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Merge branch 'master' into lite-node

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This commit is contained in:
CalDescent 2022-05-02 08:31:43 +01:00
commit 3409086978
20 changed files with 6059 additions and 5 deletions
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4
pom.xml
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@ -7,7 +7,7 @@
<packaging>jar</packaging> <packaging>jar</packaging>
<properties> <properties>
<skipTests>true</skipTests> <skipTests>true</skipTests>
<altcoinj.version>bf9fb80</altcoinj.version> <altcoinj.version>6628cfd</altcoinj.version>
<bitcoinj.version>0.15.10</bitcoinj.version> <bitcoinj.version>0.15.10</bitcoinj.version>
<bouncycastle.version>1.64</bouncycastle.version> <bouncycastle.version>1.64</bouncycastle.version>
<build.timestamp>${maven.build.timestamp}</build.timestamp> <build.timestamp>${maven.build.timestamp}</build.timestamp>
@ -444,7 +444,7 @@
</dependency> </dependency>
<!-- For Litecoin, etc. support, requires bitcoinj --> <!-- For Litecoin, etc. support, requires bitcoinj -->
<dependency> <dependency>
<groupId>com.github.jjos2372</groupId> <groupId>com.github.qortal</groupId>
<artifactId>altcoinj</artifactId> <artifactId>altcoinj</artifactId>
<version>${altcoinj.version}</version> <version>${altcoinj.version}</version>
</dependency> </dependency>

29
src/main/java/org/qortal/api/model/crosschain/DigibyteSendRequest.java Normal file
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@ -0,0 +1,29 @@
package org.qortal.api.model.crosschain;
import javax.xml.bind.annotation.XmlAccessType;
import javax.xml.bind.annotation.XmlAccessorType;
import javax.xml.bind.annotation.adapters.XmlJavaTypeAdapter;
import io.swagger.v3.oas.annotations.media.Schema;
@XmlAccessorType(XmlAccessType.FIELD)
public class DigibyteSendRequest {
@Schema(description = "Digibyte BIP32 extended private key", example = "tprv___________________________________________________________________________________________________________")
public String xprv58;
@Schema(description = "Recipient's Digibyte address ('legacy' P2PKH only)", example = "1DigByteEaterAddressDontSendf59kuE")
public String receivingAddress;
@Schema(description = "Amount of DGB to send", type = "number")
@XmlJavaTypeAdapter(value = org.qortal.api.AmountTypeAdapter.class)
public long digibyteAmount;
@Schema(description = "Transaction fee per byte (optional). Default is 0.00000100 DGB (100 sats) per byte", example = "0.00000100", type = "number")
@XmlJavaTypeAdapter(value = org.qortal.api.AmountTypeAdapter.class)
public Long feePerByte;
public DigibyteSendRequest() {
}
}

29
src/main/java/org/qortal/api/model/crosschain/RavencoinSendRequest.java Normal file
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@ -0,0 +1,29 @@
package org.qortal.api.model.crosschain;
import javax.xml.bind.annotation.XmlAccessType;
import javax.xml.bind.annotation.XmlAccessorType;
import javax.xml.bind.annotation.adapters.XmlJavaTypeAdapter;
import io.swagger.v3.oas.annotations.media.Schema;
@XmlAccessorType(XmlAccessType.FIELD)
public class RavencoinSendRequest {
@Schema(description = "Ravencoin BIP32 extended private key", example = "tprv___________________________________________________________________________________________________________")
public String xprv58;
@Schema(description = "Recipient's Ravencoin address ('legacy' P2PKH only)", example = "1RvnCoinEaterAddressDontSendf59kuE")
public String receivingAddress;
@Schema(description = "Amount of RVN to send", type = "number")
@XmlJavaTypeAdapter(value = org.qortal.api.AmountTypeAdapter.class)
public long ravencoinAmount;
@Schema(description = "Transaction fee per byte (optional). Default is 0.00000100 RVN (100 sats) per byte", example = "0.00000100", type = "number")
@XmlJavaTypeAdapter(value = org.qortal.api.AmountTypeAdapter.class)
public Long feePerByte;
public RavencoinSendRequest() {
}
}

177
src/main/java/org/qortal/api/resource/CrossChainDigibyteResource.java Normal file
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@ -0,0 +1,177 @@
package org.qortal.api.resource;
import io.swagger.v3.oas.annotations.Operation;
import io.swagger.v3.oas.annotations.media.ArraySchema;
import io.swagger.v3.oas.annotations.media.Content;
import io.swagger.v3.oas.annotations.media.Schema;
import io.swagger.v3.oas.annotations.parameters.RequestBody;
import io.swagger.v3.oas.annotations.responses.ApiResponse;
import io.swagger.v3.oas.annotations.security.SecurityRequirement;
import io.swagger.v3.oas.annotations.tags.Tag;
import java.util.List;
import javax.servlet.http.HttpServletRequest;
import javax.ws.rs.HeaderParam;
import javax.ws.rs.POST;
import javax.ws.rs.Path;
import javax.ws.rs.core.Context;
import javax.ws.rs.core.MediaType;
import org.bitcoinj.core.Transaction;
import org.qortal.api.ApiError;
import org.qortal.api.ApiErrors;
import org.qortal.api.ApiExceptionFactory;
import org.qortal.api.Security;
import org.qortal.api.model.crosschain.DigibyteSendRequest;
import org.qortal.crosschain.Digibyte;
import org.qortal.crosschain.ForeignBlockchainException;
import org.qortal.crosschain.SimpleTransaction;
@Path("/crosschain/dgb")
@Tag(name = "Cross-Chain (Digibyte)")
public class CrossChainDigibyteResource {
@Context
HttpServletRequest request;
@POST
@Path("/walletbalance")
@Operation(
summary = "Returns DGB balance for hierarchical, deterministic BIP32 wallet",
description = "Supply BIP32 'm' private/public key in base58, starting with 'xprv'/'xpub' for mainnet, 'tprv'/'tpub' for testnet",
requestBody = @RequestBody(
required = true,
content = @Content(
mediaType = MediaType.TEXT_PLAIN,
schema = @Schema(
type = "string",
description = "BIP32 'm' private/public key in base58",
example = "tpubD6NzVbkrYhZ4XTPc4btCZ6SMgn8CxmWkj6VBVZ1tfcJfMq4UwAjZbG8U74gGSypL9XBYk2R2BLbDBe8pcEyBKM1edsGQEPKXNbEskZozeZc"
)
)
),
responses = {
@ApiResponse(
content = @Content(mediaType = MediaType.TEXT_PLAIN, schema = @Schema(type = "string", description = "balance (satoshis)"))
)
}
)
@ApiErrors({ApiError.INVALID_PRIVATE_KEY, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE})
@SecurityRequirement(name = "apiKey")
public String getDigibyteWalletBalance(@HeaderParam(Security.API_KEY_HEADER) String apiKey, String key58) {
Security.checkApiCallAllowed(request);
Digibyte digibyte = Digibyte.getInstance();
if (!digibyte.isValidDeterministicKey(key58))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_PRIVATE_KEY);
try {
Long balance = digibyte.getWalletBalanceFromTransactions(key58);
if (balance == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
return balance.toString();
} catch (ForeignBlockchainException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
}
}
@POST
@Path("/wallettransactions")
@Operation(
summary = "Returns transactions for hierarchical, deterministic BIP32 wallet",
description = "Supply BIP32 'm' private/public key in base58, starting with 'xprv'/'xpub' for mainnet, 'tprv'/'tpub' for testnet",
requestBody = @RequestBody(
required = true,
content = @Content(
mediaType = MediaType.TEXT_PLAIN,
schema = @Schema(
type = "string",
description = "BIP32 'm' private/public key in base58",
example = "tpubD6NzVbkrYhZ4XTPc4btCZ6SMgn8CxmWkj6VBVZ1tfcJfMq4UwAjZbG8U74gGSypL9XBYk2R2BLbDBe8pcEyBKM1edsGQEPKXNbEskZozeZc"
)
)
),
responses = {
@ApiResponse(
content = @Content(array = @ArraySchema( schema = @Schema( implementation = SimpleTransaction.class ) ) )
)
}
)
@ApiErrors({ApiError.INVALID_PRIVATE_KEY, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE})
@SecurityRequirement(name = "apiKey")
public List<SimpleTransaction> getDigibyteWalletTransactions(@HeaderParam(Security.API_KEY_HEADER) String apiKey, String key58) {
Security.checkApiCallAllowed(request);
Digibyte digibyte = Digibyte.getInstance();
if (!digibyte.isValidDeterministicKey(key58))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_PRIVATE_KEY);
try {
return digibyte.getWalletTransactions(key58);
} catch (ForeignBlockchainException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
}
}
@POST
@Path("/send")
@Operation(
summary = "Sends DGB from hierarchical, deterministic BIP32 wallet to specific address",
description = "Currently supports 'legacy' P2PKH Digibyte addresses and Native SegWit (P2WPKH) addresses. Supply BIP32 'm' private key in base58, starting with 'xprv' for mainnet, 'tprv' for testnet",
requestBody = @RequestBody(
required = true,
content = @Content(
mediaType = MediaType.APPLICATION_JSON,
schema = @Schema(
implementation = DigibyteSendRequest.class
)
)
),
responses = {
@ApiResponse(
content = @Content(mediaType = MediaType.TEXT_PLAIN, schema = @Schema(type = "string", description = "transaction hash"))
)
}
)
@ApiErrors({ApiError.INVALID_PRIVATE_KEY, ApiError.INVALID_CRITERIA, ApiError.INVALID_ADDRESS, ApiError.FOREIGN_BLOCKCHAIN_BALANCE_ISSUE, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE})
@SecurityRequirement(name = "apiKey")
public String sendBitcoin(@HeaderParam(Security.API_KEY_HEADER) String apiKey, DigibyteSendRequest digibyteSendRequest) {
Security.checkApiCallAllowed(request);
if (digibyteSendRequest.digibyteAmount <= 0)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
if (digibyteSendRequest.feePerByte != null && digibyteSendRequest.feePerByte <= 0)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
Digibyte digibyte = Digibyte.getInstance();
if (!digibyte.isValidAddress(digibyteSendRequest.receivingAddress))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_ADDRESS);
if (!digibyte.isValidDeterministicKey(digibyteSendRequest.xprv58))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_PRIVATE_KEY);
Transaction spendTransaction = digibyte.buildSpend(digibyteSendRequest.xprv58,
digibyteSendRequest.receivingAddress,
digibyteSendRequest.digibyteAmount,
digibyteSendRequest.feePerByte);
if (spendTransaction == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_BALANCE_ISSUE);
try {
digibyte.broadcastTransaction(spendTransaction);
} catch (ForeignBlockchainException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
}
return spendTransaction.getTxId().toString();
}
}

177
src/main/java/org/qortal/api/resource/CrossChainRavencoinResource.java Normal file
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@ -0,0 +1,177 @@
package org.qortal.api.resource;
import io.swagger.v3.oas.annotations.Operation;
import io.swagger.v3.oas.annotations.media.ArraySchema;
import io.swagger.v3.oas.annotations.media.Content;
import io.swagger.v3.oas.annotations.media.Schema;
import io.swagger.v3.oas.annotations.parameters.RequestBody;
import io.swagger.v3.oas.annotations.responses.ApiResponse;
import io.swagger.v3.oas.annotations.security.SecurityRequirement;
import io.swagger.v3.oas.annotations.tags.Tag;
import java.util.List;
import javax.servlet.http.HttpServletRequest;
import javax.ws.rs.HeaderParam;
import javax.ws.rs.POST;
import javax.ws.rs.Path;
import javax.ws.rs.core.Context;
import javax.ws.rs.core.MediaType;
import org.bitcoinj.core.Transaction;
import org.qortal.api.ApiError;
import org.qortal.api.ApiErrors;
import org.qortal.api.ApiExceptionFactory;
import org.qortal.api.Security;
import org.qortal.api.model.crosschain.RavencoinSendRequest;
import org.qortal.crosschain.Ravencoin;
import org.qortal.crosschain.ForeignBlockchainException;
import org.qortal.crosschain.SimpleTransaction;
@Path("/crosschain/rvn")
@Tag(name = "Cross-Chain (Ravencoin)")
public class CrossChainRavencoinResource {
@Context
HttpServletRequest request;
@POST
@Path("/walletbalance")
@Operation(
summary = "Returns RVN balance for hierarchical, deterministic BIP32 wallet",
description = "Supply BIP32 'm' private/public key in base58, starting with 'xprv'/'xpub' for mainnet, 'tprv'/'tpub' for testnet",
requestBody = @RequestBody(
required = true,
content = @Content(
mediaType = MediaType.TEXT_PLAIN,
schema = @Schema(
type = "string",
description = "BIP32 'm' private/public key in base58",
example = "tpubD6NzVbkrYhZ4XTPc4btCZ6SMgn8CxmWkj6VBVZ1tfcJfMq4UwAjZbG8U74gGSypL9XBYk2R2BLbDBe8pcEyBKM1edsGQEPKXNbEskZozeZc"
)
)
),
responses = {
@ApiResponse(
content = @Content(mediaType = MediaType.TEXT_PLAIN, schema = @Schema(type = "string", description = "balance (satoshis)"))
)
}
)
@ApiErrors({ApiError.INVALID_PRIVATE_KEY, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE})
@SecurityRequirement(name = "apiKey")
public String getRavencoinWalletBalance(@HeaderParam(Security.API_KEY_HEADER) String apiKey, String key58) {
Security.checkApiCallAllowed(request);
Ravencoin ravencoin = Ravencoin.getInstance();
if (!ravencoin.isValidDeterministicKey(key58))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_PRIVATE_KEY);
try {
Long balance = ravencoin.getWalletBalanceFromTransactions(key58);
if (balance == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
return balance.toString();
} catch (ForeignBlockchainException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
}
}
@POST
@Path("/wallettransactions")
@Operation(
summary = "Returns transactions for hierarchical, deterministic BIP32 wallet",
description = "Supply BIP32 'm' private/public key in base58, starting with 'xprv'/'xpub' for mainnet, 'tprv'/'tpub' for testnet",
requestBody = @RequestBody(
required = true,
content = @Content(
mediaType = MediaType.TEXT_PLAIN,
schema = @Schema(
type = "string",
description = "BIP32 'm' private/public key in base58",
example = "tpubD6NzVbkrYhZ4XTPc4btCZ6SMgn8CxmWkj6VBVZ1tfcJfMq4UwAjZbG8U74gGSypL9XBYk2R2BLbDBe8pcEyBKM1edsGQEPKXNbEskZozeZc"
)
)
),
responses = {
@ApiResponse(
content = @Content(array = @ArraySchema( schema = @Schema( implementation = SimpleTransaction.class ) ) )
)
}
)
@ApiErrors({ApiError.INVALID_PRIVATE_KEY, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE})
@SecurityRequirement(name = "apiKey")
public List<SimpleTransaction> getRavencoinWalletTransactions(@HeaderParam(Security.API_KEY_HEADER) String apiKey, String key58) {
Security.checkApiCallAllowed(request);
Ravencoin ravencoin = Ravencoin.getInstance();
if (!ravencoin.isValidDeterministicKey(key58))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_PRIVATE_KEY);
try {
return ravencoin.getWalletTransactions(key58);
} catch (ForeignBlockchainException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
}
}
@POST
@Path("/send")
@Operation(
summary = "Sends RVN from hierarchical, deterministic BIP32 wallet to specific address",
description = "Currently only supports 'legacy' P2PKH Ravencoin addresses. Supply BIP32 'm' private key in base58, starting with 'xprv' for mainnet, 'tprv' for testnet",
requestBody = @RequestBody(
required = true,
content = @Content(
mediaType = MediaType.APPLICATION_JSON,
schema = @Schema(
implementation = RavencoinSendRequest.class
)
)
),
responses = {
@ApiResponse(
content = @Content(mediaType = MediaType.TEXT_PLAIN, schema = @Schema(type = "string", description = "transaction hash"))
