Add get_tx_proof support, needed for new sanity check

Enhance debug info
This commit is contained in:
cslashm 2019-03-21 17:22:43 +01:00
parent 98fdcb2aa5
commit 7c44091541
8 changed files with 186 additions and 62 deletions

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@ -27,21 +27,6 @@
// THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
/* Note about debug:
* To debug Device you can def the following :
* #define DEBUG_HWDEVICE
* Activate debug mechanism:
* - Add more trace
* - All computation done by device are checked by default device.
* Required IODUMMYCRYPT_HWDEVICE or IONOCRYPT_HWDEVICE for fully working
* #define IODUMMYCRYPT_HWDEVICE 1
* - It assumes sensitive data encryption is is off on device side. a XOR with 0x55. This allow Ledger Class to make check on clear value
* #define IONOCRYPT_HWDEVICE 1
* - It assumes sensitive data encryption is off on device side.
*/
#pragma once
#include "crypto/crypto.h"
@ -211,6 +196,10 @@ namespace hw {
/* TRANSACTION */
/* ======================================================================= */
virtual void generate_tx_proof(const crypto::hash &prefix_hash,
const crypto::public_key &R, const crypto::public_key &A, const boost::optional<crypto::public_key> &B, const crypto::public_key &D, const crypto::secret_key &r,
crypto::signature &sig) = 0;
virtual bool open_tx(crypto::secret_key &tx_key) = 0;
virtual bool encrypt_payment_id(crypto::hash8 &payment_id, const crypto::public_key &public_key, const crypto::secret_key &secret_key) = 0;

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@ -37,7 +37,6 @@
#include "cryptonote_core/cryptonote_tx_utils.h"
#include "ringct/rctOps.h"
#include "log.hpp"
#define ENCRYPTED_PAYMENT_ID_TAIL 0x8d
#define CHACHA8_KEY_TAIL 0x8c
@ -273,6 +272,11 @@ namespace hw {
/* ======================================================================= */
/* TRANSACTION */
/* ======================================================================= */
void device_default::generate_tx_proof(const crypto::hash &prefix_hash,
const crypto::public_key &R, const crypto::public_key &A, const boost::optional<crypto::public_key> &B, const crypto::public_key &D, const crypto::secret_key &r,
crypto::signature &sig) {
crypto::generate_tx_proof(prefix_hash, R, A, B, D, r, sig);
}
bool device_default::open_tx(crypto::secret_key &tx_key) {
cryptonote::keypair txkey = cryptonote::keypair::generate(*this);

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@ -107,6 +107,10 @@ namespace hw {
/* TRANSACTION */
/* ======================================================================= */
void generate_tx_proof(const crypto::hash &prefix_hash,
const crypto::public_key &R, const crypto::public_key &A, const boost::optional<crypto::public_key> &B, const crypto::public_key &D, const crypto::secret_key &r,
crypto::signature &sig) override;
bool open_tx(crypto::secret_key &tx_key) override;
bool encrypt_payment_id(crypto::hash8 &payment_id, const crypto::public_key &public_key, const crypto::secret_key &secret_key) override;

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@ -29,7 +29,6 @@
