1160 lines
47 KiB
C++
1160 lines
47 KiB
C++
// Copyright (c) 2022-2023 Zano Project
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// Copyright (c) 2022-2023 sowle (val@zano.org, crypto.sowle@gmail.com)
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// Distributed under the MIT/X11 software license, see the accompanying
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// file COPYING or http://www.opensource.org/licenses/mit-license.php.
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//
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// This file contains implementation of CLSAG (s.a. https://eprint.iacr.org/2019/654.pdf by Goodel at el)
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//
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#include "clsag.h"
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//#include "misc_log_ex.h"
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#include "../currency_core/crypto_config.h"
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DISABLE_GCC_AND_CLANG_WARNING(unused-function)
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namespace crypto
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{
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#if 0
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# define DBG_VAL_PRINT(x) std::cout << std::setw(30) << std::left << #x ": " << x << std::endl
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# define DBG_PRINT(x) std::cout << x << std::endl
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#else
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# define DBG_VAL_PRINT(x) (void(0))
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# define DBG_PRINT(x) (void(0))
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#endif
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static std::ostream &operator <<(std::ostream &o, const crypto::hash &v) { return o << pod_to_hex(v); }
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static std::ostream &operator <<(std::ostream &o, const crypto::public_key &v) { return o << pod_to_hex(v); }
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bool generate_CLSAG_GG(const hash& m, const std::vector<CLSAG_GG_input_ref_t>& ring, const point_t& pseudo_out_amount_commitment, const key_image& ki,
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const scalar_t& secret_x, const scalar_t& secret_f, uint64_t secret_index, CLSAG_GG_signature& sig)
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{
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DBG_PRINT("generate_CLSAG_GG");
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size_t ring_size = ring.size();
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CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
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CRYPTO_CHECK_AND_THROW_MES(secret_index < ring_size, "secret_index is out of range");
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// calculate key images
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point_t ki_base = hash_helper_t::hp(ring[secret_index].stealth_address);
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point_t key_image = secret_x * ki_base;
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CRYPTO_CHECK_AND_THROW_MES(key_image == point_t(ki), "key image 0 mismatch");
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point_t K1_div8 = (c_scalar_1div8 * secret_f) * ki_base;
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K1_div8.to_public_key(sig.K1);
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point_t K1 = K1_div8;
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K1.modify_mul8();
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// calculate aggregation coefficients
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hash_helper_t::hs_t hsc(3 + 2 * ring_size);
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hsc.add_scalar(m);
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for(size_t i = 0; i < ring_size; ++i)
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{
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hsc.add_pub_key(ring[i].stealth_address);
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hsc.add_pub_key(ring[i].amount_commitment);
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}
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hsc.add_point(c_scalar_1div8 * pseudo_out_amount_commitment);
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hsc.add_key_image(ki);
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hash input_hash = hsc.calc_hash_no_reduce();
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GG_LAYER_0);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_0 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_0);
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GG_LAYER_1);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_1 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_1);
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// calculate aggregate pub keys
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std::vector<point_t> W_pub_keys;
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W_pub_keys.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
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{
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W_pub_keys.emplace_back(agg_coeff_0 * point_t(ring[i].stealth_address) + agg_coeff_1 * (point_t(ring[i].amount_commitment).modify_mul8() - pseudo_out_amount_commitment));
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DBG_VAL_PRINT(W_pub_keys[i]);
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}
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// aggregate secret key
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scalar_t w_sec_key = agg_coeff_0 * secret_x + agg_coeff_1 * secret_f;
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// calculate aggregate key image
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point_t W_key_image = agg_coeff_0 * key_image + agg_coeff_1 * K1;
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DBG_VAL_PRINT(W_key_image);
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// initial commitment
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scalar_t alpha = scalar_t::random();
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GG_CHALLENGE);
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hsc.add_hash(input_hash);
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hsc.add_point(alpha * c_point_G);
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hsc.add_point(alpha * ki_base);
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scalar_t c_prev = hsc.calc_hash(); // c_{secret_index + 1}
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sig.r.clear();
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sig.r.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
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sig.r.emplace_back(scalar_t::random());
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for(size_t j = 0, i = (secret_index + 1) % ring_size; j < ring_size - 1; ++j, i = (i + 1) % ring_size)
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{
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if (i == 0)
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sig.c = c_prev; // c_0
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GG_CHALLENGE);
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hsc.add_hash(input_hash);
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hsc.add_point(sig.r[i] * c_point_G + c_prev * W_pub_keys[i]);
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hsc.add_point(sig.r[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image);
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c_prev = hsc.calc_hash(); // c_{i + 1}
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}
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if (secret_index == 0)
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sig.c = c_prev;
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sig.r[secret_index] = alpha - c_prev * w_sec_key;
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return true;
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}
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bool verify_CLSAG_GG(const hash& m, const std::vector<CLSAG_GG_input_ref_t>& ring, const crypto::public_key& pseudo_out_amount_commitment, const key_image& ki,
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const CLSAG_GG_signature& sig)
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{
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DBG_PRINT("verify_CLSAG_GG");
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size_t ring_size = ring.size();
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CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
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CRYPTO_CHECK_AND_THROW_MES(ring_size == sig.r.size(), "ring size != r size");
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point_t key_image(ki);
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CRYPTO_CHECK_AND_THROW_MES(key_image.is_in_main_subgroup(), "key image 0 does not belong to the main subgroup");
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point_t pseudo_out_amount_commitment_pt(pseudo_out_amount_commitment);
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pseudo_out_amount_commitment_pt.modify_mul8();
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// calculate aggregation coefficients
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hash_helper_t::hs_t hsc(3 + 2 * ring_size);
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hsc.add_scalar(m);
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for(size_t i = 0; i < ring_size; ++i)
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{
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hsc.add_pub_key(ring[i].stealth_address);
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hsc.add_pub_key(ring[i].amount_commitment);
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}
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hsc.add_pub_key(pseudo_out_amount_commitment);
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hsc.add_key_image(ki);
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hash input_hash = hsc.calc_hash_no_reduce();
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GG_LAYER_0);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_0 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_0);
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GG_LAYER_1);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_1 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_1);
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// calculate aggregate pub keys
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std::vector<point_t> W_pub_keys;
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W_pub_keys.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
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{
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W_pub_keys.emplace_back(agg_coeff_0 * point_t(ring[i].stealth_address) + agg_coeff_1 * (point_t(ring[i].amount_commitment).modify_mul8() - pseudo_out_amount_commitment_pt));
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DBG_VAL_PRINT(W_pub_keys[i]);
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}
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// calculate aggregate key image
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point_t W_key_image = agg_coeff_0 * key_image + agg_coeff_1 * point_t(sig.K1).modify_mul8();
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DBG_VAL_PRINT(W_key_image);
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scalar_t c_prev = sig.c;
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for(size_t i = 0; i < ring_size; ++i)
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{
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GG_CHALLENGE);
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hsc.add_hash(input_hash);
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hsc.add_point(sig.r[i] * c_point_G + c_prev * W_pub_keys[i]);
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hsc.add_point(sig.r[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image);
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c_prev = hsc.calc_hash(); // c_{i + 1}
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}
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return c_prev == sig.c;
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}
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//---------------------------------------------------------------
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//
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// Disclaimer: extensions to the CLSAG implemented below are non-standard and are in proof-of-concept state.