)
}
)
@ApiErrors({ApiError.INVALID_PRIVATE_KEY, ApiError.INVALID_CRITERIA, ApiError.INVALID_ADDRESS, ApiError.FOREIGN_BLOCKCHAIN_BALANCE_ISSUE, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE})
@SecurityRequirement(name = "apiKey")
public String sendBitcoin(@HeaderParam(Security.API_KEY_HEADER) String apiKey, RavencoinSendRequest ravencoinSendRequest) {
Security.checkApiCallAllowed(request);
if (ravencoinSendRequest.ravencoinAmount <= 0)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
if (ravencoinSendRequest.feePerByte != null && ravencoinSendRequest.feePerByte <= 0)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
Ravencoin ravencoin = Ravencoin.getInstance();
if (!ravencoin.isValidAddress(ravencoinSendRequest.receivingAddress))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_ADDRESS);
if (!ravencoin.isValidDeterministicKey(ravencoinSendRequest.xprv58))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_PRIVATE_KEY);
Transaction spendTransaction = ravencoin.buildSpend(ravencoinSendRequest.xprv58,
ravencoinSendRequest.receivingAddress,
ravencoinSendRequest.ravencoinAmount,
ravencoinSendRequest.feePerByte);
if (spendTransaction == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_BALANCE_ISSUE);
try {
ravencoin.broadcastTransaction(spendTransaction);
} catch (ForeignBlockchainException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.FOREIGN_BLOCKCHAIN_NETWORK_ISSUE);
}
return spendTransaction.getTxId().toString();
}
}

2
src/main/java/org/qortal/arbitrary/ArbitraryDataRenderer.java
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@ -120,7 +120,7 @@ public class ArbitraryDataRenderer {
byte[] data = Files.readAllBytes(Paths.get(filePath)); // TODO: limit file size that can be read into memory byte[] data = Files.readAllBytes(Paths.get(filePath)); // TODO: limit file size that can be read into memory
HTMLParser htmlParser = new HTMLParser(resourceId, inPath, prefix, usePrefix, data); HTMLParser htmlParser = new HTMLParser(resourceId, inPath, prefix, usePrefix, data);
htmlParser.addAdditionalHeaderTags(); htmlParser.addAdditionalHeaderTags();
response.addHeader("Content-Security-Policy", "default-src 'self' 'unsafe-inline' 'unsafe-eval'; media-src 'self' blob:"); response.addHeader("Content-Security-Policy", "default-src 'self' 'unsafe-inline' 'unsafe-eval'; media-src 'self' blob:; img-src 'self' data: blob:;");
response.setContentType(context.getMimeType(filename)); response.setContentType(context.getMimeType(filename));
response.setContentLength(htmlParser.getData().length); response.setContentLength(htmlParser.getData().length);
response.getOutputStream().write(htmlParser.getData()); response.getOutputStream().write(htmlParser.getData());

885
src/main/java/org/qortal/controller/tradebot/DigibyteACCTv3TradeBot.java Normal file
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@ -0,0 +1,885 @@
package org.qortal.controller.tradebot;
import org.apache.logging.log4j.LogManager;
import org.apache.logging.log4j.Logger;
import org.bitcoinj.core.*;
import org.bitcoinj.script.Script.ScriptType;
import org.qortal.account.PrivateKeyAccount;
import org.qortal.account.PublicKeyAccount;
import org.qortal.api.model.crosschain.TradeBotCreateRequest;
import org.qortal.asset.Asset;
import org.qortal.crosschain.*;
import org.qortal.crypto.Crypto;
import org.qortal.data.at.ATData;
import org.qortal.data.crosschain.CrossChainTradeData;
import org.qortal.data.crosschain.TradeBotData;
import org.qortal.data.transaction.BaseTransactionData;
import org.qortal.data.transaction.DeployAtTransactionData;
import org.qortal.data.transaction.MessageTransactionData;
import org.qortal.group.Group;
import org.qortal.repository.DataException;
import org.qortal.repository.Repository;
import org.qortal.transaction.DeployAtTransaction;
import org.qortal.transaction.MessageTransaction;
import org.qortal.transaction.Transaction.ValidationResult;
import org.qortal.transform.TransformationException;
import org.qortal.transform.transaction.DeployAtTransactionTransformer;
import org.qortal.utils.Base58;
import org.qortal.utils.NTP;
import java.util.Arrays;
import java.util.List;
import java.util.Map;
import java.util.stream.Collectors;
import static java.util.Arrays.stream;
import static java.util.stream.Collectors.toMap;
/**
* Performing cross-chain trading steps on behalf of user.
* <p>
* We deal with three different independent state-spaces here:
* <ul>
* <li>Qortal blockchain</li>
* <li>Foreign blockchain</li>
* <li>Trade-bot entries</li>
* </ul>
*/
public class DigibyteACCTv3TradeBot implements AcctTradeBot {
private static final Logger LOGGER = LogManager.getLogger(DigibyteACCTv3TradeBot.class);
public enum State implements TradeBot.StateNameAndValueSupplier {
BOB_WAITING_FOR_AT_CONFIRM(10, false, false),
BOB_WAITING_FOR_MESSAGE(15, true, true),
BOB_WAITING_FOR_AT_REDEEM(25, true, true),
BOB_DONE(30, false, false),
BOB_REFUNDED(35, false, false),
ALICE_WAITING_FOR_AT_LOCK(85, true, true),
ALICE_DONE(95, false, false),
ALICE_REFUNDING_A(105, true, true),
ALICE_REFUNDED(110, false, false);
private static final Map<Integer, State> map = stream(State.values()).collect(toMap(state -> state.value, state -> state));
public final int value;
public final boolean requiresAtData;
public final boolean requiresTradeData;
State(int value, boolean requiresAtData, boolean requiresTradeData) {
this.value = value;
this.requiresAtData = requiresAtData;
this.requiresTradeData = requiresTradeData;
}
public static State valueOf(int value) {
return map.get(value);
}
@Override
public String getState() {
return this.name();
}
@Override
public int getStateValue() {
return this.value;
}
}
/** Maximum time Bob waits for his AT creation transaction to be confirmed into a block. (milliseconds) */
private static final long MAX_AT_CONFIRMATION_PERIOD = 24 * 60 * 60 * 1000L; // ms
private static DigibyteACCTv3TradeBot instance;
private final List<String> endStates = Arrays.asList(State.BOB_DONE, State.BOB_REFUNDED, State.ALICE_DONE, State.ALICE_REFUNDING_A, State.ALICE_REFUNDED).stream()
.map(State::name)
.collect(Collectors.toUnmodifiableList());
private DigibyteACCTv3TradeBot() {
}
public static synchronized DigibyteACCTv3TradeBot getInstance() {
if (instance == null)
instance = new DigibyteACCTv3TradeBot();
return instance;
}
@Override
public List<String> getEndStates() {
return this.endStates;
}
/**
* Creates a new trade-bot entry from the "Bob" viewpoint, i.e. OFFERing QORT in exchange for DGB.
* <p>
* Generates:
* <ul>
* <li>new 'trade' private key</li>
* </ul>
* Derives:
* <ul>
* <li>'native' (as in Qortal) public key, public key hash, address (starting with Q)</li>
* <li>'foreign' (as in Digibyte) public key, public key hash</li>
* </ul>
* A Qortal AT is then constructed including the following as constants in the 'data segment':
* <ul>
* <li>'native'/Qortal 'trade' address - used as a MESSAGE contact</li>
* <li>'foreign'/Digibyte public key hash - used by Alice's P2SH scripts to allow redeem</li>
* <li>QORT amount on offer by Bob</li>
* <li>DGB amount expected in return by Bob (from Alice)</li>
* <li>trading timeout, in case things go wrong and everyone needs to refund</li>
* </ul>
* Returns a DEPLOY_AT transaction that needs to be signed and broadcast to the Qortal network.
* <p>
* Trade-bot will wait for Bob's AT to be deployed before taking next step.
* <p>
* @param repository
* @param tradeBotCreateRequest
* @return raw, unsigned DEPLOY_AT transaction
* @throws DataException
*/
public byte[] createTrade(Repository repository, TradeBotCreateRequest tradeBotCreateRequest) throws DataException {
byte[] tradePrivateKey = TradeBot.generateTradePrivateKey();
byte[] tradeNativePublicKey = TradeBot.deriveTradeNativePublicKey(tradePrivateKey);
byte[] tradeNativePublicKeyHash = Crypto.hash160(tradeNativePublicKey);
String tradeNativeAddress = Crypto.toAddress(tradeNativePublicKey);
byte[] tradeForeignPublicKey = TradeBot.deriveTradeForeignPublicKey(tradePrivateKey);
byte[] tradeForeignPublicKeyHash = Crypto.hash160(tradeForeignPublicKey);
// Convert Digibyte receiving address into public key hash (we only support P2PKH at this time)
Address digibyteReceivingAddress;
try {
digibyteReceivingAddress = Address.fromString(Digibyte.getInstance().getNetworkParameters(), tradeBotCreateRequest.receivingAddress);
} catch (AddressFormatException e) {
throw new DataException("Unsupported Digibyte receiving address: " + tradeBotCreateRequest.receivingAddress);
}
if (digibyteReceivingAddress.getOutputScriptType() != ScriptType.P2PKH)
throw new DataException("Unsupported Digibyte receiving address: " + tradeBotCreateRequest.receivingAddress);
byte[] digibyteReceivingAccountInfo = digibyteReceivingAddress.getHash();
PublicKeyAccount creator = new PublicKeyAccount(repository, tradeBotCreateRequest.creatorPublicKey);
// Deploy AT
long timestamp = NTP.getTime();
byte[] reference = creator.getLastReference();
long fee = 0L;
byte[] signature = null;
BaseTransactionData baseTransactionData = new BaseTransactionData(timestamp, Group.NO_GROUP, reference, creator.getPublicKey(), fee, signature);
String name = "QORT/DGB ACCT";
String description = "QORT/DGB cross-chain trade";
String aTType = "ACCT";
String tags = "ACCT QORT DGB";
byte[] creationBytes = DigibyteACCTv3.buildQortalAT(tradeNativeAddress, tradeForeignPublicKeyHash, tradeBotCreateRequest.qortAmount,
tradeBotCreateRequest.foreignAmount, tradeBotCreateRequest.tradeTimeout);
long amount = tradeBotCreateRequest.fundingQortAmount;
DeployAtTransactionData deployAtTransactionData = new DeployAtTransactionData(baseTransactionData, name, description, aTType, tags, creationBytes, amount, Asset.QORT);
DeployAtTransaction deployAtTransaction = new DeployAtTransaction(repository, deployAtTransactionData);
fee = deployAtTransaction.calcRecommendedFee();
deployAtTransactionData.setFee(fee);
DeployAtTransaction.ensureATAddress(deployAtTransactionData);
String atAddress = deployAtTransactionData.getAtAddress();
TradeBotData tradeBotData = new TradeBotData(tradePrivateKey, DigibyteACCTv3.NAME,
State.BOB_WAITING_FOR_AT_CONFIRM.name(), State.BOB_WAITING_FOR_AT_CONFIRM.value,
creator.getAddress(), atAddress, timestamp, tradeBotCreateRequest.qortAmount,
tradeNativePublicKey, tradeNativePublicKeyHash, tradeNativeAddress,
null, null,
SupportedBlockchain.DIGIBYTE.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
tradeBotCreateRequest.foreignAmount, null, null, null, digibyteReceivingAccountInfo);
TradeBot.updateTradeBotState(repository, tradeBotData, () -> String.format("Built AT %s. Waiting for deployment", atAddress));
// Attempt to backup the trade bot data
TradeBot.backupTradeBotData(repository, null);
// Return to user for signing and broadcast as we don't have their Qortal private key
try {
return DeployAtTransactionTransformer.toBytes(deployAtTransactionData);
} catch (TransformationException e) {
throw new DataException("Failed to transform DEPLOY_AT transaction?", e);
}
}
/**
* Creates a trade-bot entry from the 'Alice' viewpoint, i.e. matching DGB to an existing offer.
* <p>
* Requires a chosen trade offer from Bob, passed by <tt>crossChainTradeData</tt>
* and access to a Digibyte wallet via <tt>xprv58</tt>.
* <p>
* The <tt>crossChainTradeData</tt> contains the current trade offer state
* as extracted from the AT's data segment.
* <p>
* Access to a funded wallet is via a Digibyte BIP32 hierarchical deterministic key,
* passed via <tt>xprv58</tt>.
* <b>This key will be stored in your node's database</b>
* to allow trade-bot to create/fund the necessary P2SH transactions!
* However, due to the nature of BIP32 keys, it is possible to give the trade-bot
* only a subset of wallet access (see BIP32 for more details).
* <p>
* As an example, the xprv58 can be extract from a <i>legacy, password-less</i>
* Electrum wallet by going to the console tab and entering:<br>
* <tt>wallet.keystore.xprv</tt><br>
* which should result in a base58 string starting with either 'xprv' (for Digibyte main-net)
* or 'tprv' for (Digibyte test-net).
* <p>
* It is envisaged that the value in <tt>xprv58</tt> will actually come from a Qortal-UI-managed wallet.
* <p>
* If sufficient funds are available, <b>this method will actually fund the P2SH-A</b>
* with the Digibyte amount expected by 'Bob'.
* <p>
* If the Digibyte transaction is successfully broadcast to the network then
* we also send a MESSAGE to Bob's trade-bot to let them know.
* <p>
* The trade-bot entry is saved to the repository and the cross-chain trading process commences.
* <p>
* @param repository
* @param crossChainTradeData chosen trade OFFER that Alice wants to match
* @param xprv58 funded wallet xprv in base58
* @return true if P2SH-A funding transaction successfully broadcast to Digibyte network, false otherwise
* @throws DataException
*/
public ResponseResult startResponse(Repository repository, ATData atData, ACCT acct, CrossChainTradeData crossChainTradeData, String xprv58, String receivingAddress) throws DataException {
byte[] tradePrivateKey = TradeBot.generateTradePrivateKey();
byte[] secretA = TradeBot.generateSecret();
byte[] hashOfSecretA = Crypto.hash160(secretA);
byte[] tradeNativePublicKey = TradeBot.deriveTradeNativePublicKey(tradePrivateKey);
byte[] tradeNativePublicKeyHash = Crypto.hash160(tradeNativePublicKey);
String tradeNativeAddress = Crypto.toAddress(tradeNativePublicKey);
byte[] tradeForeignPublicKey = TradeBot.deriveTradeForeignPublicKey(tradePrivateKey);
byte[] tradeForeignPublicKeyHash = Crypto.hash160(tradeForeignPublicKey);
byte[] receivingPublicKeyHash = Base58.decode(receivingAddress); // Actually the whole address, not just PKH
// We need to generate lockTime-A: add tradeTimeout to now
long now = NTP.getTime();
int lockTimeA = crossChainTradeData.tradeTimeout * 60 + (int) (now / 1000L);
TradeBotData tradeBotData = new TradeBotData(tradePrivateKey, DigibyteACCTv3.NAME,
State.ALICE_WAITING_FOR_AT_LOCK.name(), State.ALICE_WAITING_FOR_AT_LOCK.value,
receivingAddress, crossChainTradeData.qortalAtAddress, now, crossChainTradeData.qortAmount,
tradeNativePublicKey, tradeNativePublicKeyHash, tradeNativeAddress,
secretA, hashOfSecretA,
SupportedBlockchain.DIGIBYTE.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
crossChainTradeData.expectedForeignAmount, xprv58, null, lockTimeA, receivingPublicKeyHash);
// Attempt to backup the trade bot data
// Include tradeBotData as an additional parameter, since it's not in the repository yet
TradeBot.backupTradeBotData(repository, Arrays.asList(tradeBotData));
// Check we have enough funds via xprv58 to fund P2SH to cover expectedForeignAmount
long p2shFee;
try {
p2shFee = Digibyte.getInstance().getP2shFee(now);
} catch (ForeignBlockchainException e) {
LOGGER.debug("Couldn't estimate Digibyte fees?");
return ResponseResult.NETWORK_ISSUE;
}
// Fee for redeem/refund is subtracted from P2SH-A balance.