#include "version.h"
#include "device_ledger.hpp"
#include "log.hpp"
#include "ringct/rctOps.h"
#include "cryptonote_basic/account.h"
#include "cryptonote_basic/subaddress_index.h"
@ -182,6 +181,7 @@ namespace hw {
#define INS_MLSAG 0x7E
#define INS_CLOSE_TX 0x80
#define INS_GET_TX_PROOF 0xA0
#define INS_GET_RESPONSE 0xc0
@ -808,7 +808,11 @@ namespace hw {
const crypto::secret_key a_x = hw::ledger::decrypt(a);
const crypto::secret_key b_x = hw::ledger::decrypt(b);
crypto::secret_key r_x;
rct::key aG_x;
log_hexbuffer("sc_secret_add: [[IN]] a ", (char*)a_x.data, 32);
log_hexbuffer("sc_secret_add: [[IN]] b ", (char*)b_x.data, 32);
this->controle_device->sc_secret_add(r_x, a_x, b_x);
log_hexbuffer("sc_secret_add: [[OUT]] aG", (char*)r_x.data, 32);
#endif
int offset = set_command_header_noopt(INS_SECRET_KEY_ADD);
@ -843,6 +847,11 @@ namespace hw {
#ifdef DEBUG_HWDEVICE
crypto::public_key pub_x;
crypto::secret_key sec_x;
crypto::secret_key recovery_key_x;
if (recover) {
recovery_key_x = hw::ledger::decrypt(recovery_key);
log_hexbuffer("generate_keys: [[IN]] pub", (char*)recovery_key_x.data, 32);
}
#endif
send_simple(INS_GENERATE_KEYPAIR);
@ -854,6 +863,9 @@ namespace hw {
#ifdef DEBUG_HWDEVICE
crypto::secret_key sec_clear = hw::ledger::decrypt(sec);
sec_x = sec_clear;
log_hexbuffer("generate_keys: [[OUT]] pub", (char*)pub.data, 32);
log_hexbuffer("generate_keys: [[OUT]] sec", (char*)sec_clear.data, 32);
crypto::secret_key_to_public_key(sec_x,pub_x);
hw::ledger::check32("generate_keys", "pub", pub_x.data, pub.data);
#endif
@ -868,7 +880,7 @@ namespace hw {
#ifdef DEBUG_HWDEVICE
const crypto::public_key pub_x = pub;
const crypto::secret_key sec_x = hw::ledger::decrypt(sec);
const crypto::secret_key sec_x = (sec == rct::rct2sk(rct::I)) ? sec: hw::ledger::decrypt(sec);
crypto::key_derivation derivation_x;
log_hexbuffer("generate_key_derivation: [[IN]] pub ", pub_x.data, 32);
log_hexbuffer("generate_key_derivation: [[IN]] sec ", sec_x.data, 32);
@ -884,7 +896,6 @@ namespace hw {
assert(is_fake_view_key(sec));
r = crypto::generate_key_derivation(pub, this->viewkey, derivation);
} else {
int offset = set_command_header_noopt(INS_GEN_KEY_DERIVATION);
//pub
memmove(this->buffer_send+offset, pub.data, 32);
@ -903,11 +914,11 @@ namespace hw {
}
#ifdef DEBUG_HWDEVICE
crypto::key_derivation derivation_clear ;
if ((this->mode == TRANSACTION_PARSE) && has_view_key) {
derivation_clear = derivation;
}else {
derivation_clear = hw::ledger::decrypt(derivation);
}
if ((this->mode == TRANSACTION_PARSE) && has_view_key) {
derivation_clear = derivation;
} else {
derivation_clear = hw::ledger::decrypt(derivation);
}
hw::ledger::check32("generate_key_derivation", "derivation", derivation_x.data, derivation_clear.data);
#endif
@ -1068,7 +1079,7 @@ namespace hw {
bool rc = this->controle_device->secret_key_to_public_key(sec_x, pub_x);
log_hexbuffer("secret_key_to_public_key: [[OUT]] pub", pub_x.data, 32);
if (!rc){
log_message("secret_key_to_public_key", "secret_key rejected");
log_message("FAIL secret_key_to_public_key", "secret_key rejected");
}
#endif
@ -1130,6 +1141,75 @@ namespace hw {