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// They shouldn't be used in production code until formal security proofs are done and (ideally) the code is peer-reviewed.
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// -- sowle
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//
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bool generate_CLSAG_GGX(const hash& m, const std::vector<CLSAG_GGX_input_ref_t>& ring, const point_t& pseudo_out_amount_commitment, const point_t& pseudo_out_blinded_asset_id, const key_image& ki,
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const scalar_t& secret_0_xp, const scalar_t& secret_1_f, const scalar_t& secret_2_t, uint64_t secret_index, CLSAG_GGX_signature& sig)
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{
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DBG_PRINT("== generate_CLSAG_GGX ==");
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size_t ring_size = ring.size();
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CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
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CRYPTO_CHECK_AND_THROW_MES(secret_index < ring_size, "secret_index is out of range");
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// calculate key images
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point_t ki_base = hash_helper_t::hp(ring[secret_index].stealth_address);
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point_t key_image = secret_0_xp * ki_base;
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#ifndef NDEBUG
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CRYPTO_CHECK_AND_THROW_MES(key_image == point_t(ki), "key image 0 mismatch");
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CRYPTO_CHECK_AND_THROW_MES((secret_0_xp * c_point_G).to_public_key() == ring[secret_index].stealth_address, "secret_0_xp mismatch");
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CRYPTO_CHECK_AND_THROW_MES( secret_1_f * c_point_G == 8 * point_t(ring[secret_index].amount_commitment) - pseudo_out_amount_commitment, "secret_1_f mismatch");
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CRYPTO_CHECK_AND_THROW_MES( secret_2_t * c_point_X == 8 * point_t(ring[secret_index].blinded_asset_id) - pseudo_out_blinded_asset_id, "secret_2_t mismatch");
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//CRYPTO_CHECK_AND_THROW_MES( secret_3_q * c_point_G == 8 * point_t(ring[secret_index].concealing_point), "");
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//CRYPTO_CHECK_AND_THROW_MES( secret_4_x * c_point_X == extended_amount_commitment - 8 * point_t(ring[secret_index].amount_commitment) - 8 * point_t(ring[secret_index].concealing_point), "");
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#endif
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point_t K1_div8 = (c_scalar_1div8 * secret_1_f) * ki_base;
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K1_div8.to_public_key(sig.K1);
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point_t K1 = K1_div8;
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K1.modify_mul8();
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point_t K2_div8 = (c_scalar_1div8 * secret_2_t) * ki_base;
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K2_div8.to_public_key(sig.K2);
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point_t K2 = K2_div8;
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K2.modify_mul8();
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//point_t K3_div8 = (c_scalar_1div8 * secret_3_q) * ki_base;
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//K3_div8.to_public_key(sig.K3);
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//point_t K3 = K3_div8;
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//K3.modify_mul8();
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//point_t K4_div8 = (c_scalar_1div8 * secret_4_x) * ki_base;
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//K4_div8.to_public_key(sig.K4);
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//point_t K4 = K4_div8;
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//K4.modify_mul8();
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// calculate aggregation coefficients
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hash_helper_t::hs_t hsc(4 + 3 * ring_size);
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hsc.add_scalar(m);
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for(size_t i = 0; i < ring_size; ++i)
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{
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hsc.add_pub_key(ring[i].stealth_address);
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hsc.add_pub_key(ring[i].amount_commitment);
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hsc.add_pub_key(ring[i].blinded_asset_id);
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DBG_PRINT("ring[" << i << "]: sa:" << ring[i].stealth_address << ", ac:" << ring[i].amount_commitment << ", baid:" << ring[i].blinded_asset_id);
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}
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hsc.add_point(c_scalar_1div8 * pseudo_out_amount_commitment);
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hsc.add_point(c_scalar_1div8 * pseudo_out_blinded_asset_id);
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hsc.add_key_image(ki);
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hash input_hash = hsc.calc_hash_no_reduce();
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DBG_VAL_PRINT(input_hash);
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_0);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_0 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_0);
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_1);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_1 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_1);
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// may we get rid of it?
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_2);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_2 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_2);
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//hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_3);
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//hsc.add_hash(input_hash);
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//scalar_t agg_coeff_3 = hsc.calc_hash();
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//DBG_VAL_PRINT(agg_coeff_3);
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// prepare A_i, Q_i
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std::vector<point_t> A_i, Q_i;
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A_i.reserve(ring_size), Q_i.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
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{
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A_i.emplace_back(ring[i].amount_commitment);
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A_i.back().modify_mul8();
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Q_i.emplace_back(ring[i].blinded_asset_id);
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Q_i.back().modify_mul8();
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DBG_PRINT("A_i[" << i << "] = " << A_i[i] << " Q_i[" << i << "] = " << Q_i[i]);
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}
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// calculate aggregate pub keys (layers 0, 1; G components)
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std::vector<point_t> W_pub_keys_g;
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W_pub_keys_g.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
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{
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W_pub_keys_g.emplace_back(
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agg_coeff_0 * point_t(ring[i].stealth_address) +
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agg_coeff_1 * (A_i[i] - pseudo_out_amount_commitment)
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);
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DBG_VAL_PRINT(W_pub_keys_g[i]);
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}