// Do not include fee for funding transaction as this is covered by buildSpend()
long amountA = crossChainTradeData.expectedForeignAmount + p2shFee /*redeeming/refunding P2SH-A*/;
// P2SH-A to be funded
byte[] redeemScriptBytes = BitcoinyHTLC.buildScript(tradeForeignPublicKeyHash, lockTimeA, crossChainTradeData.creatorForeignPKH, hashOfSecretA);
String p2shAddress = Digibyte.getInstance().deriveP2shAddress(redeemScriptBytes);
// Build transaction for funding P2SH-A
Transaction p2shFundingTransaction = Digibyte.getInstance().buildSpend(tradeBotData.getForeignKey(), p2shAddress, amountA);
if (p2shFundingTransaction == null) {
LOGGER.debug("Unable to build P2SH-A funding transaction - lack of funds?");
return ResponseResult.BALANCE_ISSUE;
}
try {
Digibyte.getInstance().broadcastTransaction(p2shFundingTransaction);
} catch (ForeignBlockchainException e) {
// We couldn't fund P2SH-A at this time
LOGGER.debug("Couldn't broadcast P2SH-A funding transaction?");
return ResponseResult.NETWORK_ISSUE;
}
// Attempt to send MESSAGE to Bob's Qortal trade address
byte[] messageData = DigibyteACCTv3.buildOfferMessage(tradeBotData.getTradeForeignPublicKeyHash(), tradeBotData.getHashOfSecret(), tradeBotData.getLockTimeA());
String messageRecipient = crossChainTradeData.qortalCreatorTradeAddress;
boolean isMessageAlreadySent = repository.getMessageRepository().exists(tradeBotData.getTradeNativePublicKey(), messageRecipient, messageData);
if (!isMessageAlreadySent) {
PrivateKeyAccount sender = new PrivateKeyAccount(repository, tradeBotData.getTradePrivateKey());
MessageTransaction messageTransaction = MessageTransaction.build(repository, sender, Group.NO_GROUP, messageRecipient, messageData, false, false);
messageTransaction.computeNonce();
messageTransaction.sign(sender);
// reset repository state to prevent deadlock
repository.discardChanges();
ValidationResult result = messageTransaction.importAsUnconfirmed();
if (result != ValidationResult.OK) {
LOGGER.warn(() -> String.format("Unable to send MESSAGE to Bob's trade-bot %s: %s", messageRecipient, result.name()));
return ResponseResult.NETWORK_ISSUE;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, () -> String.format("Funding P2SH-A %s. Messaged Bob. Waiting for AT-lock", p2shAddress));
return ResponseResult.OK;
}
@Override
public boolean canDelete(Repository repository, TradeBotData tradeBotData) throws DataException {
State tradeBotState = State.valueOf(tradeBotData.getStateValue());
if (tradeBotState == null)
return true;
// If the AT doesn't exist then we might as well let the user tidy up
if (!repository.getATRepository().exists(tradeBotData.getAtAddress()))
return true;
switch (tradeBotState) {
case BOB_WAITING_FOR_AT_CONFIRM:
case ALICE_DONE:
case BOB_DONE:
case ALICE_REFUNDED:
case BOB_REFUNDED:
case ALICE_REFUNDING_A:
return true;
default:
return false;
}
}
@Override
public void progress(Repository repository, TradeBotData tradeBotData) throws DataException, ForeignBlockchainException {
State tradeBotState = State.valueOf(tradeBotData.getStateValue());
if (tradeBotState == null) {
LOGGER.info(() -> String.format("Trade-bot entry for AT %s has invalid state?", tradeBotData.getAtAddress()));
return;
}
ATData atData = null;
CrossChainTradeData tradeData = null;
if (tradeBotState.requiresAtData) {
// Attempt to fetch AT data
atData = repository.getATRepository().fromATAddress(tradeBotData.getAtAddress());
if (atData == null) {
LOGGER.debug(() -> String.format("Unable to fetch trade AT %s from repository", tradeBotData.getAtAddress()));
return;
}
if (tradeBotState.requiresTradeData) {
tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
if (tradeData == null) {
LOGGER.warn(() -> String.format("Unable to fetch ACCT trade data for AT %s from repository", tradeBotData.getAtAddress()));
return;
}
}
}
switch (tradeBotState) {
case BOB_WAITING_FOR_AT_CONFIRM:
handleBobWaitingForAtConfirm(repository, tradeBotData);
break;
case BOB_WAITING_FOR_MESSAGE:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleBobWaitingForMessage(repository, tradeBotData, atData, tradeData);
break;
case ALICE_WAITING_FOR_AT_LOCK:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleAliceWaitingForAtLock(repository, tradeBotData, atData, tradeData);
break;
case BOB_WAITING_FOR_AT_REDEEM:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleBobWaitingForAtRedeem(repository, tradeBotData, atData, tradeData);
break;
case ALICE_DONE:
case BOB_DONE:
break;
case ALICE_REFUNDING_A:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleAliceRefundingP2shA(repository, tradeBotData, atData, tradeData);
break;
case ALICE_REFUNDED:
case BOB_REFUNDED:
break;
}
}
/**
* Trade-bot is waiting for Bob's AT to deploy.
* <p>
* If AT is deployed, then trade-bot's next step is to wait for MESSAGE from Alice.
*/
private void handleBobWaitingForAtConfirm(Repository repository, TradeBotData tradeBotData) throws DataException {
if (!repository.getATRepository().exists(tradeBotData.getAtAddress())) {
if (NTP.getTime() - tradeBotData.getTimestamp() <= MAX_AT_CONFIRMATION_PERIOD)
return;
// We've waited ages for AT to be confirmed into a block but something has gone awry.
// After this long we assume transaction loss so give up with trade-bot entry too.
tradeBotData.setState(State.BOB_REFUNDED.name());
tradeBotData.setStateValue(State.BOB_REFUNDED.value);
tradeBotData.setTimestamp(NTP.getTime());
// We delete trade-bot entry here instead of saving, hence not using updateTradeBotState()
repository.getCrossChainRepository().delete(tradeBotData.getTradePrivateKey());
repository.saveChanges();
LOGGER.info(() -> String.format("AT %s never confirmed. Giving up on trade", tradeBotData.getAtAddress()));
TradeBot.notifyStateChange(tradeBotData);
return;
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_WAITING_FOR_MESSAGE,
() -> String.format("AT %s confirmed ready. Waiting for trade message", tradeBotData.getAtAddress()));
}
/**
* Trade-bot is waiting for MESSAGE from Alice's trade-bot, containing Alice's trade info.
* <p>
* It's possible Bob has cancelling his trade offer, receiving an automatic QORT refund,
* in which case trade-bot is done with this specific trade and finalizes on refunded state.
* <p>
* Assuming trade is still on offer, trade-bot checks the contents of MESSAGE from Alice's trade-bot.
* <p>
* Details from Alice are used to derive P2SH-A address and this is checked for funding balance.
* <p>
* Assuming P2SH-A has at least expected Digibyte balance,
* Bob's trade-bot constructs a zero-fee, PoW MESSAGE to send to Bob's AT with more trade details.
* <p>
* On processing this MESSAGE, Bob's AT should switch into 'TRADE' mode and only trade with Alice.
* <p>
* Trade-bot's next step is to wait for Alice to redeem the AT, which will allow Bob to
* extract secret-A needed to redeem Alice's P2SH.
* @throws ForeignBlockchainException
*/
private void handleBobWaitingForMessage(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
// If AT has finished then Bob likely cancelled his trade offer
if (atData.getIsFinished()) {
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s cancelled - trading aborted", tradeBotData.getAtAddress()));
return;
}
Digibyte digibyte = Digibyte.getInstance();
String address = tradeBotData.getTradeNativeAddress();
List<MessageTransactionData> messageTransactionsData = repository.getMessageRepository().getMessagesByParticipants(null, address, null, null, null);
for (MessageTransactionData messageTransactionData : messageTransactionsData) {
if (messageTransactionData.isText())
continue;
// We're expecting: HASH160(secret-A), Alice's Digibyte pubkeyhash and lockTime-A
byte[] messageData = messageTransactionData.getData();
DigibyteACCTv3.OfferMessageData offerMessageData = DigibyteACCTv3.extractOfferMessageData(messageData);
if (offerMessageData == null)
continue;
byte[] aliceForeignPublicKeyHash = offerMessageData.partnerDigibytePKH;
byte[] hashOfSecretA = offerMessageData.hashOfSecretA;
int lockTimeA = (int) offerMessageData.lockTimeA;
long messageTimestamp = messageTransactionData.getTimestamp();
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(messageTimestamp, lockTimeA);
// Determine P2SH-A address and confirm funded
byte[] redeemScriptA = BitcoinyHTLC.buildScript(aliceForeignPublicKeyHash, lockTimeA, tradeBotData.getTradeForeignPublicKeyHash(), hashOfSecretA);
String p2shAddressA = digibyte.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Digibyte.getInstance().getP2shFee(feeTimestamp);
final long minimumAmountA = tradeBotData.getForeignAmount() + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(digibyte.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
// There might be another MESSAGE from someone else with an actually funded P2SH-A...
continue;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// We've already redeemed this?
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_DONE,
() -> String.format("P2SH-A %s already spent? Assuming trade complete", p2shAddressA));
return;
case REFUND_IN_PROGRESS:
case REFUNDED:
// This P2SH-A is burnt, but there might be another MESSAGE from someone else with an actually funded P2SH-A...
continue;
case FUNDED:
// Fall-through out of switch...
break;
}
// Good to go - send MESSAGE to AT
String aliceNativeAddress = Crypto.toAddress(messageTransactionData.getCreatorPublicKey());
// Build outgoing message, padding each part to 32 bytes to make it easier for AT to consume
byte[] outgoingMessageData = DigibyteACCTv3.buildTradeMessage(aliceNativeAddress, aliceForeignPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
String messageRecipient = tradeBotData.getAtAddress();
boolean isMessageAlreadySent = repository.getMessageRepository().exists(tradeBotData.getTradeNativePublicKey(), messageRecipient, outgoingMessageData);
if (!isMessageAlreadySent) {
PrivateKeyAccount sender = new PrivateKeyAccount(repository, tradeBotData.getTradePrivateKey());
MessageTransaction outgoingMessageTransaction = MessageTransaction.build(repository, sender, Group.NO_GROUP, messageRecipient, outgoingMessageData, false, false);
outgoingMessageTransaction.computeNonce();
outgoingMessageTransaction.sign(sender);
// reset repository state to prevent deadlock
repository.discardChanges();
ValidationResult result = outgoingMessageTransaction.importAsUnconfirmed();
if (result != ValidationResult.OK) {
LOGGER.warn(() -> String.format("Unable to send MESSAGE to AT %s: %s", messageRecipient, result.name()));
return;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_WAITING_FOR_AT_REDEEM,
() -> String.format("Locked AT %s to %s. Waiting for AT redeem", tradeBotData.getAtAddress(), aliceNativeAddress));
return;
}
}
/**
* Trade-bot is waiting for Bob's AT to switch to TRADE mode and lock trade to Alice only.
* <p>
* It's possible that Bob has cancelled his trade offer in the mean time, or that somehow
* this process has taken so long that we've reached P2SH-A's locktime, or that someone else
* has managed to trade with Bob. In any of these cases, trade-bot switches to begin the refunding process.
* <p>
* Assuming Bob's AT is locked to Alice, trade-bot checks AT's state data to make sure it is correct.
* <p>
* If all is well, trade-bot then redeems AT using Alice's secret-A, releasing Bob's QORT to Alice.
* <p>
* In revealing a valid secret-A, Bob can then redeem the DGB funds from P2SH-A.
* <p>
* @throws ForeignBlockchainException
*/
private void handleAliceWaitingForAtLock(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
if (aliceUnexpectedState(repository, tradeBotData, atData, crossChainTradeData))
return;
Digibyte digibyte = Digibyte.getInstance();
int lockTimeA = tradeBotData.getLockTimeA();
// Refund P2SH-A if we've passed lockTime-A
if (NTP.getTime() >= lockTimeA * 1000L) {
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = digibyte.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Digibyte.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(digibyte.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
case FUNDED:
break;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// Already redeemed?
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("P2SH-A %s already spent? Assuming trade completed", p2shAddressA));
return;
case REFUND_IN_PROGRESS:
case REFUNDED:
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDED,
() -> String.format("P2SH-A %s already refunded. Trade aborted", p2shAddressA));
return;
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDING_A,
() -> atData.getIsFinished()
? String.format("AT %s cancelled. Refunding P2SH-A %s - aborting trade", tradeBotData.getAtAddress(), p2shAddressA)
: String.format("LockTime-A reached, refunding P2SH-A %s - aborting trade", p2shAddressA));
return;
}
// We're waiting for AT to be in TRADE mode
if (crossChainTradeData.mode != AcctMode.TRADING)
return;
// AT is in TRADE mode and locked to us as checked by aliceUnexpectedState() above
// Find our MESSAGE to AT from previous state
List<MessageTransactionData> messageTransactionsData = repository.getMessageRepository().getMessagesByParticipants(tradeBotData.getTradeNativePublicKey(),
crossChainTradeData.qortalCreatorTradeAddress, null, null, null);
if (messageTransactionsData == null || messageTransactionsData.isEmpty()) {
LOGGER.warn(() -> String.format("Unable to find our message to trade creator %s?", crossChainTradeData.qortalCreatorTradeAddress));
return;
}
long recipientMessageTimestamp = messageTransactionsData.get(0).getTimestamp();
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(recipientMessageTimestamp, lockTimeA);
// Our calculated refundTimeout should match AT's refundTimeout
if (refundTimeout != crossChainTradeData.refundTimeout) {
LOGGER.debug(() -> String.format("Trade AT refundTimeout '%d' doesn't match our refundTimeout '%d'", crossChainTradeData.refundTimeout, refundTimeout));
// We'll eventually refund
return;
}
// We're good to redeem AT
// Send 'redeem' MESSAGE to AT using both secret
byte[] secretA = tradeBotData.getSecret();
String qortalReceivingAddress = Base58.encode(tradeBotData.getReceivingAccountInfo()); // Actually contains whole address, not just PKH
byte[] messageData = DigibyteACCTv3.buildRedeemMessage(secretA, qortalReceivingAddress);
String messageRecipient = tradeBotData.getAtAddress();
boolean isMessageAlreadySent = repository.getMessageRepository().exists(tradeBotData.getTradeNativePublicKey(), messageRecipient, messageData);
if (!isMessageAlreadySent) {
PrivateKeyAccount sender = new PrivateKeyAccount(repository, tradeBotData.getTradePrivateKey());
MessageTransaction messageTransaction = MessageTransaction.build(repository, sender, Group.NO_GROUP, messageRecipient, messageData, false, false);
messageTransaction.computeNonce();
messageTransaction.sign(sender);
// Reset repository state to prevent deadlock
repository.discardChanges();
ValidationResult result = messageTransaction.importAsUnconfirmed();
if (result != ValidationResult.OK) {
LOGGER.warn(() -> String.format("Unable to send MESSAGE to AT %s: %s", messageRecipient, result.name()));
return;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("Redeeming AT %s. Funds should arrive at %s",
tradeBotData.getAtAddress(), qortalReceivingAddress));
}
/**
* Trade-bot is waiting for Alice to redeem Bob's AT, thus revealing secret-A which is required to spend the DGB funds from P2SH-A.