/* TRANSACTION */
/* ======================================================================= */
void device_ledger::generate_tx_proof(const crypto::hash &prefix_hash,
const crypto::public_key &R, const crypto::public_key &A, const boost::optional<crypto::public_key> &B, const crypto::public_key &D, const crypto::secret_key &r,
crypto::signature &sig) {
AUTO_LOCK_CMD();
#ifdef DEBUG_HWDEVICE
const crypto::hash prefix_hash_x = prefix_hash;
const crypto::public_key R_x = R;
const crypto::public_key A_x = A;
const boost::optional<crypto::public_key> B_x = B;
const crypto::public_key D_x = D;
const crypto::secret_key r_x = hw::ledger::decrypt(r);
crypto::signature sig_x;
log_hexbuffer("generate_tx_proof: [[IN]] prefix_hash ", prefix_hash_x.data, 32);
log_hexbuffer("generate_tx_proof: [[IN]] R ", R_x.data, 32);
log_hexbuffer("generate_tx_proof: [[IN]] A ", A_x.data, 32);
if (B_x) {
log_hexbuffer("generate_tx_proof: [[IN]] B ", (*B_x).data, 32);
}
log_hexbuffer("generate_tx_proof: [[IN]] D ", D_x.data, 32);
log_hexbuffer("generate_tx_proof: [[IN]] r ", r_x.data, 32);
#endif
int offset = set_command_header(INS_GET_TX_PROOF);
//options
this->buffer_send[offset] = B?0x01:0x00;
offset += 1;
//prefix_hash
memmove(&this->buffer_send[offset], prefix_hash.data, 32);
offset += 32;
// R
memmove(&this->buffer_send[offset], R.data, 32);
offset += 32;
// A
memmove(&this->buffer_send[offset], A.data, 32);
offset += 32;
// B
if (B) {
memmove(&this->buffer_send[offset], (*B).data, 32);
} else {
memset(&this->buffer_send[offset], 0, 32);
}
offset += 32;
// D
memmove(&this->buffer_send[offset], D.data, 32);
offset += 32;
// r
memmove(&this->buffer_send[offset], r.data, 32);
offset += 32;
this->buffer_send[4] = offset-5;
this->length_send = offset;
this->exchange();
memmove(sig.c.data, &this->buffer_recv[0], 32);
memmove(sig.r.data, &this->buffer_recv[32], 32);
#ifdef DEBUG_HWDEVICE
log_hexbuffer("GENERATE_TX_PROOF: **c** ", sig.c.data, sizeof( sig.c.data));
log_hexbuffer("GENERATE_TX_PROOF: **r** ", sig.r.data, sizeof( sig.r.data));
this->controle_device->generate_tx_proof(prefix_hash_x, R_x, A_x, B_x, D_x, r_x, sig_x);
hw::ledger::check32("generate_tx_proof", "c", sig_x.c.data, sig.c.data);
hw::ledger::check32("generate_tx_proof", "r", sig_x.r.data, sig.r.data);
#endif
}
bool device_ledger::open_tx(crypto::secret_key &tx_key) {
AUTO_LOCK_CMD();
@ -1148,7 +1228,11 @@ namespace hw {
this->exchange();
memmove(tx_key.data, &this->buffer_recv[32], 32);
#ifdef DEBUG_HWDEVICE
const crypto::secret_key r_x = hw::ledger::decrypt(tx_key);
log_hexbuffer("open_tx: [[OUT]] R ", (char*)&this->buffer_recv[0], 32);
log_hexbuffer("open_tx: [[OUT]] r ", r_x.data, 32);
#endif
return true;
}
@ -1159,7 +1243,11 @@ namespace hw {
const crypto::public_key public_key_x = public_key;
const crypto::secret_key secret_key_x = hw::ledger::decrypt(secret_key);
crypto::hash8 payment_id_x = payment_id;
log_hexbuffer("encrypt_payment_id: [[IN]] payment_id ", payment_id_x.data, 32);
log_hexbuffer("encrypt_payment_id: [[IN]] public_key ", public_key_x.data, 32);
log_hexbuffer("encrypt_payment_id: [[IN]] secret_key ", secret_key_x.data, 32);