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// calculate aggregate pub keys (layer 2; X component)
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std::vector<point_t> W_pub_keys_x;
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W_pub_keys_x.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
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{
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W_pub_keys_x.emplace_back(
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agg_coeff_2 * (Q_i[i] - pseudo_out_blinded_asset_id)
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);
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DBG_VAL_PRINT(W_pub_keys_x[i]);
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}
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// aggregate secret key (layers 0, 1; G component)
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scalar_t w_sec_key_g = agg_coeff_0 * secret_0_xp + agg_coeff_1 * secret_1_f; // + agg_coeff_3 * secret_3_q;
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DBG_VAL_PRINT(w_sec_key_g * c_point_G);
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// aggregate secret key (layer 2; X component)
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scalar_t w_sec_key_x = agg_coeff_2 * secret_2_t;
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DBG_VAL_PRINT(w_sec_key_x * c_point_X);
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// calculate aggregate key image (layers 0, 1, 3; G component)
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point_t W_key_image_g = agg_coeff_0 * key_image + agg_coeff_1 * K1 /* + agg_coeff_3 * K3 */;
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DBG_VAL_PRINT(key_image);
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DBG_VAL_PRINT(K1);
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//DBG_VAL_PRINT(K3);
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DBG_VAL_PRINT(W_key_image_g);
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// calculate aggregate key image (layer 2; X component)
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point_t W_key_image_x = agg_coeff_2 * K2;
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DBG_VAL_PRINT(K2);
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DBG_VAL_PRINT(W_key_image_x);
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#ifndef NDEBUG
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CRYPTO_CHECK_AND_THROW_MES(w_sec_key_g * c_point_G == W_pub_keys_g[secret_index], "aggregated secret G and pub key mismatch");
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CRYPTO_CHECK_AND_THROW_MES(w_sec_key_g * hash_helper_t::hp(ring[secret_index].stealth_address) == W_key_image_g, "aggregated secret G and key image mismatch");
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CRYPTO_CHECK_AND_THROW_MES(w_sec_key_x * c_point_X == W_pub_keys_x[secret_index], "aggregated secret X and pub key mismatch");
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CRYPTO_CHECK_AND_THROW_MES(w_sec_key_x * hash_helper_t::hp(ring[secret_index].stealth_address) == W_key_image_x, "aggregated secret X and key image mismatch");
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#endif
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// initial commitment
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scalar_t alpha_g = scalar_t::random(); // randomness for layers 0,1
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scalar_t alpha_x = scalar_t::random(); // randomness for layer 2
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_CHALLENGE);
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hsc.add_hash(input_hash);
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hsc.add_point(alpha_g * c_point_G);
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hsc.add_point(alpha_g * ki_base);
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hsc.add_point(alpha_x * c_point_X);
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hsc.add_point(alpha_x * ki_base);
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//DBG_PRINT("c[" << secret_index << "] = Hs(ih, " << alpha_g * c_point_G << ", " << alpha_g * ki_base << ", " << alpha_x * c_point_X << ", " << alpha_x * ki_base << ")");
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scalar_t c_prev = hsc.calc_hash(); // c_{secret_index + 1}
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sig.r_g.clear();
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sig.r_x.clear();
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sig.r_g.reserve(ring_size);
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sig.r_x.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
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{
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sig.r_g.emplace_back(scalar_t::random());
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sig.r_x.emplace_back(scalar_t::random());
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}
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for(size_t j = 0, i = (secret_index + 1) % ring_size; j < ring_size - 1; ++j, i = (i + 1) % ring_size)
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{
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DBG_PRINT("c[" << i << "] = " << c_prev);
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if (i == 0)
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sig.c = c_prev; // c_0
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_CHALLENGE);
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hsc.add_hash(input_hash);
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hsc.add_point(sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i]);
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hsc.add_point(sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g);
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hsc.add_point(sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i]);
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hsc.add_point(sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x);
|
|
c_prev = hsc.calc_hash(); // c_{i + 1}
|
|
}
|
|
DBG_PRINT("c[" << secret_index << "] = " << c_prev);
|
|
|
|
if (secret_index == 0)
|
|
sig.c = c_prev;
|
|
|
|
sig.r_g[secret_index] = alpha_g - c_prev * w_sec_key_g;
|
|
sig.r_x[secret_index] = alpha_x - c_prev * w_sec_key_x;
|
|
|
|
return true;
|
|
}
|
|
|
|
bool verify_CLSAG_GGX(const hash& m, const std::vector<CLSAG_GGX_input_ref_t>& ring, const public_key& pseudo_out_amount_commitment,
|
|
const public_key& pseudo_out_blinded_asset_id, const key_image& ki, const CLSAG_GGX_signature& sig)
|
|
{
|
|
DBG_PRINT("== verify_CLSAG_GGX ==");
|
|
size_t ring_size = ring.size();
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size == sig.r_g.size(), "ring size != r_g size");
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size == sig.r_x.size(), "ring size != r_x size");
|
|
|
|
point_t key_image(ki);
|
|
CRYPTO_CHECK_AND_THROW_MES(key_image.is_in_main_subgroup(), "key image 0 does not belong to the main subgroup");
|
|
|
|
point_t pseudo_out_amount_commitment_pt(pseudo_out_amount_commitment);
|
|
pseudo_out_amount_commitment_pt.modify_mul8();
|
|
|
|
point_t pseudo_out_blinded_asset_id_pt(pseudo_out_blinded_asset_id);
|
|
pseudo_out_blinded_asset_id_pt.modify_mul8();
|
|
|
|
// calculate aggregation coefficients
|
|
hash_helper_t::hs_t hsc(4 + 3 * ring_size);
|
|
hsc.add_scalar(m);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_pub_key(ring[i].stealth_address);
|
|
hsc.add_pub_key(ring[i].amount_commitment);
|
|
hsc.add_pub_key(ring[i].blinded_asset_id);
|
|
DBG_PRINT("ring[" << i << "]: sa:" << ring[i].stealth_address << ", ac:" << ring[i].amount_commitment << ", baid:" << ring[i].blinded_asset_id);
|
|
}
|
|
hsc.add_pub_key(pseudo_out_amount_commitment);
|
|
hsc.add_pub_key(pseudo_out_blinded_asset_id);
|
|
hsc.add_key_image(ki);
|
|
hash input_hash = hsc.calc_hash_no_reduce();
|
|
DBG_VAL_PRINT(input_hash);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_0);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_0 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_0);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_1);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_1 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_1);
|
|
|
|
// may we get rid of it?