* <p>
* It's possible that Bob's AT has reached its trading timeout and automatically refunded QORT back to Bob. In which case,
* trade-bot is done with this specific trade and finalizes in refunded state.
* <p>
* Assuming trade-bot can extract a valid secret-A from Alice's MESSAGE then trade-bot uses that to redeem the DGB funds from P2SH-A
* to Bob's 'foreign'/Digibyte trade legacy-format address, as derived from trade private key.
* <p>
* (This could potentially be 'improved' to send DGB to any address of Bob's choosing by changing the transaction output).
* <p>
* If trade-bot successfully broadcasts the transaction, then this specific trade is done.
* @throws ForeignBlockchainException
*/
private void handleBobWaitingForAtRedeem(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
// AT should be 'finished' once Alice has redeemed QORT funds
if (!atData.getIsFinished())
// Not finished yet
return;
// If AT is REFUNDED or CANCELLED then something has gone wrong
if (crossChainTradeData.mode == AcctMode.REFUNDED || crossChainTradeData.mode == AcctMode.CANCELLED) {
// Alice hasn't redeemed the QORT, so there is no point in trying to redeem the DGB
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s has auto-refunded - trade aborted", tradeBotData.getAtAddress()));
return;
}
byte[] secretA = DigibyteACCTv3.getInstance().findSecretA(repository, crossChainTradeData);
if (secretA == null) {
LOGGER.debug(() -> String.format("Unable to find secret-A from redeem message to AT %s?", tradeBotData.getAtAddress()));
return;
}
// Use secret-A to redeem P2SH-A
Digibyte digibyte = Digibyte.getInstance();
byte[] receivingAccountInfo = tradeBotData.getReceivingAccountInfo();
int lockTimeA = crossChainTradeData.lockTimeA;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(crossChainTradeData.partnerForeignPKH, lockTimeA, crossChainTradeData.creatorForeignPKH, crossChainTradeData.hashOfSecretA);
String p2shAddressA = digibyte.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Digibyte.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(digibyte.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
// P2SH-A suddenly not funded? Our best bet at this point is to hope for AT auto-refund
return;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// Double-check that we have redeemed P2SH-A...
break;
case REFUND_IN_PROGRESS:
case REFUNDED:
// Wait for AT to auto-refund
return;
case FUNDED: {
Coin redeemAmount = Coin.valueOf(crossChainTradeData.expectedForeignAmount);
ECKey redeemKey = ECKey.fromPrivate(tradeBotData.getTradePrivateKey());
List<TransactionOutput> fundingOutputs = digibyte.getUnspentOutputs(p2shAddressA);
Transaction p2shRedeemTransaction = BitcoinyHTLC.buildRedeemTransaction(digibyte.getNetworkParameters(), redeemAmount, redeemKey,
fundingOutputs, redeemScriptA, secretA, receivingAccountInfo);
digibyte.broadcastTransaction(p2shRedeemTransaction);
break;
}
}
String receivingAddress = digibyte.pkhToAddress(receivingAccountInfo);
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_DONE,
() -> String.format("P2SH-A %s redeemed. Funds should arrive at %s", tradeBotData.getAtAddress(), receivingAddress));
}
/**
* Trade-bot is attempting to refund P2SH-A.
* @throws ForeignBlockchainException
*/
private void handleAliceRefundingP2shA(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
int lockTimeA = tradeBotData.getLockTimeA();
// We can't refund P2SH-A until lockTime-A has passed
if (NTP.getTime() <= lockTimeA * 1000L)
return;
Digibyte digibyte = Digibyte.getInstance();
// We can't refund P2SH-A until median block time has passed lockTime-A (see BIP113)
int medianBlockTime = digibyte.getMedianBlockTime();
if (medianBlockTime <= lockTimeA)
return;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = digibyte.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Digibyte.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(digibyte.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
// Still waiting for P2SH-A to be funded...
return;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// Too late!
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("P2SH-A %s already spent!", p2shAddressA));
return;
case REFUND_IN_PROGRESS:
case REFUNDED:
break;
case FUNDED:{
Coin refundAmount = Coin.valueOf(crossChainTradeData.expectedForeignAmount);
ECKey refundKey = ECKey.fromPrivate(tradeBotData.getTradePrivateKey());
List<TransactionOutput> fundingOutputs = digibyte.getUnspentOutputs(p2shAddressA);
// Determine receive address for refund
String receiveAddress = digibyte.getUnusedReceiveAddress(tradeBotData.getForeignKey());
Address receiving = Address.fromString(digibyte.getNetworkParameters(), receiveAddress);
Transaction p2shRefundTransaction = BitcoinyHTLC.buildRefundTransaction(digibyte.getNetworkParameters(), refundAmount, refundKey,
fundingOutputs, redeemScriptA, lockTimeA, receiving.getHash());
digibyte.broadcastTransaction(p2shRefundTransaction);
break;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDED,
() -> String.format("LockTime-A reached. Refunded P2SH-A %s. Trade aborted", p2shAddressA));
}
/**
* Returns true if Alice finds AT unexpectedly cancelled, refunded, redeemed or locked to someone else.
* <p>
* Will automatically update trade-bot state to <tt>ALICE_REFUNDING_A</tt> or <tt>ALICE_DONE</tt> as necessary.
*
* @throws DataException
* @throws ForeignBlockchainException
*/
private boolean aliceUnexpectedState(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
// This is OK
if (!atData.getIsFinished() && crossChainTradeData.mode == AcctMode.OFFERING)
return false;
boolean isAtLockedToUs = tradeBotData.getTradeNativeAddress().equals(crossChainTradeData.qortalPartnerAddress);
if (!atData.getIsFinished() && crossChainTradeData.mode == AcctMode.TRADING)
if (isAtLockedToUs) {
// AT is trading with us - OK
return false;
} else {
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDING_A,
() -> String.format("AT %s trading with someone else: %s. Refunding & aborting trade", tradeBotData.getAtAddress(), crossChainTradeData.qortalPartnerAddress));
return true;
}
if (atData.getIsFinished() && crossChainTradeData.mode == AcctMode.REDEEMED && isAtLockedToUs) {
// We've redeemed already?
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("AT %s already redeemed by us. Trade completed", tradeBotData.getAtAddress()));
} else {
// Any other state is not good, so start defensive refund
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDING_A,
() -> String.format("AT %s cancelled/refunded/redeemed by someone else/invalid state. Refunding & aborting trade", tradeBotData.getAtAddress()));
}
return true;
}
private long calcFeeTimestamp(int lockTimeA, int tradeTimeout) {
return (lockTimeA - tradeTimeout * 60) * 1000L;
}
}

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src/main/java/org/qortal/controller/tradebot/RavencoinACCTv3TradeBot.java Normal file
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package org.qortal.controller.tradebot;
import org.apache.logging.log4j.LogManager;
import org.apache.logging.log4j.Logger;
import org.bitcoinj.core.*;
import org.bitcoinj.script.Script.ScriptType;
import org.qortal.account.PrivateKeyAccount;
import org.qortal.account.PublicKeyAccount;
import org.qortal.api.model.crosschain.TradeBotCreateRequest;
import org.qortal.asset.Asset;
import org.qortal.crosschain.*;
import org.qortal.crypto.Crypto;
import org.qortal.data.at.ATData;
import org.qortal.data.crosschain.CrossChainTradeData;
import org.qortal.data.crosschain.TradeBotData;
import org.qortal.data.transaction.BaseTransactionData;
import org.qortal.data.transaction.DeployAtTransactionData;
import org.qortal.data.transaction.MessageTransactionData;
import org.qortal.group.Group;
import org.qortal.repository.DataException;
import org.qortal.repository.Repository;
import org.qortal.transaction.DeployAtTransaction;
import org.qortal.transaction.MessageTransaction;
import org.qortal.transaction.Transaction.ValidationResult;
import org.qortal.transform.TransformationException;
import org.qortal.transform.transaction.DeployAtTransactionTransformer;
import org.qortal.utils.Base58;
import org.qortal.utils.NTP;
import java.util.Arrays;
import java.util.List;
import java.util.Map;
import java.util.stream.Collectors;
import static java.util.Arrays.stream;
import static java.util.stream.Collectors.toMap;
/**
* Performing cross-chain trading steps on behalf of user.
* <p>
* We deal with three different independent state-spaces here:
* <ul>
* <li>Qortal blockchain</li>
* <li>Foreign blockchain</li>
* <li>Trade-bot entries</li>
* </ul>
*/
public class RavencoinACCTv3TradeBot implements AcctTradeBot {
private static final Logger LOGGER = LogManager.getLogger(RavencoinACCTv3TradeBot.class);
public enum State implements TradeBot.StateNameAndValueSupplier {
BOB_WAITING_FOR_AT_CONFIRM(10, false, false),
BOB_WAITING_FOR_MESSAGE(15, true, true),
BOB_WAITING_FOR_AT_REDEEM(25, true, true),
BOB_DONE(30, false, false),
BOB_REFUNDED(35, false, false),
ALICE_WAITING_FOR_AT_LOCK(85, true, true),
ALICE_DONE(95, false, false),
ALICE_REFUNDING_A(105, true, true),
ALICE_REFUNDED(110, false, false);
private static final Map<Integer, State> map = stream(State.values()).collect(toMap(state -> state.value, state -> state));
public final int value;
public final boolean requiresAtData;
public final boolean requiresTradeData;
State(int value, boolean requiresAtData, boolean requiresTradeData) {
this.value = value;
this.requiresAtData = requiresAtData;
this.requiresTradeData = requiresTradeData;
}
public static State valueOf(int value) {
return map.get(value);
}
@Override
public String getState() {
return this.name();
}
@Override
public int getStateValue() {
return this.value;
}
}
/** Maximum time Bob waits for his AT creation transaction to be confirmed into a block. (milliseconds) */
private static final long MAX_AT_CONFIRMATION_PERIOD = 24 * 60 * 60 * 1000L; // ms
private static RavencoinACCTv3TradeBot instance;
private final List<String> endStates = Arrays.asList(State.BOB_DONE, State.BOB_REFUNDED, State.ALICE_DONE, State.ALICE_REFUNDING_A, State.ALICE_REFUNDED).stream()
.map(State::name)
.collect(Collectors.toUnmodifiableList());
private RavencoinACCTv3TradeBot() {
}
public static synchronized RavencoinACCTv3TradeBot getInstance() {
if (instance == null)
instance = new RavencoinACCTv3TradeBot();
return instance;
}
@Override
public List<String> getEndStates() {
return this.endStates;
}
/**
* Creates a new trade-bot entry from the "Bob" viewpoint, i.e. OFFERing QORT in exchange for RVN.
* <p>
* Generates:
* <ul>
* <li>new 'trade' private key</li>
* </ul>
* Derives:
* <ul>
* <li>'native' (as in Qortal) public key, public key hash, address (starting with Q)</li>
* <li>'foreign' (as in Ravencoin) public key, public key hash</li>
* </ul>
* A Qortal AT is then constructed including the following as constants in the 'data segment':
* <ul>
* <li>'native'/Qortal 'trade' address - used as a MESSAGE contact</li>
* <li>'foreign'/Ravencoin public key hash - used by Alice's P2SH scripts to allow redeem</li>
* <li>QORT amount on offer by Bob</li>
* <li>RVN amount expected in return by Bob (from Alice)</li>
* <li>trading timeout, in case things go wrong and everyone needs to refund</li>
* </ul>
* Returns a DEPLOY_AT transaction that needs to be signed and broadcast to the Qortal network.
* <p>
* Trade-bot will wait for Bob's AT to be deployed before taking next step.
* <p>
* @param repository
* @param tradeBotCreateRequest
* @return raw, unsigned DEPLOY_AT transaction
* @throws DataException
*/
public byte[] createTrade(Repository repository, TradeBotCreateRequest tradeBotCreateRequest) throws DataException {
byte[] tradePrivateKey = TradeBot.generateTradePrivateKey();
byte[] tradeNativePublicKey = TradeBot.deriveTradeNativePublicKey(tradePrivateKey);
byte[] tradeNativePublicKeyHash = Crypto.hash160(tradeNativePublicKey);
String tradeNativeAddress = Crypto.toAddress(tradeNativePublicKey);
byte[] tradeForeignPublicKey = TradeBot.deriveTradeForeignPublicKey(tradePrivateKey);
byte[] tradeForeignPublicKeyHash = Crypto.hash160(tradeForeignPublicKey);
// Convert Ravencoin receiving address into public key hash (we only support P2PKH at this time)
Address ravencoinReceivingAddress;
try {
ravencoinReceivingAddress = Address.fromString(Ravencoin.getInstance().getNetworkParameters(), tradeBotCreateRequest.receivingAddress);
} catch (AddressFormatException e) {
throw new DataException("Unsupported Ravencoin receiving address: " + tradeBotCreateRequest.receivingAddress);
}
if (ravencoinReceivingAddress.getOutputScriptType() != ScriptType.P2PKH)
throw new DataException("Unsupported Ravencoin receiving address: " + tradeBotCreateRequest.receivingAddress);
byte[] ravencoinReceivingAccountInfo = ravencoinReceivingAddress.getHash();
PublicKeyAccount creator = new PublicKeyAccount(repository, tradeBotCreateRequest.creatorPublicKey);
// Deploy AT
long timestamp = NTP.getTime();
byte[] reference = creator.getLastReference();
long fee = 0L;
byte[] signature = null;
BaseTransactionData baseTransactionData = new BaseTransactionData(timestamp, Group.NO_GROUP, reference, creator.getPublicKey(), fee, signature);
String name = "QORT/RVN ACCT";
String description = "QORT/RVN cross-chain trade";
String aTType = "ACCT";
String tags = "ACCT QORT RVN";
byte[] creationBytes = RavencoinACCTv3.buildQortalAT(tradeNativeAddress, tradeForeignPublicKeyHash, tradeBotCreateRequest.qortAmount,
tradeBotCreateRequest.foreignAmount, tradeBotCreateRequest.tradeTimeout);
long amount = tradeBotCreateRequest.fundingQortAmount;
DeployAtTransactionData deployAtTransactionData = new DeployAtTransactionData(baseTransactionData, name, description, aTType, tags, creationBytes, amount, Asset.QORT);
DeployAtTransaction deployAtTransaction = new DeployAtTransaction(repository, deployAtTransactionData);
fee = deployAtTransaction.calcRecommendedFee();
deployAtTransactionData.setFee(fee);
DeployAtTransaction.ensureATAddress(deployAtTransactionData);
String atAddress = deployAtTransactionData.getAtAddress();
TradeBotData tradeBotData = new TradeBotData(tradePrivateKey, RavencoinACCTv3.NAME,
State.BOB_WAITING_FOR_AT_CONFIRM.name(), State.BOB_WAITING_FOR_AT_CONFIRM.value,
creator.getAddress(), atAddress, timestamp, tradeBotCreateRequest.qortAmount,
tradeNativePublicKey, tradeNativePublicKeyHash, tradeNativeAddress,
null, null,
SupportedBlockchain.RAVENCOIN.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
tradeBotCreateRequest.foreignAmount, null, null, null, ravencoinReceivingAccountInfo);
TradeBot.updateTradeBotState(repository, tradeBotData, () -> String.format("Built AT %s. Waiting for deployment", atAddress));
// Attempt to backup the trade bot data
TradeBot.backupTradeBotData(repository, null);
// Return to user for signing and broadcast as we don't have their Qortal private key
try {
return DeployAtTransactionTransformer.toBytes(deployAtTransactionData);
} catch (TransformationException e) {
throw new DataException("Failed to transform DEPLOY_AT transaction?", e);
}
}
/**
* Creates a trade-bot entry from the 'Alice' viewpoint, i.e. matching RVN to an existing offer.