this->controle_device->encrypt_payment_id(payment_id_x, public_key_x, secret_key_x);
log_hexbuffer("encrypt_payment_id: [[OUT]] payment_id ", payment_id_x.data, 32);
#endif
int offset = set_command_header_noopt(INS_STEALTH);
@ -1196,10 +1284,9 @@ namespace hw {
#ifdef DEBUG_HWDEVICE
const size_t &tx_version_x = tx_version;
const cryptonote::account_keys sender_account_keys_x = sender_account_keys;
const cryptonote::account_keys sender_account_keys_x = hw::ledger::decrypt(sender_account_keys);
memmove((void*)sender_account_keys_x.m_view_secret_key.data, dbg_viewkey.data, 32);
const crypto::public_key txkey_pub_x = txkey_pub;
const crypto::secret_key tx_key_x = hw::ledger::decrypt(tx_key);
const cryptonote::tx_destination_entry dst_entr_x = dst_entr;
@ -1215,12 +1302,32 @@ namespace hw {
std::vector<crypto::public_key> additional_tx_public_keys_x;
std::vector<rct::key> amount_keys_x;
crypto::public_key out_eph_public_key_x;
log_message ("generate_output_ephemeral_keys: [[IN]] tx_version", std::to_string(tx_version_x));
//log_hexbuffer("generate_output_ephemeral_keys: [[IN]] sender_account_keys.view", sender_account_keys.m_sview_secret_key.data, 32);
//log_hexbuffer("generate_output_ephemeral_keys: [[IN]] sender_account_keys.spend", sender_account_keys.m_spend_secret_key.data, 32);
log_hexbuffer("generate_output_ephemeral_keys: [[IN]] txkey_pub", txkey_pub_x.data, 32);
log_hexbuffer("generate_output_ephemeral_keys: [[IN]] tx_key", tx_key_x.data, 32);
log_hexbuffer("generate_output_ephemeral_keys: [[IN]] dst_entr.view", dst_entr_x.addr.m_view_public_key.data, 32);
log_hexbuffer("generate_output_ephemeral_keys: [[IN]] dst_entr.spend", dst_entr_x.addr.m_spend_public_key.data, 32);
if (change_addr) {
log_hexbuffer("generate_output_ephemeral_keys: [[IN]] change_addr.view", (*change_addr_x).m_view_public_key.data, 32);
log_hexbuffer("generate_output_ephemeral_keys: [[IN]] change_addr.spend", (*change_addr_x).m_spend_public_key.data, 32);
}
log_message ("generate_output_ephemeral_keys: [[IN]] output_index", std::to_string(output_index_x));
log_message ("generate_output_ephemeral_keys: [[IN]] need_additional_txkeys", std::to_string(need_additional_txkeys_x));
if(need_additional_txkeys_x) {
log_hexbuffer("generate_output_ephemeral_keys: [[IN]] additional_tx_keys[oi]", additional_tx_keys_x[output_index].data, 32);
}
this->controle_device->generate_output_ephemeral_keys(tx_version_x, sender_account_keys_x, txkey_pub_x, tx_key_x, dst_entr_x, change_addr_x, output_index_x, need_additional_txkeys_x, additional_tx_keys_x,
additional_tx_public_keys_x, amount_keys_x, out_eph_public_key_x);
if(need_additional_txkeys_x) {
log_hexbuffer("additional_tx_public_keys_x: [[OUT]] additional_tx_public_keys_x", additional_tx_public_keys_x.back().data, 32);
}
log_hexbuffer("generate_output_ephemeral_keys: [[OUT]] amount_keys ", (char*)amount_keys_x.back().bytes, 32);
log_hexbuffer("generate_output_ephemeral_keys: [[OUT]] out_eph_public_key ", out_eph_public_key_x.data, 32);
#endif
ASSERT_X(tx_version > 1, "TX version not supported"<<tx_version);
// make additional tx pubkey if necessary