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_2);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_2 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_2);
|
|
|
|
//hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_LAYER_3);
|
|
//hsc.add_hash(input_hash);
|
|
//scalar_t agg_coeff_3 = hsc.calc_hash();
|
|
//DBG_VAL_PRINT(agg_coeff_3);
|
|
|
|
// prepare A_i, Q_i
|
|
std::vector<point_t> A_i, Q_i;
|
|
A_i.reserve(ring_size), Q_i.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
A_i.emplace_back(ring[i].amount_commitment);
|
|
A_i.back().modify_mul8();
|
|
Q_i.emplace_back(ring[i].blinded_asset_id);
|
|
Q_i.back().modify_mul8();
|
|
DBG_PRINT("A_i[" << i << "] = " << A_i[i] << " Q_i[" << i << "] = " << Q_i[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layers 0, 1; G components)
|
|
std::vector<point_t> W_pub_keys_g;
|
|
W_pub_keys_g.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_g.emplace_back(
|
|
agg_coeff_0 * point_t(ring[i].stealth_address) +
|
|
agg_coeff_1 * (A_i[i] - pseudo_out_amount_commitment_pt)
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_g[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layer 2; X component)
|
|
std::vector<point_t> W_pub_keys_x;
|
|
W_pub_keys_x.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_x.emplace_back(
|
|
agg_coeff_2 * (Q_i[i] - pseudo_out_blinded_asset_id_pt)
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_x[i]);
|
|
}
|
|
|
|
// calculate aggregate key image (layers 0, 1, 3; G components)
|
|
point_t W_key_image_g =
|
|
agg_coeff_0 * key_image +
|
|
agg_coeff_1 * point_t(sig.K1).modify_mul8();
|
|
// agg_coeff_3 * point_t(sig.K3).modify_mul8();
|
|
DBG_VAL_PRINT(point_t(sig.K1).modify_mul8());
|
|
//DBG_VAL_PRINT(point_t(sig.K3).modify_mul8());
|
|
DBG_VAL_PRINT(W_key_image_g);
|
|
|
|
// calculate aggregate key image (layer 2; X component)
|
|
point_t W_key_image_x =
|
|
agg_coeff_2 * point_t(sig.K2).modify_mul8();
|
|
DBG_VAL_PRINT(point_t(sig.K2).modify_mul8());
|
|
DBG_VAL_PRINT(W_key_image_x);
|
|
|
|
|
|
scalar_t c_prev = sig.c;
|
|
DBG_PRINT("c[0] = " << c_prev);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGX_CHALLENGE);
|
|
hsc.add_hash(input_hash);
|
|
hsc.add_point(sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i]);
|
|
hsc.add_point(sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g);
|
|
hsc.add_point(sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i]);
|
|
hsc.add_point(sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x);
|
|
c_prev = hsc.calc_hash(); // c_{i + 1}
|
|
DBG_PRINT("c[" << i + 1 << "] = " << c_prev);
|
|
//DBG_PRINT("c[" << i + 1 << "] = Hs(ih, " << sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i] << ", " << sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g << ", " << sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i] << ", " << sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x << ")");
|
|
}
|
|
|
|
return c_prev == sig.c;
|
|
}
|
|
|
|
|
|
//---------------------------------------------------------------
|
|
|
|
|
|
bool generate_CLSAG_GGXG(const hash& m, const std::vector<CLSAG_GGXG_input_ref_t>& ring, const point_t& pseudo_out_amount_commitment, const point_t& extended_amount_commitment, const key_image& ki,
|
|
const scalar_t& secret_0_xp, const scalar_t& secret_1_f, const scalar_t& secret_2_x, const scalar_t& secret_3_q, uint64_t secret_index, CLSAG_GGXG_signature& sig)
|
|
{
|
|
DBG_PRINT("== generate_CLSAG_GGXG ==");
|
|
size_t ring_size = ring.size();
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
|
|
CRYPTO_CHECK_AND_THROW_MES(secret_index < ring_size, "secret_index is out of range");
|
|
|
|
// calculate key images
|
|
point_t ki_base = hash_helper_t::hp(ring[secret_index].stealth_address);
|
|
point_t key_image = secret_0_xp * ki_base;
|
|
|
|
#ifndef NDEBUG
|
|
CRYPTO_CHECK_AND_THROW_MES(key_image == point_t(ki), "key image 0 mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES((secret_0_xp * c_point_G).to_public_key() == ring[secret_index].stealth_address, "secret_0_xp mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(secret_1_f * c_point_G == 8 * point_t(ring[secret_index].amount_commitment) - pseudo_out_amount_commitment, "secret_1_f mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(secret_3_q * c_point_G == 8 * point_t(ring[secret_index].concealing_point), "secret_3_q mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(secret_2_x * c_point_X == extended_amount_commitment - 8 * point_t(ring[secret_index].amount_commitment) - 8 * point_t(ring[secret_index].concealing_point), "secret_2_x mismatch");
|
|
#endif
|
|
|
|
point_t K1_div8 = (c_scalar_1div8 * secret_1_f) * ki_base;
|
|
K1_div8.to_public_key(sig.K1);
|
|
point_t K1 = K1_div8;
|
|
K1.modify_mul8();
|
|
|
|
point_t K2_div8 = (c_scalar_1div8 * secret_2_x) * ki_base;
|
|
K2_div8.to_public_key(sig.K2);
|
|
point_t K2 = K2_div8;
|
|
K2.modify_mul8();
|
|
|
|
point_t K3_div8 = (c_scalar_1div8 * secret_3_q) * ki_base;
|
|
K3_div8.to_public_key(sig.K3);
|
|
point_t K3 = K3_div8;
|
|
K3.modify_mul8();
|
|
|
|
// calculate aggregation coefficients
|
|
hash_helper_t::hs_t hsc(4 + 3 * ring_size);
|
|
hsc.add_scalar(m);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_pub_key(ring[i].stealth_address);
|
|
hsc.add_pub_key(ring[i].amount_commitment);
|
|
hsc.add_pub_key(ring[i].concealing_point);
|
|
DBG_PRINT("ring[" << i << "]: sa:" << ring[i].stealth_address << ", ac:" << ring[i].amount_commitment << ", cp:" << ring[i].concealing_point);
|
|
}
|
|
hsc.add_point(c_scalar_1div8 * pseudo_out_amount_commitment);
|
|
hsc.add_point(c_scalar_1div8 * extended_amount_commitment);
|
|
hsc.add_key_image(ki);
|
|
hash input_hash = hsc.calc_hash_no_reduce();
|
|
DBG_VAL_PRINT(input_hash);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_0);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_0 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_0);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_1);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_1 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_1);
|
|
|
|
// may we get rid of it?