* <p>
* Requires a chosen trade offer from Bob, passed by <tt>crossChainTradeData</tt>
* and access to a Ravencoin wallet via <tt>xprv58</tt>.
* <p>
* The <tt>crossChainTradeData</tt> contains the current trade offer state
* as extracted from the AT's data segment.
* <p>
* Access to a funded wallet is via a Ravencoin BIP32 hierarchical deterministic key,
* passed via <tt>xprv58</tt>.
* <b>This key will be stored in your node's database</b>
* to allow trade-bot to create/fund the necessary P2SH transactions!
* However, due to the nature of BIP32 keys, it is possible to give the trade-bot
* only a subset of wallet access (see BIP32 for more details).
* <p>
* As an example, the xprv58 can be extract from a <i>legacy, password-less</i>
* Electrum wallet by going to the console tab and entering:<br>
* <tt>wallet.keystore.xprv</tt><br>
* which should result in a base58 string starting with either 'xprv' (for Ravencoin main-net)
* or 'tprv' for (Ravencoin test-net).
* <p>
* It is envisaged that the value in <tt>xprv58</tt> will actually come from a Qortal-UI-managed wallet.
* <p>
* If sufficient funds are available, <b>this method will actually fund the P2SH-A</b>
* with the Ravencoin amount expected by 'Bob'.
* <p>
* If the Ravencoin transaction is successfully broadcast to the network then
* we also send a MESSAGE to Bob's trade-bot to let them know.
* <p>
* The trade-bot entry is saved to the repository and the cross-chain trading process commences.
* <p>
* @param repository
* @param crossChainTradeData chosen trade OFFER that Alice wants to match
* @param xprv58 funded wallet xprv in base58
* @return true if P2SH-A funding transaction successfully broadcast to Ravencoin network, false otherwise
* @throws DataException
*/
public ResponseResult startResponse(Repository repository, ATData atData, ACCT acct, CrossChainTradeData crossChainTradeData, String xprv58, String receivingAddress) throws DataException {
byte[] tradePrivateKey = TradeBot.generateTradePrivateKey();
byte[] secretA = TradeBot.generateSecret();
byte[] hashOfSecretA = Crypto.hash160(secretA);
byte[] tradeNativePublicKey = TradeBot.deriveTradeNativePublicKey(tradePrivateKey);
byte[] tradeNativePublicKeyHash = Crypto.hash160(tradeNativePublicKey);
String tradeNativeAddress = Crypto.toAddress(tradeNativePublicKey);
byte[] tradeForeignPublicKey = TradeBot.deriveTradeForeignPublicKey(tradePrivateKey);
byte[] tradeForeignPublicKeyHash = Crypto.hash160(tradeForeignPublicKey);
byte[] receivingPublicKeyHash = Base58.decode(receivingAddress); // Actually the whole address, not just PKH
// We need to generate lockTime-A: add tradeTimeout to now
long now = NTP.getTime();
int lockTimeA = crossChainTradeData.tradeTimeout * 60 + (int) (now / 1000L);
TradeBotData tradeBotData = new TradeBotData(tradePrivateKey, RavencoinACCTv3.NAME,
State.ALICE_WAITING_FOR_AT_LOCK.name(), State.ALICE_WAITING_FOR_AT_LOCK.value,
receivingAddress, crossChainTradeData.qortalAtAddress, now, crossChainTradeData.qortAmount,
tradeNativePublicKey, tradeNativePublicKeyHash, tradeNativeAddress,
secretA, hashOfSecretA,
SupportedBlockchain.RAVENCOIN.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
crossChainTradeData.expectedForeignAmount, xprv58, null, lockTimeA, receivingPublicKeyHash);
// Attempt to backup the trade bot data
// Include tradeBotData as an additional parameter, since it's not in the repository yet
TradeBot.backupTradeBotData(repository, Arrays.asList(tradeBotData));
// Check we have enough funds via xprv58 to fund P2SH to cover expectedForeignAmount
long p2shFee;
try {
p2shFee = Ravencoin.getInstance().getP2shFee(now);
} catch (ForeignBlockchainException e) {
LOGGER.debug("Couldn't estimate Ravencoin fees?");
return ResponseResult.NETWORK_ISSUE;
}
// Fee for redeem/refund is subtracted from P2SH-A balance.
// Do not include fee for funding transaction as this is covered by buildSpend()
long amountA = crossChainTradeData.expectedForeignAmount + p2shFee /*redeeming/refunding P2SH-A*/;
// P2SH-A to be funded
byte[] redeemScriptBytes = BitcoinyHTLC.buildScript(tradeForeignPublicKeyHash, lockTimeA, crossChainTradeData.creatorForeignPKH, hashOfSecretA);
String p2shAddress = Ravencoin.getInstance().deriveP2shAddress(redeemScriptBytes);
// Build transaction for funding P2SH-A
Transaction p2shFundingTransaction = Ravencoin.getInstance().buildSpend(tradeBotData.getForeignKey(), p2shAddress, amountA);
if (p2shFundingTransaction == null) {
LOGGER.debug("Unable to build P2SH-A funding transaction - lack of funds?");
return ResponseResult.BALANCE_ISSUE;
}
try {
Ravencoin.getInstance().broadcastTransaction(p2shFundingTransaction);
} catch (ForeignBlockchainException e) {
// We couldn't fund P2SH-A at this time
LOGGER.debug("Couldn't broadcast P2SH-A funding transaction?");
return ResponseResult.NETWORK_ISSUE;
}
// Attempt to send MESSAGE to Bob's Qortal trade address
byte[] messageData = RavencoinACCTv3.buildOfferMessage(tradeBotData.getTradeForeignPublicKeyHash(), tradeBotData.getHashOfSecret(), tradeBotData.getLockTimeA());
String messageRecipient = crossChainTradeData.qortalCreatorTradeAddress;
boolean isMessageAlreadySent = repository.getMessageRepository().exists(tradeBotData.getTradeNativePublicKey(), messageRecipient, messageData);
if (!isMessageAlreadySent) {
PrivateKeyAccount sender = new PrivateKeyAccount(repository, tradeBotData.getTradePrivateKey());
MessageTransaction messageTransaction = MessageTransaction.build(repository, sender, Group.NO_GROUP, messageRecipient, messageData, false, false);
messageTransaction.computeNonce();
messageTransaction.sign(sender);
// reset repository state to prevent deadlock
repository.discardChanges();
ValidationResult result = messageTransaction.importAsUnconfirmed();
if (result != ValidationResult.OK) {
LOGGER.warn(() -> String.format("Unable to send MESSAGE to Bob's trade-bot %s: %s", messageRecipient, result.name()));
return ResponseResult.NETWORK_ISSUE;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, () -> String.format("Funding P2SH-A %s. Messaged Bob. Waiting for AT-lock", p2shAddress));
return ResponseResult.OK;
}
@Override
public boolean canDelete(Repository repository, TradeBotData tradeBotData) throws DataException {
State tradeBotState = State.valueOf(tradeBotData.getStateValue());
if (tradeBotState == null)
return true;
// If the AT doesn't exist then we might as well let the user tidy up
if (!repository.getATRepository().exists(tradeBotData.getAtAddress()))
return true;
switch (tradeBotState) {
case BOB_WAITING_FOR_AT_CONFIRM:
case ALICE_DONE:
case BOB_DONE:
case ALICE_REFUNDED:
case BOB_REFUNDED:
case ALICE_REFUNDING_A:
return true;
default:
return false;
}
}
@Override
public void progress(Repository repository, TradeBotData tradeBotData) throws DataException, ForeignBlockchainException {
State tradeBotState = State.valueOf(tradeBotData.getStateValue());
if (tradeBotState == null) {
LOGGER.info(() -> String.format("Trade-bot entry for AT %s has invalid state?", tradeBotData.getAtAddress()));
return;
}
ATData atData = null;
CrossChainTradeData tradeData = null;
if (tradeBotState.requiresAtData) {
// Attempt to fetch AT data
atData = repository.getATRepository().fromATAddress(tradeBotData.getAtAddress());
if (atData == null) {
LOGGER.debug(() -> String.format("Unable to fetch trade AT %s from repository", tradeBotData.getAtAddress()));
return;
}
if (tradeBotState.requiresTradeData) {
tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
if (tradeData == null) {
LOGGER.warn(() -> String.format("Unable to fetch ACCT trade data for AT %s from repository", tradeBotData.getAtAddress()));
return;
}
}
}
switch (tradeBotState) {
case BOB_WAITING_FOR_AT_CONFIRM:
handleBobWaitingForAtConfirm(repository, tradeBotData);
break;
case BOB_WAITING_FOR_MESSAGE:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleBobWaitingForMessage(repository, tradeBotData, atData, tradeData);
break;
case ALICE_WAITING_FOR_AT_LOCK:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleAliceWaitingForAtLock(repository, tradeBotData, atData, tradeData);
break;
case BOB_WAITING_FOR_AT_REDEEM:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleBobWaitingForAtRedeem(repository, tradeBotData, atData, tradeData);
break;
case ALICE_DONE:
case BOB_DONE:
break;
case ALICE_REFUNDING_A:
TradeBot.getInstance().updatePresence(repository, tradeBotData, tradeData);
handleAliceRefundingP2shA(repository, tradeBotData, atData, tradeData);
break;
case ALICE_REFUNDED:
case BOB_REFUNDED:
break;
}
}
/**
* Trade-bot is waiting for Bob's AT to deploy.
* <p>
* If AT is deployed, then trade-bot's next step is to wait for MESSAGE from Alice.
*/
private void handleBobWaitingForAtConfirm(Repository repository, TradeBotData tradeBotData) throws DataException {
if (!repository.getATRepository().exists(tradeBotData.getAtAddress())) {
if (NTP.getTime() - tradeBotData.getTimestamp() <= MAX_AT_CONFIRMATION_PERIOD)
return;
// We've waited ages for AT to be confirmed into a block but something has gone awry.
// After this long we assume transaction loss so give up with trade-bot entry too.
tradeBotData.setState(State.BOB_REFUNDED.name());
tradeBotData.setStateValue(State.BOB_REFUNDED.value);
tradeBotData.setTimestamp(NTP.getTime());
// We delete trade-bot entry here instead of saving, hence not using updateTradeBotState()
repository.getCrossChainRepository().delete(tradeBotData.getTradePrivateKey());
repository.saveChanges();
LOGGER.info(() -> String.format("AT %s never confirmed. Giving up on trade", tradeBotData.getAtAddress()));
TradeBot.notifyStateChange(tradeBotData);
return;
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_WAITING_FOR_MESSAGE,
() -> String.format("AT %s confirmed ready. Waiting for trade message", tradeBotData.getAtAddress()));
}
/**
* Trade-bot is waiting for MESSAGE from Alice's trade-bot, containing Alice's trade info.
* <p>
* It's possible Bob has cancelling his trade offer, receiving an automatic QORT refund,
* in which case trade-bot is done with this specific trade and finalizes on refunded state.
* <p>
* Assuming trade is still on offer, trade-bot checks the contents of MESSAGE from Alice's trade-bot.
* <p>
* Details from Alice are used to derive P2SH-A address and this is checked for funding balance.
* <p>
* Assuming P2SH-A has at least expected Ravencoin balance,
* Bob's trade-bot constructs a zero-fee, PoW MESSAGE to send to Bob's AT with more trade details.
* <p>
* On processing this MESSAGE, Bob's AT should switch into 'TRADE' mode and only trade with Alice.
* <p>
* Trade-bot's next step is to wait for Alice to redeem the AT, which will allow Bob to
* extract secret-A needed to redeem Alice's P2SH.
* @throws ForeignBlockchainException
*/
private void handleBobWaitingForMessage(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
// If AT has finished then Bob likely cancelled his trade offer
if (atData.getIsFinished()) {
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s cancelled - trading aborted", tradeBotData.getAtAddress()));
return;
}
Ravencoin ravencoin = Ravencoin.getInstance();
String address = tradeBotData.getTradeNativeAddress();
List<MessageTransactionData> messageTransactionsData = repository.getMessageRepository().getMessagesByParticipants(null, address, null, null, null);
for (MessageTransactionData messageTransactionData : messageTransactionsData) {
if (messageTransactionData.isText())
continue;
// We're expecting: HASH160(secret-A), Alice's Ravencoin pubkeyhash and lockTime-A
byte[] messageData = messageTransactionData.getData();
RavencoinACCTv3.OfferMessageData offerMessageData = RavencoinACCTv3.extractOfferMessageData(messageData);
if (offerMessageData == null)
continue;
byte[] aliceForeignPublicKeyHash = offerMessageData.partnerRavencoinPKH;
byte[] hashOfSecretA = offerMessageData.hashOfSecretA;
int lockTimeA = (int) offerMessageData.lockTimeA;
long messageTimestamp = messageTransactionData.getTimestamp();
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(messageTimestamp, lockTimeA);
// Determine P2SH-A address and confirm funded
byte[] redeemScriptA = BitcoinyHTLC.buildScript(aliceForeignPublicKeyHash, lockTimeA, tradeBotData.getTradeForeignPublicKeyHash(), hashOfSecretA);
String p2shAddressA = ravencoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Ravencoin.getInstance().getP2shFee(feeTimestamp);
final long minimumAmountA = tradeBotData.getForeignAmount() + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(ravencoin.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
// There might be another MESSAGE from someone else with an actually funded P2SH-A...
continue;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// We've already redeemed this?
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_DONE,
() -> String.format("P2SH-A %s already spent? Assuming trade complete", p2shAddressA));
return;
case REFUND_IN_PROGRESS:
case REFUNDED:
// This P2SH-A is burnt, but there might be another MESSAGE from someone else with an actually funded P2SH-A...
continue;
case FUNDED:
// Fall-through out of switch...
break;
}
// Good to go - send MESSAGE to AT
String aliceNativeAddress = Crypto.toAddress(messageTransactionData.getCreatorPublicKey());
// Build outgoing message, padding each part to 32 bytes to make it easier for AT to consume
byte[] outgoingMessageData = RavencoinACCTv3.buildTradeMessage(aliceNativeAddress, aliceForeignPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
String messageRecipient = tradeBotData.getAtAddress();
boolean isMessageAlreadySent = repository.getMessageRepository().exists(tradeBotData.getTradeNativePublicKey(), messageRecipient, outgoingMessageData);
if (!isMessageAlreadySent) {
PrivateKeyAccount sender = new PrivateKeyAccount(repository, tradeBotData.getTradePrivateKey());
MessageTransaction outgoingMessageTransaction = MessageTransaction.build(repository, sender, Group.NO_GROUP, messageRecipient, outgoingMessageData, false, false);
outgoingMessageTransaction.computeNonce();
outgoingMessageTransaction.sign(sender);
// reset repository state to prevent deadlock
repository.discardChanges();
ValidationResult result = outgoingMessageTransaction.importAsUnconfirmed();
if (result != ValidationResult.OK) {
LOGGER.warn(() -> String.format("Unable to send MESSAGE to AT %s: %s", messageRecipient, result.name()));
return;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_WAITING_FOR_AT_REDEEM,
() -> String.format("Locked AT %s to %s. Waiting for AT redeem", tradeBotData.getAtAddress(), aliceNativeAddress));
return;
}
}
/**
* Trade-bot is waiting for Bob's AT to switch to TRADE mode and lock trade to Alice only.
