"ZeroTier");
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unsigned char *ram = new unsigned char[ZT_IDENTITY_DERIVEADDRESS_MEMORY];
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// Encrypt and digest a large memory buffer for several rounds
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for(unsigned long i=0;i<ZT_IDENTITY_DERIVEADDRESS_MEMORY;++i)
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ram[i] = (unsigned char)(i & 0xff) ^ dig[i & 31];
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for(unsigned long r=0;r<ZT_IDENTITY_DERIVEADDRESS_ROUNDS;++r) {
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SHA256_Init(&sha);
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SHA256_Update(&sha,(const unsigned char *)keyBytes,keyLen);
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SHA256_Update(&sha,dig,32);
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for(unsigned long i=0;i<ZT_IDENTITY_DERIVEADDRESS_MEMORY;++i) {
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if (ram[i] == 17) // Forces a branch to be required
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ram[i] ^= dig[i & 31];
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}
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s20b.init(dig,256,"ZeroTier");
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s20a.encrypt(ram,ram,ZT_IDENTITY_DERIVEADDRESS_MEMORY);
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s20b.encrypt(ram,ram,ZT_IDENTITY_DERIVEADDRESS_MEMORY);
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SHA256_Update(&sha,ram,ZT_IDENTITY_DERIVEADDRESS_MEMORY);
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SHA256_Final(dig,&sha);
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}
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// Final digest, executed for twice our number of rounds
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SHA256_Init(&sha);
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for(unsigned long r=0;r<(ZT_IDENTITY_DERIVEADDRESS_ROUNDS * 2);++r) {
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SHA256_Update(&sha,(const unsigned char *)keyBytes,keyLen);
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SHA256_Update(&sha,ram,ZT_IDENTITY_DERIVEADDRESS_ROUNDS);
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SHA256_Update(&sha,dig,32);
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SHA256_Update(&sha,(const unsigned char *)keyBytes,keyLen);
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}
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SHA256_Final(dig,&sha);
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delete [] ram;
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return Address(dig,ZT_ADDRESS_LENGTH); // first 5 bytes of dig[]
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}
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} // namespace ZeroTier
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