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_2);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_2 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_2);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_3);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_3 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_3);
|
|
|
|
// prepare A_i, Q_i
|
|
std::vector<point_t> A_i, Q_i;
|
|
A_i.reserve(ring_size), Q_i.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
A_i.emplace_back(ring[i].amount_commitment);
|
|
A_i.back().modify_mul8();
|
|
Q_i.emplace_back(ring[i].concealing_point);
|
|
Q_i.back().modify_mul8();
|
|
DBG_PRINT("A_i[" << i << "] = " << A_i[i] << " Q_i[" << i << "] = " << Q_i[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layers 0, 1, 3; G components)
|
|
std::vector<point_t> W_pub_keys_g;
|
|
W_pub_keys_g.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_g.emplace_back(
|
|
agg_coeff_0 * point_t(ring[i].stealth_address) +
|
|
agg_coeff_1 * (A_i[i] - pseudo_out_amount_commitment) +
|
|
agg_coeff_3 * Q_i[i]
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_g[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layer 2; X component)
|
|
std::vector<point_t> W_pub_keys_x;
|
|
W_pub_keys_x.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_x.emplace_back(
|
|
agg_coeff_2 * (extended_amount_commitment - A_i[i] - Q_i[i])
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_x[i]);
|
|
}
|
|
|
|
// aggregate secret key (layers 0, 1, 3; G component)
|
|
scalar_t w_sec_key_g = agg_coeff_0 * secret_0_xp + agg_coeff_1 * secret_1_f + agg_coeff_3 * secret_3_q;
|
|
DBG_VAL_PRINT(w_sec_key_g * c_point_G);
|
|
|
|
// aggregate secret key (layer 2; X component)
|
|
scalar_t w_sec_key_x = agg_coeff_2 * secret_2_x;
|
|
DBG_VAL_PRINT(w_sec_key_x * c_point_X);
|
|
|
|
// calculate aggregate key image (layers 0, 1, 3; G component)
|
|
point_t W_key_image_g = agg_coeff_0 * key_image + agg_coeff_1 * K1 + /*agg_coeff_2 * K2 +*/ agg_coeff_3 * K3;
|
|
DBG_VAL_PRINT(key_image);
|
|
DBG_VAL_PRINT(K1);
|
|
DBG_VAL_PRINT(K3);
|
|
DBG_VAL_PRINT(W_key_image_g);
|
|
|
|
// calculate aggregate key image (layer 2; X component)
|
|
point_t W_key_image_x = agg_coeff_2 * K2;
|
|
DBG_VAL_PRINT(K2);
|
|
DBG_VAL_PRINT(W_key_image_x);
|
|
|
|
#ifndef NDEBUG
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_g * c_point_G == W_pub_keys_g[secret_index], "aggregated secret G and pub key mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_g * hash_helper_t::hp(ring[secret_index].stealth_address) == W_key_image_g, "aggregated secret G and key image mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_x * c_point_X == W_pub_keys_x[secret_index], "aggregated secret X and pub key mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_x * hash_helper_t::hp(ring[secret_index].stealth_address) == W_key_image_x, "aggregated secret X and key image mismatch");
|
|
#endif
|
|
|
|
// initial commitment
|
|
scalar_t alpha_g = scalar_t::random(); // randomness for layers 0,1,3
|
|
scalar_t alpha_x = scalar_t::random(); // randomness for layer 2
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_CHALLENGE);
|
|
hsc.add_hash(input_hash);
|
|
hsc.add_point(alpha_g * c_point_G);
|
|
hsc.add_point(alpha_g * ki_base);
|
|
hsc.add_point(alpha_x * c_point_X);
|
|
hsc.add_point(alpha_x * ki_base);
|
|
//DBG_PRINT("c[" << secret_index << "] = Hs(ih, " << alpha_g * c_point_G << ", " << alpha_g * ki_base << ", " << alpha_x * c_point_X << ", " << alpha_x * ki_base << ")");
|
|
scalar_t c_prev = hsc.calc_hash(); // c_{secret_index + 1}
|
|
|
|
sig.r_g.clear();
|
|
sig.r_x.clear();
|
|
sig.r_g.reserve(ring_size);
|
|
sig.r_x.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
sig.r_g.emplace_back(scalar_t::random());
|
|
sig.r_x.emplace_back(scalar_t::random());
|
|
}
|
|
|
|
for(size_t j = 0, i = (secret_index + 1) % ring_size; j < ring_size - 1; ++j, i = (i + 1) % ring_size)
|
|
{
|
|
DBG_PRINT("c[" << i << "] = " << c_prev);
|
|
if (i == 0)
|
|
sig.c = c_prev; // c_0
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_CHALLENGE);
|
|
hsc.add_hash(input_hash);
|
|
hsc.add_point(sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i]);
|
|
hsc.add_point(sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g);
|
|
hsc.add_point(sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i]);
|
|
hsc.add_point(sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x);
|
|
c_prev = hsc.calc_hash(); // c_{i + 1}
|
|
}
|
|
DBG_PRINT("c[" << secret_index << "] = " << c_prev);
|
|
|
|
if (secret_index == 0)
|
|
sig.c = c_prev;
|
|
|
|
sig.r_g[secret_index] = alpha_g - c_prev * w_sec_key_g;
|
|
sig.r_x[secret_index] = alpha_x - c_prev * w_sec_key_x;
|
|
|
|
return true;
|
|
}
|
|
|
|
|
|
bool verify_CLSAG_GGXG(const hash& m, const std::vector<CLSAG_GGXG_input_ref_t>& ring, const public_key& pseudo_out_amount_commitment, const public_key& extended_amount_commitment,
|
|
const key_image& ki, const CLSAG_GGXG_signature& sig)
|
|
{
|
|
DBG_PRINT("== verify_CLSAG_GGXG ==");
|
|
size_t ring_size = ring.size();
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size == sig.r_g.size(), "ring size != r_g size");
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size == sig.r_x.size(), "ring size != r_x size");
|
|
|
|
point_t key_image(ki);
|
|
CRYPTO_CHECK_AND_THROW_MES(key_image.is_in_main_subgroup(), "key image 0 does not belong to the main subgroup");
|
|
|
|
point_t pseudo_out_amount_commitment_pt(pseudo_out_amount_commitment);
|
|
pseudo_out_amount_commitment_pt.modify_mul8();
|
|
|
|
point_t extended_amount_commitment_pt(extended_amount_commitment);
|
|
extended_amount_commitment_pt.modify_mul8();
|
|
|
|
// calculate aggregation coefficients
|
|
hash_helper_t::hs_t hsc(4 + 3 * ring_size);
|
|
hsc.add_scalar(m);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_pub_key(ring[i].stealth_address);
|
|
hsc.add_pub_key(ring[i].amount_commitment);
|
|
hsc.add_pub_key(ring[i].concealing_point);
|
|
DBG_PRINT("ring[" << i << "]: sa:" << ring[i].stealth_address << ", ac:" << ring[i].amount_commitment << ", cp:" << ring[i].concealing_point);
|
|
}
|
|
hsc.add_pub_key(pseudo_out_amount_commitment);
|
|
hsc.add_pub_key(extended_amount_commitment);
|
|
hsc.add_key_image(ki);
|
|
hash input_hash = hsc.calc_hash_no_reduce();
|
|
DBG_VAL_PRINT(input_hash);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_0);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_0 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_0);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_1);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_1 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_1);
|
|
|
|
// may we get rid of it?