@ -1236,7 +1343,6 @@ namespace hw {
this->buffer_send[offset+2] = tx_version>>8;
this->buffer_send[offset+3] = tx_version>>0;
offset += 4;
//tx_key
memmove(&this->buffer_send[offset], tx_key.data, 32);
offset += 32;
@ -1256,7 +1362,7 @@ namespace hw {
this->buffer_send[offset+3] = output_index>>0;
offset += 4;
//is_change,
bool is_change = (change_addr && dst_entr.addr == *change_addr);
bool is_change = (change_addr && dst_entr.addr == *change_addr);
this->buffer_send[offset] = is_change;
offset++;
//is_subaddress
@ -1265,13 +1371,14 @@ namespace hw {
//need_additional_key
this->buffer_send[offset] = need_additional_txkeys;
offset++;
//additional_tx_key
//additional_tx_key
if (need_additional_txkeys) {
memmove(&this->buffer_send[offset], additional_txkey.sec.data, 32);
} else {
memset(&this->buffer_send[offset], 0, 32);
}
offset += 32;
this->buffer_send[4] = offset-5;
this->length_send = offset;
this->exchange();
@ -1280,7 +1387,7 @@ namespace hw {
unsigned int recv_len = this->length_recv;
//if (tx_version > 1)
{
{
ASSERT_X(recv_len>=32, "Not enought data from device");
crypto::secret_key scalar1;
memmove(scalar1.data, &this->buffer_recv[offset],32);
@ -1312,7 +1419,7 @@ namespace hw {
hw::ledger::check32("generate_output_ephemeral_keys", "amount_key", (const char*)amount_keys_x.back().bytes, (const char*)hw::ledger::decrypt(amount_keys.back()).bytes);
if (need_additional_txkeys) {
hw::ledger::check32("generate_output_ephemeral_keys", "additional_tx_key", additional_tx_public_keys_x.back().data, additional_tx_public_keys.back().data);
}
}
hw::ledger::check32("generate_output_ephemeral_keys", "out_eph_public_key", out_eph_public_key_x.data, out_eph_public_key.data);
#endif

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@ -33,6 +33,7 @@
#include <cstddef>
#include <string>
#include "device.hpp"
#include "log.hpp"
#include "device_io_hid.hpp"
#include <boost/thread/mutex.hpp>
#include <boost/thread/recursive_mutex.hpp>
@ -202,6 +203,9 @@ namespace hw {
/* ======================================================================= */
/* TRANSACTION */
/* ======================================================================= */
void generate_tx_proof(const crypto::hash &prefix_hash,
const crypto::public_key &R, const crypto::public_key &A, const boost::optional<crypto::public_key> &B, const crypto::public_key &D, const crypto::secret_key &r,
crypto::signature &sig) override;
bool open_tx(crypto::secret_key &tx_key) override;

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@ -40,6 +40,19 @@
namespace hw {
/* Note about debug:
* To debug Device you can def the following :
* #define DEBUG_HWDEVICE
* Activate debug mechanism:
* - Add more trace
* - All computation done by device are checked by default device.
* Required IODUMMYCRYPT_HWDEVICE or IONOCRYPT_HWDEVICE for fully working
* #define IODUMMYCRYPT_HWDEVICE 1
* - It assumes sensitive data encryption is is off on device side. a XOR with 0x55. This allow Ledger Class to make check on clear value
* #define IONOCRYPT_HWDEVICE 1
* - It assumes sensitive data encryption is off on device side.