* <p>
* It's possible that Bob has cancelled his trade offer in the mean time, or that somehow
* this process has taken so long that we've reached P2SH-A's locktime, or that someone else
* has managed to trade with Bob. In any of these cases, trade-bot switches to begin the refunding process.
* <p>
* Assuming Bob's AT is locked to Alice, trade-bot checks AT's state data to make sure it is correct.
* <p>
* If all is well, trade-bot then redeems AT using Alice's secret-A, releasing Bob's QORT to Alice.
* <p>
* In revealing a valid secret-A, Bob can then redeem the RVN funds from P2SH-A.
* <p>
* @throws ForeignBlockchainException
*/
private void handleAliceWaitingForAtLock(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
if (aliceUnexpectedState(repository, tradeBotData, atData, crossChainTradeData))
return;
Ravencoin ravencoin = Ravencoin.getInstance();
int lockTimeA = tradeBotData.getLockTimeA();
// Refund P2SH-A if we've passed lockTime-A
if (NTP.getTime() >= lockTimeA * 1000L) {
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = ravencoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Ravencoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(ravencoin.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
case FUNDED:
break;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// Already redeemed?
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("P2SH-A %s already spent? Assuming trade completed", p2shAddressA));
return;
case REFUND_IN_PROGRESS:
case REFUNDED:
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDED,
() -> String.format("P2SH-A %s already refunded. Trade aborted", p2shAddressA));
return;
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDING_A,
() -> atData.getIsFinished()
? String.format("AT %s cancelled. Refunding P2SH-A %s - aborting trade", tradeBotData.getAtAddress(), p2shAddressA)
: String.format("LockTime-A reached, refunding P2SH-A %s - aborting trade", p2shAddressA));
return;
}
// We're waiting for AT to be in TRADE mode
if (crossChainTradeData.mode != AcctMode.TRADING)
return;
// AT is in TRADE mode and locked to us as checked by aliceUnexpectedState() above
// Find our MESSAGE to AT from previous state
List<MessageTransactionData> messageTransactionsData = repository.getMessageRepository().getMessagesByParticipants(tradeBotData.getTradeNativePublicKey(),
crossChainTradeData.qortalCreatorTradeAddress, null, null, null);
if (messageTransactionsData == null || messageTransactionsData.isEmpty()) {
LOGGER.warn(() -> String.format("Unable to find our message to trade creator %s?", crossChainTradeData.qortalCreatorTradeAddress));
return;
}
long recipientMessageTimestamp = messageTransactionsData.get(0).getTimestamp();
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(recipientMessageTimestamp, lockTimeA);
// Our calculated refundTimeout should match AT's refundTimeout
if (refundTimeout != crossChainTradeData.refundTimeout) {
LOGGER.debug(() -> String.format("Trade AT refundTimeout '%d' doesn't match our refundTimeout '%d'", crossChainTradeData.refundTimeout, refundTimeout));
// We'll eventually refund
return;
}
// We're good to redeem AT
// Send 'redeem' MESSAGE to AT using both secret
byte[] secretA = tradeBotData.getSecret();
String qortalReceivingAddress = Base58.encode(tradeBotData.getReceivingAccountInfo()); // Actually contains whole address, not just PKH
byte[] messageData = RavencoinACCTv3.buildRedeemMessage(secretA, qortalReceivingAddress);
String messageRecipient = tradeBotData.getAtAddress();
boolean isMessageAlreadySent = repository.getMessageRepository().exists(tradeBotData.getTradeNativePublicKey(), messageRecipient, messageData);
if (!isMessageAlreadySent) {
PrivateKeyAccount sender = new PrivateKeyAccount(repository, tradeBotData.getTradePrivateKey());
MessageTransaction messageTransaction = MessageTransaction.build(repository, sender, Group.NO_GROUP, messageRecipient, messageData, false, false);
messageTransaction.computeNonce();
messageTransaction.sign(sender);
// Reset repository state to prevent deadlock
repository.discardChanges();
ValidationResult result = messageTransaction.importAsUnconfirmed();
if (result != ValidationResult.OK) {
LOGGER.warn(() -> String.format("Unable to send MESSAGE to AT %s: %s", messageRecipient, result.name()));
return;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("Redeeming AT %s. Funds should arrive at %s",
tradeBotData.getAtAddress(), qortalReceivingAddress));
}
/**
* Trade-bot is waiting for Alice to redeem Bob's AT, thus revealing secret-A which is required to spend the RVN funds from P2SH-A.
* <p>
* It's possible that Bob's AT has reached its trading timeout and automatically refunded QORT back to Bob. In which case,
* trade-bot is done with this specific trade and finalizes in refunded state.
* <p>
* Assuming trade-bot can extract a valid secret-A from Alice's MESSAGE then trade-bot uses that to redeem the RVN funds from P2SH-A
* to Bob's 'foreign'/Ravencoin trade legacy-format address, as derived from trade private key.
* <p>
* (This could potentially be 'improved' to send RVN to any address of Bob's choosing by changing the transaction output).
* <p>
* If trade-bot successfully broadcasts the transaction, then this specific trade is done.
* @throws ForeignBlockchainException
*/
private void handleBobWaitingForAtRedeem(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
// AT should be 'finished' once Alice has redeemed QORT funds
if (!atData.getIsFinished())
// Not finished yet
return;
// If AT is REFUNDED or CANCELLED then something has gone wrong
if (crossChainTradeData.mode == AcctMode.REFUNDED || crossChainTradeData.mode == AcctMode.CANCELLED) {
// Alice hasn't redeemed the QORT, so there is no point in trying to redeem the RVN
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s has auto-refunded - trade aborted", tradeBotData.getAtAddress()));
return;
}
byte[] secretA = RavencoinACCTv3.getInstance().findSecretA(repository, crossChainTradeData);
if (secretA == null) {
LOGGER.debug(() -> String.format("Unable to find secret-A from redeem message to AT %s?", tradeBotData.getAtAddress()));
return;
}
// Use secret-A to redeem P2SH-A
Ravencoin ravencoin = Ravencoin.getInstance();
byte[] receivingAccountInfo = tradeBotData.getReceivingAccountInfo();
int lockTimeA = crossChainTradeData.lockTimeA;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(crossChainTradeData.partnerForeignPKH, lockTimeA, crossChainTradeData.creatorForeignPKH, crossChainTradeData.hashOfSecretA);
String p2shAddressA = ravencoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Ravencoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(ravencoin.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
// P2SH-A suddenly not funded? Our best bet at this point is to hope for AT auto-refund
return;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// Double-check that we have redeemed P2SH-A...
break;
case REFUND_IN_PROGRESS:
case REFUNDED:
// Wait for AT to auto-refund
return;
case FUNDED: {
Coin redeemAmount = Coin.valueOf(crossChainTradeData.expectedForeignAmount);
ECKey redeemKey = ECKey.fromPrivate(tradeBotData.getTradePrivateKey());
List<TransactionOutput> fundingOutputs = ravencoin.getUnspentOutputs(p2shAddressA);
Transaction p2shRedeemTransaction = BitcoinyHTLC.buildRedeemTransaction(ravencoin.getNetworkParameters(), redeemAmount, redeemKey,
fundingOutputs, redeemScriptA, secretA, receivingAccountInfo);
ravencoin.broadcastTransaction(p2shRedeemTransaction);
break;
}
}
String receivingAddress = ravencoin.pkhToAddress(receivingAccountInfo);
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_DONE,
() -> String.format("P2SH-A %s redeemed. Funds should arrive at %s", tradeBotData.getAtAddress(), receivingAddress));
}
/**
* Trade-bot is attempting to refund P2SH-A.
* @throws ForeignBlockchainException
*/
private void handleAliceRefundingP2shA(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
int lockTimeA = tradeBotData.getLockTimeA();
// We can't refund P2SH-A until lockTime-A has passed
if (NTP.getTime() <= lockTimeA * 1000L)
return;
Ravencoin ravencoin = Ravencoin.getInstance();
// We can't refund P2SH-A until median block time has passed lockTime-A (see BIP113)
int medianBlockTime = ravencoin.getMedianBlockTime();
if (medianBlockTime <= lockTimeA)
return;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = ravencoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Ravencoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(ravencoin.getBlockchainProvider(), p2shAddressA, minimumAmountA);
switch (htlcStatusA) {
case UNFUNDED:
case FUNDING_IN_PROGRESS:
// Still waiting for P2SH-A to be funded...
return;
case REDEEM_IN_PROGRESS:
case REDEEMED:
// Too late!
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("P2SH-A %s already spent!", p2shAddressA));
return;
case REFUND_IN_PROGRESS:
case REFUNDED:
break;
case FUNDED:{
Coin refundAmount = Coin.valueOf(crossChainTradeData.expectedForeignAmount);
ECKey refundKey = ECKey.fromPrivate(tradeBotData.getTradePrivateKey());
List<TransactionOutput> fundingOutputs = ravencoin.getUnspentOutputs(p2shAddressA);
// Determine receive address for refund
String receiveAddress = ravencoin.getUnusedReceiveAddress(tradeBotData.getForeignKey());
Address receiving = Address.fromString(ravencoin.getNetworkParameters(), receiveAddress);
Transaction p2shRefundTransaction = BitcoinyHTLC.buildRefundTransaction(ravencoin.getNetworkParameters(), refundAmount, refundKey,
fundingOutputs, redeemScriptA, lockTimeA, receiving.getHash());
ravencoin.broadcastTransaction(p2shRefundTransaction);
break;
}
}
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDED,
() -> String.format("LockTime-A reached. Refunded P2SH-A %s. Trade aborted", p2shAddressA));
}
/**
* Returns true if Alice finds AT unexpectedly cancelled, refunded, redeemed or locked to someone else.
* <p>
* Will automatically update trade-bot state to <tt>ALICE_REFUNDING_A</tt> or <tt>ALICE_DONE</tt> as necessary.
*
* @throws DataException
* @throws ForeignBlockchainException
*/
private boolean aliceUnexpectedState(Repository repository, TradeBotData tradeBotData,
ATData atData, CrossChainTradeData crossChainTradeData) throws DataException, ForeignBlockchainException {
// This is OK
if (!atData.getIsFinished() && crossChainTradeData.mode == AcctMode.OFFERING)
return false;
boolean isAtLockedToUs = tradeBotData.getTradeNativeAddress().equals(crossChainTradeData.qortalPartnerAddress);
if (!atData.getIsFinished() && crossChainTradeData.mode == AcctMode.TRADING)
if (isAtLockedToUs) {
// AT is trading with us - OK
return false;
} else {
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDING_A,
() -> String.format("AT %s trading with someone else: %s. Refunding & aborting trade", tradeBotData.getAtAddress(), crossChainTradeData.qortalPartnerAddress));
return true;
}
if (atData.getIsFinished() && crossChainTradeData.mode == AcctMode.REDEEMED && isAtLockedToUs) {
// We've redeemed already?
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_DONE,
() -> String.format("AT %s already redeemed by us. Trade completed", tradeBotData.getAtAddress()));
} else {
// Any other state is not good, so start defensive refund
TradeBot.updateTradeBotState(repository, tradeBotData, State.ALICE_REFUNDING_A,
() -> String.format("AT %s cancelled/refunded/redeemed by someone else/invalid state. Refunding & aborting trade", tradeBotData.getAtAddress()));
}
return true;
}
private long calcFeeTimestamp(int lockTimeA, int tradeTimeout) {
return (lockTimeA - tradeTimeout * 60) * 1000L;
}
}

2
src/main/java/org/qortal/controller/tradebot/TradeBot.java
View File

@ -100,6 +100,8 @@ public class TradeBot implements Listener {
acctTradeBotSuppliers.put(DogecoinACCTv1.class, DogecoinACCTv1TradeBot::getInstance); acctTradeBotSuppliers.put(DogecoinACCTv1.class, DogecoinACCTv1TradeBot::getInstance);
acctTradeBotSuppliers.put(DogecoinACCTv2.class, DogecoinACCTv2TradeBot::getInstance); acctTradeBotSuppliers.put(DogecoinACCTv2.class, DogecoinACCTv2TradeBot::getInstance);
acctTradeBotSuppliers.put(DogecoinACCTv3.class, DogecoinACCTv3TradeBot::getInstance); acctTradeBotSuppliers.put(DogecoinACCTv3.class, DogecoinACCTv3TradeBot::getInstance);
acctTradeBotSuppliers.put(DigibyteACCTv3.class, DigibyteACCTv3TradeBot::getInstance);
acctTradeBotSuppliers.put(RavencoinACCTv3.class, RavencoinACCTv3TradeBot::getInstance);
} }
private static TradeBot instance; private static TradeBot instance;

171
src/main/java/org/qortal/crosschain/Digibyte.java Normal file
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@ -0,0 +1,171 @@
package org.qortal.crosschain;
import java.util.Arrays;
import java.util.Collection;
import java.util.EnumMap;
import java.util.Map;
import org.bitcoinj.core.Coin;
import org.bitcoinj.core.Context;
import org.bitcoinj.core.NetworkParameters;
import org.bitcoinj.params.RegTestParams;
import org.bitcoinj.params.TestNet3Params;
import org.libdohj.params.DigibyteMainNetParams;
import org.qortal.crosschain.ElectrumX.Server;
import org.qortal.crosschain.ElectrumX.Server.ConnectionType;
import org.qortal.settings.Settings;
public class Digibyte extends Bitcoiny {
public static final String CURRENCY_CODE = "DGB";
private static final Coin DEFAULT_FEE_PER_KB = Coin.valueOf(100000); // 0.001 DGB per 1000 bytes
private static final long MINIMUM_ORDER_AMOUNT = 1000000; // 0.01 DGB minimum order, to avoid dust errors
// Temporary values until a dynamic fee system is written.
private static final long MAINNET_FEE = 10000L;
private static final long NON_MAINNET_FEE = 10000L; // enough for TESTNET3 and should be OK for REGTEST
private static final Map<ConnectionType, Integer> DEFAULT_ELECTRUMX_PORTS = new EnumMap<>(ConnectionType.class);
static {
DEFAULT_ELECTRUMX_PORTS.put(ConnectionType.TCP, 50001);
DEFAULT_ELECTRUMX_PORTS.put(ConnectionType.SSL, 50002);
}
public enum DigibyteNet {
MAIN {
@Override
public NetworkParameters getParams() {
return DigibyteMainNetParams.get();
}
@Override
public Collection<Server> getServers() {
return Arrays.asList(
// Servers chosen on NO BASIS WHATSOEVER from various sources!