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_2);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_2 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_2);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_LAYER_3);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_3 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_3);
|
|
|
|
// prepare A_i, Q_i
|
|
std::vector<point_t> A_i, Q_i;
|
|
A_i.reserve(ring_size), Q_i.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
A_i.emplace_back(ring[i].amount_commitment);
|
|
A_i.back().modify_mul8();
|
|
Q_i.emplace_back(ring[i].concealing_point);
|
|
Q_i.back().modify_mul8();
|
|
DBG_PRINT("A_i[" << i << "] = " << A_i[i] << " Q_i[" << i << "] = " << Q_i[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layers 0, 1, 3; G components)
|
|
std::vector<point_t> W_pub_keys_g;
|
|
W_pub_keys_g.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_g.emplace_back(
|
|
agg_coeff_0 * point_t(ring[i].stealth_address) +
|
|
agg_coeff_1 * (A_i[i] - pseudo_out_amount_commitment_pt) +
|
|
agg_coeff_3 * Q_i[i]
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_g[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layer 2; X component)
|
|
std::vector<point_t> W_pub_keys_x;
|
|
W_pub_keys_x.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_x.emplace_back(
|
|
agg_coeff_2 * (extended_amount_commitment_pt - A_i[i] - Q_i[i])
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_x[i]);
|
|
}
|
|
|
|
// calculate aggregate key image (layers 0, 1, 3; G components)
|
|
point_t W_key_image_g =
|
|
agg_coeff_0 * key_image +
|
|
agg_coeff_1 * point_t(sig.K1).modify_mul8() +
|
|
agg_coeff_3 * point_t(sig.K3).modify_mul8();
|
|
DBG_VAL_PRINT(point_t(sig.K1).modify_mul8());
|
|
DBG_VAL_PRINT(point_t(sig.K3).modify_mul8());
|
|
DBG_VAL_PRINT(W_key_image_g);
|
|
|
|
// calculate aggregate key image (layer 2; X component)
|
|
point_t W_key_image_x =
|
|
agg_coeff_2 * point_t(sig.K2).modify_mul8();
|
|
DBG_VAL_PRINT(point_t(sig.K2).modify_mul8());
|
|
DBG_VAL_PRINT(W_key_image_x);
|
|
|
|
|
|
scalar_t c_prev = sig.c;
|
|
DBG_PRINT("c[0] = " << c_prev);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXG_CHALLENGE);
|
|
hsc.add_hash(input_hash);
|
|
hsc.add_point(sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i]);
|
|
hsc.add_point(sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g);
|
|
hsc.add_point(sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i]);
|
|
hsc.add_point(sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x);
|
|
c_prev = hsc.calc_hash(); // c_{i + 1}
|
|
DBG_PRINT("c[" << i + 1 << "] = " << c_prev);
|
|
//DBG_PRINT("c[" << i + 1 << "] = Hs(ih, " << sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i] << ", " << sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g << ", " << sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i] << ", " << sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x << ")");
|
|
}
|
|
|
|
return c_prev == sig.c;
|
|
}
|
|
|
|
|
|
//---------------------------------------------------------------
|
|
|
|
|
|
bool generate_CLSAG_GGXXG(const hash& m, const std::vector<CLSAG_GGXXG_input_ref_t>& ring, const point_t& pseudo_out_amount_commitment, const point_t& pseudo_out_blinded_asset_id, const point_t& extended_amount_commitment, const key_image& ki,
|
|
const scalar_t& secret_0_xp, const scalar_t& secret_1_f, const scalar_t& secret_2_t, const scalar_t& secret_3_x, const scalar_t& secret_4_q, uint64_t secret_index,
|
|
CLSAG_GGXXG_signature& sig)
|
|
{
|
|
DBG_PRINT("== generate_CLSAG_GGXXG ==");
|
|
size_t ring_size = ring.size();
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
|
|
CRYPTO_CHECK_AND_THROW_MES(secret_index < ring_size, "secret_index is out of range");
|
|
|
|
// calculate key images
|
|
point_t ki_base = hash_helper_t::hp(ring[secret_index].stealth_address);
|
|
point_t key_image = secret_0_xp * ki_base;
|
|
|
|
#ifndef NDEBUG
|
|
CRYPTO_CHECK_AND_THROW_MES(key_image == point_t(ki), "key image 0 mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES((secret_0_xp * c_point_G).to_public_key() == ring[secret_index].stealth_address, "secret_0_xp mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES( secret_1_f * c_point_G == 8 * point_t(ring[secret_index].amount_commitment) - pseudo_out_amount_commitment, "secret_1_f mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES( secret_2_t * c_point_X == 8 * point_t(ring[secret_index].blinded_asset_id) - pseudo_out_blinded_asset_id, "secret_2_t mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES( secret_3_x * c_point_X == extended_amount_commitment - 8 * point_t(ring[secret_index].amount_commitment) - 8 * point_t(ring[secret_index].concealing_point), "");
|
|
CRYPTO_CHECK_AND_THROW_MES( secret_4_q * c_point_G == 8 * point_t(ring[secret_index].concealing_point), "secret_3_q mismatch");
|
|
#endif
|
|
|
|
point_t K1_div8 = (c_scalar_1div8 * secret_1_f) * ki_base;
|
|
K1_div8.to_public_key(sig.K1);
|
|
point_t K1 = K1_div8;
|
|
K1.modify_mul8();
|
|
|
|
point_t K2_div8 = (c_scalar_1div8 * secret_2_t) * ki_base;
|
|
K2_div8.to_public_key(sig.K2);
|
|
point_t K2 = K2_div8;
|
|
K2.modify_mul8();
|
|
|
|
point_t K3_div8 = (c_scalar_1div8 * secret_3_x) * ki_base;
|
|
K3_div8.to_public_key(sig.K3);
|
|
point_t K3 = K3_div8;
|
|
K3.modify_mul8();
|
|
|
|
point_t K4_div8 = (c_scalar_1div8 * secret_4_q) * ki_base;
|
|
K4_div8.to_public_key(sig.K4);
|
|
point_t K4 = K4_div8;
|
|
K4.modify_mul8();
|
|
|
|
// calculate aggregation coefficients
|
|
hash_helper_t::hs_t hsc(5 + 4 * ring_size);
|
|
hsc.add_scalar(m);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_pub_key(ring[i].stealth_address);
|
|
hsc.add_pub_key(ring[i].amount_commitment);
|
|
hsc.add_pub_key(ring[i].blinded_asset_id);
|
|
hsc.add_pub_key(ring[i].concealing_point);
|
|
DBG_PRINT("ring[" << i << "]: sa:" << ring[i].stealth_address << ", ac:" << ring[i].amount_commitment << ", baid:" << ring[i].blinded_asset_id << ", cp:" << ring[i].concealing_point);
|
|
}
|
|
hsc.add_point(c_scalar_1div8 * pseudo_out_amount_commitment);
|
|
hsc.add_point(c_scalar_1div8 * pseudo_out_blinded_asset_id);
|
|
hsc.add_point(c_scalar_1div8 * extended_amount_commitment);
|
|
hsc.add_key_image(ki);
|
|
hash input_hash = hsc.calc_hash_no_reduce();
|
|
DBG_VAL_PRINT(input_hash);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_0);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_0 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_0);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_1);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_1 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_1);
|
|
|
|
// may we get rid of it?