*/
void buffer_to_str(char *to_buff, size_t to_len, const char *buff, size_t len) ;
void log_hexbuffer(const std::string &msg, const char* buff, size_t len);
void log_message(const std::string &msg, const std::string &info );

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@ -6871,11 +6871,6 @@ bool simple_wallet::set_tx_key(const std::vector<std::string> &args_)
//----------------------------------------------------------------------------------------------------
bool simple_wallet::get_tx_proof(const std::vector<std::string> &args)
{
if (m_wallet->key_on_device() && m_wallet->get_account().get_device().get_type() != hw::device::TREZOR)
{
fail_msg_writer() << tr("command not supported by HW wallet");
return true;
}
if (args.size() != 2 && args.size() != 3)
{
PRINT_USAGE(USAGE_GET_TX_PROOF);

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@ -10411,7 +10411,7 @@ void wallet2::check_tx_key(const crypto::hash &txid, const crypto::secret_key &t
void wallet2::check_tx_key_helper(const cryptonote::transaction &tx, const crypto::key_derivation &derivation, const std::vector<crypto::key_derivation> &additional_derivations, const cryptonote::account_public_address &address, uint64_t &received) const
{
received = 0;
hw::device &hwdev = m_account.get_device();
for (size_t n = 0; n < tx.vout.size(); ++n)
{
const cryptonote::txout_to_key* const out_key = boost::get<cryptonote::txout_to_key>(std::addressof(tx.vout[n].target));
@ -10419,13 +10419,13 @@ void wallet2::check_tx_key_helper(const cryptonote::transaction &tx, const crypt
continue;
crypto::public_key derived_out_key;
bool r = hwdev.derive_public_key(derivation, n, address.m_spend_public_key, derived_out_key);
bool r = crypto::derive_public_key(derivation, n, address.m_spend_public_key, derived_out_key);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to derive public key");
bool found = out_key->key == derived_out_key;
crypto::key_derivation found_derivation = derivation;
if (!found && !additional_derivations.empty())
{
r = hwdev.derive_public_key(additional_derivations[n], n, address.m_spend_public_key, derived_out_key);
r = crypto::derive_public_key(additional_derivations[n], n, address.m_spend_public_key, derived_out_key);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to derive public key");
found = out_key->key == derived_out_key;
found_derivation = additional_derivations[n];
@ -10441,9 +10441,9 @@ void wallet2::check_tx_key_helper(const cryptonote::transaction &tx, const crypt
else
{
crypto::secret_key scalar1;
hwdev.derivation_to_scalar(found_derivation, n, scalar1);
crypto::derivation_to_scalar(found_derivation, n, scalar1);
rct::ecdhTuple ecdh_info = tx.rct_signatures.ecdhInfo[n];
hwdev.ecdhDecode(ecdh_info, rct::sk2rct(scalar1), tx.rct_signatures.type == rct::RCTTypeBulletproof2);
rct::ecdhDecode(ecdh_info, rct::sk2rct(scalar1), tx.rct_signatures.type == rct::RCTTypeBulletproof2);
const rct::key C = tx.rct_signatures.outPk[n].mask;
rct::key Ctmp;
THROW_WALLET_EXCEPTION_IF(sc_check(ecdh_info.mask.bytes) != 0, error::wallet_internal_error, "Bad ECDH input mask");
@ -10554,6 +10554,8 @@ std::string wallet2::get_tx_proof(const crypto::hash &txid, const cryptonote::ac
std::string wallet2::get_tx_proof(const cryptonote::transaction &tx, const crypto::secret_key &tx_key, const std::vector<crypto::secret_key> &additional_tx_keys, const cryptonote::account_public_address &address, bool is_subaddress, const std::string &message) const
{
hw::device &hwdev = m_account.get_device();
rct::key aP;
// determine if the address is found in the subaddress hash table (i.e. whether the proof is outbound or inbound)
const bool is_out = m_subaddresses.count(address.m_spend_public_key) == 0;
@ -10572,30 +10574,34 @@ std::string wallet2::get_tx_proof(const cryptonote::transaction &tx, const crypt
shared_secret.resize(num_sigs);
sig.resize(num_sigs);
shared_secret[0] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_view_public_key), rct::sk2rct(tx_key)));