// Status verified at https://1209k.com/bitcoin-eye/ele.php?chain=dgb
new Server("electrum1.cipig.net", ConnectionType.SSL, 20059),
new Server("electrum2.cipig.net", ConnectionType.SSL, 20059),
new Server("electrum3.cipig.net", ConnectionType.SSL, 20059));
}
@Override
public String getGenesisHash() {
return "7497ea1b465eb39f1c8f507bc877078fe016d6fcb6dfad3a64c98dcc6e1e8496";
}
@Override
public long getP2shFee(Long timestamp) {
// TODO: This will need to be replaced with something better in the near future!
return MAINNET_FEE;
}
},
TEST3 {
@Override
public NetworkParameters getParams() {
return TestNet3Params.get();
}
@Override
public Collection<Server> getServers() {
return Arrays.asList(); // TODO: find testnet servers
}
@Override
public String getGenesisHash() {
return "308ea0711d5763be2995670dd9ca9872753561285a84da1d58be58acaa822252";
}
@Override
public long getP2shFee(Long timestamp) {
return NON_MAINNET_FEE;
}
},
REGTEST {
@Override
public NetworkParameters getParams() {
return RegTestParams.get();
}
@Override
public Collection<Server> getServers() {
return Arrays.asList(
new Server("localhost", ConnectionType.TCP, 50001),
new Server("localhost", ConnectionType.SSL, 50002));
}
@Override
public String getGenesisHash() {
// This is unique to each regtest instance
return null;
}
@Override
public long getP2shFee(Long timestamp) {
return NON_MAINNET_FEE;
}
};
public abstract NetworkParameters getParams();
public abstract Collection<Server> getServers();
public abstract String getGenesisHash();
public abstract long getP2shFee(Long timestamp) throws ForeignBlockchainException;
}
private static Digibyte instance;
private final DigibyteNet digibyteNet;
// Constructors and instance
private Digibyte(DigibyteNet digibyteNet, BitcoinyBlockchainProvider blockchain, Context bitcoinjContext, String currencyCode) {
super(blockchain, bitcoinjContext, currencyCode);
this.digibyteNet = digibyteNet;
LOGGER.info(() -> String.format("Starting Digibyte support using %s", this.digibyteNet.name()));
}
public static synchronized Digibyte getInstance() {
if (instance == null) {
DigibyteNet digibyteNet = Settings.getInstance().getDigibyteNet();
BitcoinyBlockchainProvider electrumX = new ElectrumX("Digibyte-" + digibyteNet.name(), digibyteNet.getGenesisHash(), digibyteNet.getServers(), DEFAULT_ELECTRUMX_PORTS);
Context bitcoinjContext = new Context(digibyteNet.getParams());
instance = new Digibyte(digibyteNet, electrumX, bitcoinjContext, CURRENCY_CODE);
}
return instance;
}
// Getters & setters
public static synchronized void resetForTesting() {
instance = null;
}
// Actual useful methods for use by other classes
@Override
public Coin getFeePerKb() {
return DEFAULT_FEE_PER_KB;
}
@Override
public long getMinimumOrderAmount() {
return MINIMUM_ORDER_AMOUNT;
}
/**
* Returns estimated DGB fee, in sats per 1000bytes, optionally for historic timestamp.
*
* @param timestamp optional milliseconds since epoch, or null for 'now'
* @return sats per 1000bytes, or throws ForeignBlockchainException if something went wrong
*/
@Override
public long getP2shFee(Long timestamp) throws ForeignBlockchainException {
return this.digibyteNet.getP2shFee(timestamp);
}
}

858
src/main/java/org/qortal/crosschain/DigibyteACCTv3.java Normal file
View File

@ -0,0 +1,858 @@
package org.qortal.crosschain;
import com.google.common.hash.HashCode;
import com.google.common.primitives.Bytes;
import org.apache.logging.log4j.LogManager;
import org.apache.logging.log4j.Logger;
import org.ciyam.at.*;
import org.qortal.account.Account;
import org.qortal.asset.Asset;
import org.qortal.at.QortalFunctionCode;
import org.qortal.crypto.Crypto;
import org.qortal.data.at.ATData;
import org.qortal.data.at.ATStateData;
import org.qortal.data.crosschain.CrossChainTradeData;
import org.qortal.data.transaction.MessageTransactionData;
import org.qortal.repository.DataException;
import org.qortal.repository.Repository;
import org.qortal.utils.Base58;
import org.qortal.utils.BitTwiddling;
import java.nio.ByteBuffer;
import java.util.Arrays;
import java.util.List;
import static org.ciyam.at.OpCode.calcOffset;
/**
* Cross-chain trade AT
*
* <p>
* <ul>
* <li>Bob generates Digibyte & Qortal 'trade' keys
* <ul>
* <li>private key required to sign P2SH redeem tx</li>
* <li>private key could be used to create 'secret' (e.g. double-SHA256)</li>
* <li>encrypted private key could be stored in Qortal AT for access by Bob from any node</li>
* </ul>
* </li>
* <li>Bob deploys Qortal AT
* <ul>
* </ul>
* </li>
* <li>Alice finds Qortal AT and wants to trade
* <ul>
* <li>Alice generates Digibyte & Qortal 'trade' keys</li>
* <li>Alice funds Digibyte P2SH-A</li>
* <li>Alice sends 'offer' MESSAGE to Bob from her Qortal trade address, containing:
* <ul>
* <li>hash-of-secret-A</li>
* <li>her 'trade' Digibyte PKH</li>
* </ul>
* </li>
* </ul>
* </li>
* <li>Bob receives "offer" MESSAGE
* <ul>
* <li>Checks Alice's P2SH-A</li>
* <li>Sends 'trade' MESSAGE to Qortal AT from his trade address, containing:
* <ul>
* <li>Alice's trade Qortal address</li>
* <li>Alice's trade Digibyte PKH</li>
* <li>hash-of-secret-A</li>
* </ul>
* </li>
* </ul>
* </li>
* <li>Alice checks Qortal AT to confirm it's locked to her
* <ul>
* <li>Alice sends 'redeem' MESSAGE to Qortal AT from her trade address, containing:
* <ul>
* <li>secret-A</li>
* <li>Qortal receiving address of her chosing</li>
* </ul>
* </li>
* <li>AT's QORT funds are sent to Qortal receiving address</li>
* </ul>
* </li>
* <li>Bob checks AT, extracts secret-A
* <ul>
* <li>Bob redeems P2SH-A using his Digibyte trade key and secret-A</li>
* <li>P2SH-A DGB funds end up at Digibyte address determined by redeem transaction output(s)</li>
* </ul>
* </li>
* </ul>
*/
public class DigibyteACCTv3 implements ACCT {
private static final Logger LOGGER = LogManager.getLogger(DigibyteACCTv3.class);
public static final String NAME = DigibyteACCTv3.class.getSimpleName();
public static final byte[] CODE_BYTES_HASH = HashCode.fromString("e6a7dcd87296fae3ce7d80183bf7660c8e2cb4f8746c6a0421a17148f87a0e1d").asBytes(); // SHA256 of AT code bytes
public static final int SECRET_LENGTH = 32;
/** <b>Value</b> offset into AT segment where 'mode' variable (long) is stored. (Multiply by MachineState.VALUE_SIZE for byte offset). */
private static final int MODE_VALUE_OFFSET = 61;
/** <b>Byte</b> offset into AT state data where 'mode' variable (long) is stored. */
public static final int MODE_BYTE_OFFSET = MachineState.HEADER_LENGTH + (MODE_VALUE_OFFSET * MachineState.VALUE_SIZE);
public static class OfferMessageData {
public byte[] partnerDigibytePKH;
public byte[] hashOfSecretA;
public long lockTimeA;
}
public static final int OFFER_MESSAGE_LENGTH = 20 /*partnerDigibytePKH*/ + 20 /*hashOfSecretA*/ + 8 /*lockTimeA*/;
public static final int TRADE_MESSAGE_LENGTH = 32 /*partner's Qortal trade address (padded from 25 to 32)*/
+ 24 /*partner's Digibyte PKH (padded from 20 to 24)*/
+ 8 /*AT trade timeout (minutes)*/
+ 24 /*hash of secret-A (padded from 20 to 24)*/
+ 8 /*lockTimeA*/;
public static final int REDEEM_MESSAGE_LENGTH = 32 /*secret-A*/ + 32 /*partner's Qortal receiving address padded from 25 to 32*/;
public static final int CANCEL_MESSAGE_LENGTH = 32 /*AT creator's Qortal address*/;
private static DigibyteACCTv3 instance;
private DigibyteACCTv3() {
}
public static synchronized DigibyteACCTv3 getInstance() {
if (instance == null)
instance = new DigibyteACCTv3();
return instance;
}
@Override
public byte[] getCodeBytesHash() {
return CODE_BYTES_HASH;
}
@Override
public int getModeByteOffset() {
return MODE_BYTE_OFFSET;
}
@Override
public ForeignBlockchain getBlockchain() {
return Digibyte.getInstance();
}
/**
* Returns Qortal AT creation bytes for cross-chain trading AT.
* <p>
* <tt>tradeTimeout</tt> (minutes) is the time window for the trade partner to send the
* 32-byte secret to the AT, before the AT automatically refunds the AT's creator.
*
* @param creatorTradeAddress AT creator's trade Qortal address
* @param digibytePublicKeyHash 20-byte HASH160 of creator's trade Digibyte public key
* @param qortAmount how much QORT to pay trade partner if they send correct 32-byte secrets to AT
* @param digibyteAmount how much DGB the AT creator is expecting to trade
* @param tradeTimeout suggested timeout for entire trade
*/
public static byte[] buildQortalAT(String creatorTradeAddress, byte[] digibytePublicKeyHash, long qortAmount, long digibyteAmount, int tradeTimeout) {
if (digibytePublicKeyHash.length != 20)
throw new IllegalArgumentException("Digibyte public key hash should be 20 bytes");
// Labels for data segment addresses
int addrCounter = 0;
// Constants (with corresponding dataByteBuffer.put*() calls below)
final int addrCreatorTradeAddress1 = addrCounter++;
final int addrCreatorTradeAddress2 = addrCounter++;
final int addrCreatorTradeAddress3 = addrCounter++;
final int addrCreatorTradeAddress4 = addrCounter++;
final int addrDigibytePublicKeyHash = addrCounter;
addrCounter += 4;
final int addrQortAmount = addrCounter++;
final int addrDigibyteAmount = addrCounter++;
final int addrTradeTimeout = addrCounter++;
final int addrMessageTxnType = addrCounter++;
final int addrExpectedTradeMessageLength = addrCounter++;
final int addrExpectedRedeemMessageLength = addrCounter++;
final int addrCreatorAddressPointer = addrCounter++;
final int addrQortalPartnerAddressPointer = addrCounter++;
final int addrMessageSenderPointer = addrCounter++;
final int addrTradeMessagePartnerDigibytePKHOffset = addrCounter++;
final int addrPartnerDigibytePKHPointer = addrCounter++;
final int addrTradeMessageHashOfSecretAOffset = addrCounter++;
final int addrHashOfSecretAPointer = addrCounter++;
final int addrRedeemMessageReceivingAddressOffset = addrCounter++;
final int addrMessageDataPointer = addrCounter++;
final int addrMessageDataLength = addrCounter++;
final int addrPartnerReceivingAddressPointer = addrCounter++;
final int addrEndOfConstants = addrCounter;
// Variables
final int addrCreatorAddress1 = addrCounter++;
final int addrCreatorAddress2 = addrCounter++;
final int addrCreatorAddress3 = addrCounter++;
final int addrCreatorAddress4 = addrCounter++;
final int addrQortalPartnerAddress1 = addrCounter++;
final int addrQortalPartnerAddress2 = addrCounter++;
final int addrQortalPartnerAddress3 = addrCounter++;
final int addrQortalPartnerAddress4 = addrCounter++;
final int addrLockTimeA = addrCounter++;
final int addrRefundTimeout = addrCounter++;
final int addrRefundTimestamp = addrCounter++;
final int addrLastTxnTimestamp = addrCounter++;
final int addrBlockTimestamp = addrCounter++;
final int addrTxnType = addrCounter++;
final int addrResult = addrCounter++;
final int addrMessageSender1 = addrCounter++;
final int addrMessageSender2 = addrCounter++;
final int addrMessageSender3 = addrCounter++;
final int addrMessageSender4 = addrCounter++;
final int addrMessageLength = addrCounter++;
final int addrMessageData = addrCounter;
addrCounter += 4;
final int addrHashOfSecretA = addrCounter;
addrCounter += 4;
final int addrPartnerDigibytePKH = addrCounter;
addrCounter += 4;
final int addrPartnerReceivingAddress = addrCounter;
addrCounter += 4;
final int addrMode = addrCounter++;
assert addrMode == MODE_VALUE_OFFSET : String.format("addrMode %d does not match MODE_VALUE_OFFSET %d", addrMode, MODE_VALUE_OFFSET);
// Data segment
ByteBuffer dataByteBuffer = ByteBuffer.allocate(addrCounter * MachineState.VALUE_SIZE);
// AT creator's trade Qortal address, decoded from Base58
assert dataByteBuffer.position() == addrCreatorTradeAddress1 * MachineState.VALUE_SIZE : "addrCreatorTradeAddress1 incorrect";
byte[] creatorTradeAddressBytes = Base58.decode(creatorTradeAddress);
dataByteBuffer.put(Bytes.ensureCapacity(creatorTradeAddressBytes, 32, 0));
// Digibyte public key hash
assert dataByteBuffer.position() == addrDigibytePublicKeyHash * MachineState.VALUE_SIZE : "addrDigibytePublicKeyHash incorrect";
dataByteBuffer.put(Bytes.ensureCapacity(digibytePublicKeyHash, 32, 0));
// Redeem Qort amount
assert dataByteBuffer.position() == addrQortAmount * MachineState.VALUE_SIZE : "addrQortAmount incorrect";
dataByteBuffer.putLong(qortAmount);
// Expected Digibyte amount
assert dataByteBuffer.position() == addrDigibyteAmount * MachineState.VALUE_SIZE : "addrDigibyteAmount incorrect";
dataByteBuffer.putLong(digibyteAmount);
// Suggested trade timeout (minutes)
assert dataByteBuffer.position() == addrTradeTimeout * MachineState.VALUE_SIZE : "addrTradeTimeout incorrect";
dataByteBuffer.putLong(tradeTimeout);
// We're only interested in MESSAGE transactions
assert dataByteBuffer.position() == addrMessageTxnType * MachineState.VALUE_SIZE : "addrMessageTxnType incorrect";
dataByteBuffer.putLong(API.ATTransactionType.MESSAGE.value);
// Expected length of 'trade' MESSAGE data from AT creator
assert dataByteBuffer.position() == addrExpectedTradeMessageLength * MachineState.VALUE_SIZE : "addrExpectedTradeMessageLength incorrect";
dataByteBuffer.putLong(TRADE_MESSAGE_LENGTH);
// Expected length of 'redeem' MESSAGE data from trade partner
assert dataByteBuffer.position() == addrExpectedRedeemMessageLength * MachineState.VALUE_SIZE : "addrExpectedRedeemMessageLength incorrect";
dataByteBuffer.putLong(REDEEM_MESSAGE_LENGTH);
// Index into data segment of AT creator's address, used by GET_B_IND
assert dataByteBuffer.position() == addrCreatorAddressPointer * MachineState.VALUE_SIZE : "addrCreatorAddressPointer incorrect";
dataByteBuffer.putLong(addrCreatorAddress1);
// Index into data segment of partner's Qortal address, used by SET_B_IND
assert dataByteBuffer.position() == addrQortalPartnerAddressPointer * MachineState.VALUE_SIZE : "addrQortalPartnerAddressPointer incorrect";
dataByteBuffer.putLong(addrQortalPartnerAddress1);
// Index into data segment of (temporary) transaction's sender's address, used by GET_B_IND
assert dataByteBuffer.position() == addrMessageSenderPointer * MachineState.VALUE_SIZE : "addrMessageSenderPointer incorrect";
dataByteBuffer.putLong(addrMessageSender1);
// Offset into 'trade' MESSAGE data payload for extracting partner's Digibyte PKH
assert dataByteBuffer.position() == addrTradeMessagePartnerDigibytePKHOffset * MachineState.VALUE_SIZE : "addrTradeMessagePartnerDigibytePKHOffset incorrect";
dataByteBuffer.putLong(32L);
// Index into data segment of partner's Digibyte PKH, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerDigibytePKHPointer * MachineState.VALUE_SIZE : "addrPartnerDigibytePKHPointer incorrect";
dataByteBuffer.putLong(addrPartnerDigibytePKH);
// Offset into 'trade' MESSAGE data payload for extracting hash-of-secret-A
assert dataByteBuffer.position() == addrTradeMessageHashOfSecretAOffset * MachineState.VALUE_SIZE : "addrTradeMessageHashOfSecretAOffset incorrect";
dataByteBuffer.putLong(64L);
// Index into data segment to hash of secret A, used by GET_B_IND
assert dataByteBuffer.position() == addrHashOfSecretAPointer * MachineState.VALUE_SIZE : "addrHashOfSecretAPointer incorrect";
dataByteBuffer.putLong(addrHashOfSecretA);
// Offset into 'redeem' MESSAGE data payload for extracting Qortal receiving address
assert dataByteBuffer.position() == addrRedeemMessageReceivingAddressOffset * MachineState.VALUE_SIZE : "addrRedeemMessageReceivingAddressOffset incorrect";
dataByteBuffer.putLong(32L);
// Source location and length for hashing any passed secret
assert dataByteBuffer.position() == addrMessageDataPointer * MachineState.VALUE_SIZE : "addrMessageDataPointer incorrect";
dataByteBuffer.putLong(addrMessageData);
assert dataByteBuffer.position() == addrMessageDataLength * MachineState.VALUE_SIZE : "addrMessageDataLength incorrect";
dataByteBuffer.putLong(32L);
// Pointer into data segment of where to save partner's receiving Qortal address, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerReceivingAddressPointer * MachineState.VALUE_SIZE : "addrPartnerReceivingAddressPointer incorrect";
dataByteBuffer.putLong(addrPartnerReceivingAddress);
assert dataByteBuffer.position() == addrEndOfConstants * MachineState.VALUE_SIZE : "dataByteBuffer position not at end of constants";
// Code labels
Integer labelRefund = null;
Integer labelTradeTxnLoop = null;
Integer labelCheckTradeTxn = null;
Integer labelCheckCancelTxn = null;
Integer labelNotTradeNorCancelTxn = null;
Integer labelCheckNonRefundTradeTxn = null;
Integer labelTradeTxnExtract = null;
Integer labelRedeemTxnLoop = null;
Integer labelCheckRedeemTxn = null;
Integer labelCheckRedeemTxnSender = null;
Integer labelPayout = null;
ByteBuffer codeByteBuffer = ByteBuffer.allocate(768);
// Two-pass version
for (int pass = 0; pass < 2; ++pass) {
codeByteBuffer.clear();
try {
/* Initialization */
// Use AT creation 'timestamp' as starting point for finding transactions sent to AT
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_CREATION_TIMESTAMP, addrLastTxnTimestamp));
/* NOP - to ensure DIGIBYTE ACCT is unique */
codeByteBuffer.put(OpCode.NOP.compile());
// Load B register with AT creator's address so we can save it into addrCreatorAddress1-4
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_CREATOR_INTO_B));
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrCreatorAddressPointer));
// Set restart position to after this opcode
codeByteBuffer.put(OpCode.SET_PCS.compile());
/* Loop, waiting for message from AT creator's trade address containing trade partner details, or AT owner's address to cancel offer */
/* Transaction processing loop */
labelTradeTxnLoop = codeByteBuffer.position();
/* Sleep until message arrives */
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.SLEEP_UNTIL_MESSAGE.value, addrLastTxnTimestamp));
// Find next transaction (if any) to this AT since the last one (referenced by addrLastTxnTimestamp)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.PUT_TX_AFTER_TIMESTAMP_INTO_A, addrLastTxnTimestamp));
// If no transaction found, A will be zero. If A is zero, set addrResult to 1, otherwise 0.