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_2);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_2 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_2);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_3);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_3 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_3);
|
|
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_4);
|
|
hsc.add_hash(input_hash);
|
|
scalar_t agg_coeff_4 = hsc.calc_hash();
|
|
DBG_VAL_PRINT(agg_coeff_4);
|
|
|
|
// prepare A_i, Q_i
|
|
std::vector<point_t> A_i, P_i, Q_i;
|
|
A_i.reserve(ring_size), P_i.reserve(ring_size), Q_i.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
A_i.emplace_back(ring[i].amount_commitment);
|
|
A_i.back().modify_mul8();
|
|
P_i.emplace_back(ring[i].blinded_asset_id);
|
|
P_i.back().modify_mul8();
|
|
Q_i.emplace_back(ring[i].concealing_point);
|
|
Q_i.back().modify_mul8();
|
|
DBG_PRINT("A_i[" << i << "] = " << A_i[i] << " P_i[" << i << "] = " << P_i[i] << " Q_i[" << i << "] = " << Q_i[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layers 0, 1, 4; G components)
|
|
std::vector<point_t> W_pub_keys_g;
|
|
W_pub_keys_g.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_g.emplace_back(
|
|
agg_coeff_0 * point_t(ring[i].stealth_address) +
|
|
agg_coeff_1 * (A_i[i] - pseudo_out_amount_commitment) +
|
|
agg_coeff_4 * Q_i[i]
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_g[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layerx 2, 3; X component)
|
|
std::vector<point_t> W_pub_keys_x;
|
|
W_pub_keys_x.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_x.emplace_back(
|
|
agg_coeff_2 * (P_i[i] - pseudo_out_blinded_asset_id) +
|
|
agg_coeff_3 * (extended_amount_commitment - A_i[i] - Q_i[i])
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_x[i]);
|
|
}
|
|
|
|
// aggregate secret key (layers 0, 1, 4; G component)
|
|
scalar_t w_sec_key_g = agg_coeff_0 * secret_0_xp + agg_coeff_1 * secret_1_f + agg_coeff_4 * secret_4_q;
|
|
DBG_VAL_PRINT(w_sec_key_g * c_point_G);
|
|
|
|
// aggregate secret key (layer 2, 3; X component)
|
|
scalar_t w_sec_key_x = agg_coeff_2 * secret_2_t + agg_coeff_3 * secret_3_x;
|
|
DBG_VAL_PRINT(w_sec_key_x * c_point_X);
|
|
|
|
// calculate aggregate key image (layers 0, 1, 4; G component)
|
|
point_t W_key_image_g = agg_coeff_0 * key_image + agg_coeff_1 * K1 + agg_coeff_4 * K4;
|
|
DBG_VAL_PRINT(key_image);
|
|
DBG_VAL_PRINT(K1);
|
|
DBG_VAL_PRINT(K4);
|
|
DBG_VAL_PRINT(W_key_image_g);
|
|
|
|
// calculate aggregate key image (layer 2, 3; X component)
|
|
point_t W_key_image_x = agg_coeff_2 * K2 + agg_coeff_3 * K3;
|
|
DBG_VAL_PRINT(K2);
|
|
DBG_VAL_PRINT(K3);
|
|
DBG_VAL_PRINT(W_key_image_x);
|
|
|
|
#ifndef NDEBUG
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_g * c_point_G == W_pub_keys_g[secret_index], "aggregated secret G and pub key mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_g * hash_helper_t::hp(ring[secret_index].stealth_address) == W_key_image_g, "aggregated secret G and key image mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_x * c_point_X == W_pub_keys_x[secret_index], "aggregated secret X and pub key mismatch");
|
|
CRYPTO_CHECK_AND_THROW_MES(w_sec_key_x * hash_helper_t::hp(ring[secret_index].stealth_address) == W_key_image_x, "aggregated secret X and key image mismatch");
|
|
#endif
|
|
|
|
// initial commitment
|
|
scalar_t alpha_g = scalar_t::random(); // randomness for layers 0,1,4
|
|
scalar_t alpha_x = scalar_t::random(); // randomness for layer 2,3
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_CHALLENGE);
|
|
hsc.add_hash(input_hash);
|
|
hsc.add_point(alpha_g * c_point_G);
|
|
hsc.add_point(alpha_g * ki_base);
|
|
hsc.add_point(alpha_x * c_point_X);
|
|
hsc.add_point(alpha_x * ki_base);
|
|
//DBG_PRINT("c[" << secret_index << "] = Hs(ih, " << alpha_g * c_point_G << ", " << alpha_g * ki_base << ", " << alpha_x * c_point_X << ", " << alpha_x * ki_base << ")");
|
|
scalar_t c_prev = hsc.calc_hash(); // c_{secret_index + 1}
|
|
|
|
sig.r_g.clear();
|
|
sig.r_x.clear();
|
|
sig.r_g.reserve(ring_size);
|
|
sig.r_x.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
sig.r_g.emplace_back(scalar_t::random());
|
|
sig.r_x.emplace_back(scalar_t::random());
|
|
}
|
|
|
|
for(size_t j = 0, i = (secret_index + 1) % ring_size; j < ring_size - 1; ++j, i = (i + 1) % ring_size)
|
|
{
|
|
DBG_PRINT("c[" << i << "] = " << c_prev);
|
|
if (i == 0)
|
|
sig.c = c_prev; // c_0
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_CHALLENGE);
|
|
hsc.add_hash(input_hash);
|
|
hsc.add_point(sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i]);
|
|
hsc.add_point(sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g);
|
|
hsc.add_point(sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i]);
|
|
hsc.add_point(sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x);
|
|
c_prev = hsc.calc_hash(); // c_{i + 1}
|
|
//DBG_PRINT("c[" << i + 1 << "] = Hs(ih, " << sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i] << ", " << sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g << ", " << sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i] << ", " << sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x << ")");
|
|
}
|
|
DBG_PRINT("c[" << secret_index << "] = " << c_prev);
|
|
|
|
|
|
if (secret_index == 0)
|
|
sig.c = c_prev;
|
|
|
|
sig.r_g[secret_index] = alpha_g - c_prev * w_sec_key_g;
|
|
sig.r_x[secret_index] = alpha_x - c_prev * w_sec_key_x;
|
|
|
|
return true;
|
|
}
|
|
|
|
bool verify_CLSAG_GGXXG(const hash& m, const std::vector<CLSAG_GGXXG_input_ref_t>& ring, const public_key& pseudo_out_amount_commitment, const public_key& pseudo_out_blinded_asset_id, const public_key& extended_amount_commitment, const key_image& ki,
|
|
const CLSAG_GGXXG_signature& sig)
|
|
{
|
|
DBG_PRINT("== verify_CLSAG_GGXXG ==");
|
|
size_t ring_size = ring.size();
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size > 0, "ring size is zero");
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size == sig.r_g.size(), "ring size != r_g size");
|
|
CRYPTO_CHECK_AND_THROW_MES(ring_size == sig.r_x.size(), "ring size != r_x size");
|
|
|
|
point_t key_image(ki);
|
|
CRYPTO_CHECK_AND_THROW_MES(key_image.is_in_main_subgroup(), "key image 0 does not belong to the main subgroup");
|
|
|
|
point_t pseudo_out_amount_commitment_pt(pseudo_out_amount_commitment);
|
|
pseudo_out_amount_commitment_pt.modify_mul8();
|
|
|
|