hwdev.scalarmultKey(aP, rct::pk2rct(address.m_view_public_key), rct::sk2rct(tx_key));
shared_secret[0] = rct::rct2pk(aP);
crypto::public_key tx_pub_key;
if (is_subaddress)
{
tx_pub_key = rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_spend_public_key), rct::sk2rct(tx_key)));
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, address.m_spend_public_key, shared_secret[0], tx_key, sig[0]);
hwdev.scalarmultKey(aP, rct::pk2rct(address.m_spend_public_key), rct::sk2rct(tx_key));
tx_pub_key = rct2pk(aP);
hwdev.generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, address.m_spend_public_key, shared_secret[0], tx_key, sig[0]);
}
else
{
crypto::secret_key_to_public_key(tx_key, tx_pub_key);
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, boost::none, shared_secret[0], tx_key, sig[0]);
hwdev.secret_key_to_public_key(tx_key, tx_pub_key);
hwdev.generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, boost::none, shared_secret[0], tx_key, sig[0]);
}
for (size_t i = 1; i < num_sigs; ++i)
{
shared_secret[i] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_view_public_key), rct::sk2rct(additional_tx_keys[i - 1])));
hwdev.scalarmultKey(aP, rct::pk2rct(address.m_view_public_key), rct::sk2rct(additional_tx_keys[i - 1]));
shared_secret[i] = rct::rct2pk(aP);
if (is_subaddress)
{
tx_pub_key = rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_spend_public_key), rct::sk2rct(additional_tx_keys[i - 1])));
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, address.m_spend_public_key, shared_secret[i], additional_tx_keys[i - 1], sig[i]);
hwdev.scalarmultKey(aP, rct::pk2rct(address.m_spend_public_key), rct::sk2rct(additional_tx_keys[i - 1]));
tx_pub_key = rct2pk(aP);
hwdev.generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, address.m_spend_public_key, shared_secret[i], additional_tx_keys[i - 1], sig[i]);
}
else
{
crypto::secret_key_to_public_key(additional_tx_keys[i - 1], tx_pub_key);
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, boost::none, shared_secret[i], additional_tx_keys[i - 1], sig[i]);
hwdev.secret_key_to_public_key(additional_tx_keys[i - 1], tx_pub_key);
hwdev.generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, boost::none, shared_secret[i], additional_tx_keys[i - 1], sig[i]);
}
}
sig_str = std::string("OutProofV1");
@ -10611,25 +10617,27 @@ std::string wallet2::get_tx_proof(const cryptonote::transaction &tx, const crypt
sig.resize(num_sigs);
const crypto::secret_key& a = m_account.get_keys().m_view_secret_key;
shared_secret[0] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(tx_pub_key), rct::sk2rct(a)));
hwdev.scalarmultKey(aP, rct::pk2rct(tx_pub_key), rct::sk2rct(a));
shared_secret[0] = rct2pk(aP);
if (is_subaddress)
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, address.m_spend_public_key, shared_secret[0], a, sig[0]);
hwdev.generate_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, address.m_spend_public_key, shared_secret[0], a, sig[0]);
}
else
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, boost::none, shared_secret[0], a, sig[0]);
hwdev.generate_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, boost::none, shared_secret[0], a, sig[0]);
}
for (size_t i = 1; i < num_sigs; ++i)
{
shared_secret[i] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(additional_tx_pub_keys[i - 1]), rct::sk2rct(a)));
hwdev.scalarmultKey(aP,rct::pk2rct(additional_tx_pub_keys[i - 1]), rct::sk2rct(a));
shared_secret[i] = rct2pk(aP);
if (is_subaddress)
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i - 1], address.m_spend_public_key, shared_secret[i], a, sig[i]);
hwdev.generate_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i - 1], address.m_spend_public_key, shared_secret[i], a, sig[i]);
}
else
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i - 1], boost::none, shared_secret[i], a, sig[i]);
hwdev.generate_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i - 1], boost::none, shared_secret[i], a, sig[i]);
}
}
sig_str = std::string("InProofV1");