point_t pseudo_out_blinded_asset_id_pt(pseudo_out_blinded_asset_id);
|
|
pseudo_out_blinded_asset_id_pt.modify_mul8();
|
|
|
|
point_t extended_amount_commitment_pt(extended_amount_commitment);
|
|
extended_amount_commitment_pt.modify_mul8();
|
|
|
|
// calculate aggregation coefficients
|
|
hash_helper_t::hs_t hsc(5 + 4 * ring_size);
|
|
hsc.add_scalar(m);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_pub_key(ring[i].stealth_address);
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hsc.add_pub_key(ring[i].amount_commitment);
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hsc.add_pub_key(ring[i].blinded_asset_id);
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hsc.add_pub_key(ring[i].concealing_point);
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DBG_PRINT("ring[" << i << "]: sa:" << ring[i].stealth_address << ", ac:" << ring[i].amount_commitment << ", baid:" << ring[i].blinded_asset_id << ", cp:" << ring[i].concealing_point);
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}
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hsc.add_pub_key(pseudo_out_amount_commitment);
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hsc.add_pub_key(pseudo_out_blinded_asset_id);
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hsc.add_pub_key(extended_amount_commitment);
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hsc.add_key_image(ki);
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hash input_hash = hsc.calc_hash_no_reduce();
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DBG_VAL_PRINT(input_hash);
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_0);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_0 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_0);
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_1);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_1 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_1);
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|
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// may we get rid of it?
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_2);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_2 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_2);
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|
|
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_3);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_3 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_3);
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|
|
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hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_LAYER_4);
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hsc.add_hash(input_hash);
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scalar_t agg_coeff_4 = hsc.calc_hash();
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DBG_VAL_PRINT(agg_coeff_4);
|
|
|
|
// prepare A_i, Q_i
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std::vector<point_t> A_i, P_i, Q_i;
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A_i.reserve(ring_size), P_i.reserve(ring_size), Q_i.reserve(ring_size);
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for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
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A_i.emplace_back(ring[i].amount_commitment);
|
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A_i.back().modify_mul8();
|
|
P_i.emplace_back(ring[i].blinded_asset_id);
|
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P_i.back().modify_mul8();
|
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Q_i.emplace_back(ring[i].concealing_point);
|
|
Q_i.back().modify_mul8();
|
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DBG_PRINT("A_i[" << i << "] = " << A_i[i] << " P_i[" << i << "] = " << P_i[i] << " Q_i[" << i << "] = " << Q_i[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layers 0, 1, 4; G components)
|
|
std::vector<point_t> W_pub_keys_g;
|
|
W_pub_keys_g.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_g.emplace_back(
|
|
agg_coeff_0 * point_t(ring[i].stealth_address) +
|
|
agg_coeff_1 * (A_i[i] - pseudo_out_amount_commitment_pt) +
|
|
agg_coeff_4 * Q_i[i]
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_g[i]);
|
|
}
|
|
|
|
// calculate aggregate pub keys (layer 2, 3; X component)
|
|
std::vector<point_t> W_pub_keys_x;
|
|
W_pub_keys_x.reserve(ring_size);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
W_pub_keys_x.emplace_back(
|
|
agg_coeff_2 * (P_i[i] - pseudo_out_blinded_asset_id_pt) +
|
|
agg_coeff_3 * (extended_amount_commitment_pt - A_i[i] - Q_i[i])
|
|
);
|
|
DBG_VAL_PRINT(W_pub_keys_x[i]);
|
|
}
|
|
|
|
DBG_VAL_PRINT(point_t(ki));
|
|
|
|
// calculate aggregate key image (layers 0, 1, 4; G components)
|
|
DBG_VAL_PRINT(point_t(sig.K1).modify_mul8());
|
|
point_t W_key_image_g =
|
|
agg_coeff_0 * key_image +
|
|
agg_coeff_1 * point_t(sig.K1).modify_mul8() +
|
|
agg_coeff_4 * point_t(sig.K4).modify_mul8();
|
|
DBG_VAL_PRINT(point_t(sig.K1).modify_mul8());
|
|
DBG_VAL_PRINT(point_t(sig.K4).modify_mul8());
|
|
DBG_VAL_PRINT(W_key_image_g);
|
|
|
|
// calculate aggregate key image (layer 2, 3; X component)
|
|
point_t W_key_image_x =
|
|
agg_coeff_2 * point_t(sig.K2).modify_mul8() +
|
|
agg_coeff_3 * point_t(sig.K3).modify_mul8();
|
|
DBG_VAL_PRINT(point_t(sig.K2).modify_mul8());
|
|
DBG_VAL_PRINT(point_t(sig.K3).modify_mul8());
|
|
DBG_VAL_PRINT(W_key_image_x);
|
|
|
|
|
|
scalar_t c_prev = sig.c;
|
|
DBG_PRINT("c[0] = " << c_prev);
|
|
for(size_t i = 0; i < ring_size; ++i)
|
|
{
|
|
hsc.add_32_chars(CRYPTO_HDS_CLSAG_GGXXG_CHALLENGE);
|
|
hsc.add_hash(input_hash);
|
|
hsc.add_point(sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i]);
|
|
hsc.add_point(sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g);
|
|
hsc.add_point(sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i]);
|
|
hsc.add_point(sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x);
|
|
c_prev = hsc.calc_hash(); // c_{i + 1}
|
|
DBG_PRINT("c[" << i + 1 << "] = " << c_prev);
|
|
//DBG_PRINT("c[" << i + 1 << "] = Hs(ih, " << sig.r_g[i] * c_point_G + c_prev * W_pub_keys_g[i] << ", " << sig.r_g[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_g << ", " << sig.r_x[i] * c_point_X + c_prev * W_pub_keys_x[i] << ", " << sig.r_x[i] * hash_helper_t::hp(ring[i].stealth_address) + c_prev * W_key_image_x << ")");
|
|
}
|
|
|
|
return c_prev == sig.c;
|
|
}
|
|
|
|
|
|
|
|
} // namespace crypto
|