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.CHECK_A_IS_ZERO, addrResult));
// If addrResult is zero (i.e. A is non-zero, transaction was found) then go check transaction
codeByteBuffer.put(OpCode.BZR_DAT.compile(addrResult, calcOffset(codeByteBuffer, labelCheckTradeTxn)));
// Stop and wait for next block
codeByteBuffer.put(OpCode.STP_IMD.compile());
/* Check transaction */
labelCheckTradeTxn = codeByteBuffer.position();
// Update our 'last found transaction's timestamp' using 'timestamp' from transaction
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TIMESTAMP_FROM_TX_IN_A, addrLastTxnTimestamp));
// Extract transaction type (message/payment) from transaction and save type in addrTxnType
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TYPE_FROM_TX_IN_A, addrTxnType));
// If transaction type is not MESSAGE type then go look for another transaction
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrTxnType, addrMessageTxnType, calcOffset(codeByteBuffer, labelTradeTxnLoop)));
/* Check transaction's sender. We're expecting AT creator's trade address for 'trade' message, or AT creator's own address for 'cancel' message. */
// Extract sender address from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_ADDRESS_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrMessageSender1 (as pointed to by addrMessageSenderPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrMessageSenderPointer));
// Compare each part of message sender's address with AT creator's trade address. If they don't match, check for cancel situation.
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender1, addrCreatorTradeAddress1, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender2, addrCreatorTradeAddress2, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender3, addrCreatorTradeAddress3, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender4, addrCreatorTradeAddress4, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
// Message sender's address matches AT creator's trade address so go process 'trade' message
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelCheckNonRefundTradeTxn == null ? 0 : labelCheckNonRefundTradeTxn));
/* Checking message sender for possible cancel message */
labelCheckCancelTxn = codeByteBuffer.position();
// Compare each part of message sender's address with AT creator's address. If they don't match, look for another transaction.
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender1, addrCreatorAddress1, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender2, addrCreatorAddress2, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender3, addrCreatorAddress3, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender4, addrCreatorAddress4, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
// Partner address is AT creator's address, so cancel offer and finish.
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.CANCELLED.value));
// We're finished forever (finishing auto-refunds remaining balance to AT creator)
codeByteBuffer.put(OpCode.FIN_IMD.compile());
/* Not trade nor cancel message */
labelNotTradeNorCancelTxn = codeByteBuffer.position();
// Loop to find another transaction
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelTradeTxnLoop == null ? 0 : labelTradeTxnLoop));
/* Possible switch-to-trade-mode message */
labelCheckNonRefundTradeTxn = codeByteBuffer.position();
// Check 'trade' message we received has expected number of message bytes
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(QortalFunctionCode.GET_MESSAGE_LENGTH_FROM_TX_IN_A.value, addrMessageLength));
// If message length matches, branch to info extraction code
codeByteBuffer.put(OpCode.BEQ_DAT.compile(addrMessageLength, addrExpectedTradeMessageLength, calcOffset(codeByteBuffer, labelTradeTxnExtract)));
// Message length didn't match - go back to finding another 'trade' MESSAGE transaction
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelTradeTxnLoop == null ? 0 : labelTradeTxnLoop));
/* Extracting info from 'trade' MESSAGE transaction */
labelTradeTxnExtract = codeByteBuffer.position();
// Extract message from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_MESSAGE_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrQortalPartnerAddress1 (as pointed to by addrQortalPartnerAddressPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrQortalPartnerAddressPointer));
// Extract trade partner's Digibyte public key hash (PKH) from message into B
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.PUT_PARTIAL_MESSAGE_FROM_TX_IN_A_INTO_B.value, addrTradeMessagePartnerDigibytePKHOffset));
// Store partner's Digibyte PKH (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerDigibytePKHPointer));
// Extract AT trade timeout (minutes) (from B4)
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_B4, addrRefundTimeout));
// Grab next 32 bytes
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.PUT_PARTIAL_MESSAGE_FROM_TX_IN_A_INTO_B.value, addrTradeMessageHashOfSecretAOffset));
// Extract hash-of-secret-A (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrHashOfSecretAPointer));
// Extract lockTime-A (from B4)
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_B4, addrLockTimeA));
// Calculate trade timeout refund 'timestamp' by adding addrRefundTimeout minutes to this transaction's 'timestamp', then save into addrRefundTimestamp
codeByteBuffer.put(OpCode.EXT_FUN_RET_DAT_2.compile(FunctionCode.ADD_MINUTES_TO_TIMESTAMP, addrRefundTimestamp, addrLastTxnTimestamp, addrRefundTimeout));
/* We are in 'trade mode' */
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.TRADING.value));
// Set restart position to after this opcode
codeByteBuffer.put(OpCode.SET_PCS.compile());
/* Loop, waiting for trade timeout or 'redeem' MESSAGE from Qortal trade partner */
// Fetch current block 'timestamp'
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_BLOCK_TIMESTAMP, addrBlockTimestamp));
// If we're not past refund 'timestamp' then look for next transaction
codeByteBuffer.put(OpCode.BLT_DAT.compile(addrBlockTimestamp, addrRefundTimestamp, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
// We're past refund 'timestamp' so go refund everything back to AT creator
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelRefund == null ? 0 : labelRefund));
/* Transaction processing loop */
labelRedeemTxnLoop = codeByteBuffer.position();
// Find next transaction to this AT since the last one (if any)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.PUT_TX_AFTER_TIMESTAMP_INTO_A, addrLastTxnTimestamp));
// If no transaction found, A will be zero. If A is zero, set addrComparator to 1, otherwise 0.
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.CHECK_A_IS_ZERO, addrResult));
// If addrResult is zero (i.e. A is non-zero, transaction was found) then go check transaction
codeByteBuffer.put(OpCode.BZR_DAT.compile(addrResult, calcOffset(codeByteBuffer, labelCheckRedeemTxn)));
// Stop and wait for next block
codeByteBuffer.put(OpCode.STP_IMD.compile());
/* Check transaction */
labelCheckRedeemTxn = codeByteBuffer.position();
// Update our 'last found transaction's timestamp' using 'timestamp' from transaction
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TIMESTAMP_FROM_TX_IN_A, addrLastTxnTimestamp));
// Extract transaction type (message/payment) from transaction and save type in addrTxnType
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TYPE_FROM_TX_IN_A, addrTxnType));
// If transaction type is not MESSAGE type then go look for another transaction
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrTxnType, addrMessageTxnType, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
/* Check message payload length */
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(QortalFunctionCode.GET_MESSAGE_LENGTH_FROM_TX_IN_A.value, addrMessageLength));
// If message length matches, branch to sender checking code
codeByteBuffer.put(OpCode.BEQ_DAT.compile(addrMessageLength, addrExpectedRedeemMessageLength, calcOffset(codeByteBuffer, labelCheckRedeemTxnSender)));
// Message length didn't match - go back to finding another 'redeem' MESSAGE transaction
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelRedeemTxnLoop == null ? 0 : labelRedeemTxnLoop));
/* Check transaction's sender */
labelCheckRedeemTxnSender = codeByteBuffer.position();
// Extract sender address from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_ADDRESS_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrMessageSender1 (as pointed to by addrMessageSenderPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrMessageSenderPointer));
// Compare each part of transaction's sender's address with expected address. If they don't match, look for another transaction.
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender1, addrQortalPartnerAddress1, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender2, addrQortalPartnerAddress2, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender3, addrQortalPartnerAddress3, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender4, addrQortalPartnerAddress4, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
/* Check 'secret-A' in transaction's message */
// Extract secret-A from first 32 bytes of message from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_MESSAGE_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrMessageData (as pointed to by addrMessageDataPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrMessageDataPointer));
// Load B register with expected hash result (as pointed to by addrHashOfSecretAPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.SET_B_IND, addrHashOfSecretAPointer));
// Perform HASH160 using source data at addrMessageData. (Location and length specified via addrMessageDataPointer and addrMessageDataLength).
// Save the equality result (1 if they match, 0 otherwise) into addrResult.
codeByteBuffer.put(OpCode.EXT_FUN_RET_DAT_2.compile(FunctionCode.CHECK_HASH160_WITH_B, addrResult, addrMessageDataPointer, addrMessageDataLength));
// If hashes don't match, addrResult will be zero so go find another transaction
codeByteBuffer.put(OpCode.BNZ_DAT.compile(addrResult, calcOffset(codeByteBuffer, labelPayout)));
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelRedeemTxnLoop == null ? 0 : labelRedeemTxnLoop));
/* Success! Pay arranged amount to receiving address */
labelPayout = codeByteBuffer.position();
// Extract Qortal receiving address from next 32 bytes of message from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.PUT_PARTIAL_MESSAGE_FROM_TX_IN_A_INTO_B.value, addrRedeemMessageReceivingAddressOffset));
// Save B register into data segment starting at addrPartnerReceivingAddress (as pointed to by addrPartnerReceivingAddressPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerReceivingAddressPointer));
// Pay AT's balance to receiving address
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.PAY_TO_ADDRESS_IN_B, addrQortAmount));
// Set redeemed mode
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.REDEEMED.value));
// We're finished forever (finishing auto-refunds remaining balance to AT creator)
codeByteBuffer.put(OpCode.FIN_IMD.compile());
// Fall-through to refunding any remaining balance back to AT creator
/* Refund balance back to AT creator */
labelRefund = codeByteBuffer.position();
// Set refunded mode
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.REFUNDED.value));
// We're finished forever (finishing auto-refunds remaining balance to AT creator)
codeByteBuffer.put(OpCode.FIN_IMD.compile());
} catch (CompilationException e) {
throw new IllegalStateException("Unable to compile DGB-QORT ACCT?", e);
}
}
codeByteBuffer.flip();
byte[] codeBytes = new byte[codeByteBuffer.limit()];
codeByteBuffer.get(codeBytes);
assert Arrays.equals(Crypto.digest(codeBytes), DigibyteACCTv3.CODE_BYTES_HASH)
: String.format("BTCACCT.CODE_BYTES_HASH mismatch: expected %s, actual %s", HashCode.fromBytes(CODE_BYTES_HASH), HashCode.fromBytes(Crypto.digest(codeBytes)));
final short ciyamAtVersion = 2;
final short numCallStackPages = 0;
final short numUserStackPages = 0;
final long minActivationAmount = 0L;
return MachineState.toCreationBytes(ciyamAtVersion, codeBytes, dataByteBuffer.array(), numCallStackPages, numUserStackPages, minActivationAmount);
}
/**
* Returns CrossChainTradeData with useful info extracted from AT.
*/
@Override
public CrossChainTradeData populateTradeData(Repository repository, ATData atData) throws DataException {
ATStateData atStateData = repository.getATRepository().getLatestATState(atData.getATAddress());
return populateTradeData(repository, atData.getCreatorPublicKey(), atData.getCreation(), atStateData);
}
/**
* Returns CrossChainTradeData with useful info extracted from AT.
*/
@Override
public CrossChainTradeData populateTradeData(Repository repository, ATStateData atStateData) throws DataException {
ATData atData = repository.getATRepository().fromATAddress(atStateData.getATAddress());
return populateTradeData(repository, atData.getCreatorPublicKey(), atData.getCreation(), atStateData);
}
/**
* Returns CrossChainTradeData with useful info extracted from AT.
*/
public CrossChainTradeData populateTradeData(Repository repository, byte[] creatorPublicKey, long creationTimestamp, ATStateData atStateData) throws DataException {
byte[] addressBytes = new byte[25]; // for general use
String atAddress = atStateData.getATAddress();
CrossChainTradeData tradeData = new CrossChainTradeData();
tradeData.foreignBlockchain = SupportedBlockchain.DIGIBYTE.name();
tradeData.acctName = NAME;
tradeData.qortalAtAddress = atAddress;
tradeData.qortalCreator = Crypto.toAddress(creatorPublicKey);
tradeData.creationTimestamp = creationTimestamp;
Account atAccount = new Account(repository, atAddress);
tradeData.qortBalance = atAccount.getConfirmedBalance(Asset.QORT);
byte[] stateData = atStateData.getStateData();
ByteBuffer dataByteBuffer = ByteBuffer.wrap(stateData);
dataByteBuffer.position(MachineState.HEADER_LENGTH);
/* Constants */
// Skip creator's trade address
dataByteBuffer.get(addressBytes);
tradeData.qortalCreatorTradeAddress = Base58.encode(addressBytes);
dataByteBuffer.position(dataByteBuffer.position() + 32 - addressBytes.length);
// Creator's Digibyte/foreign public key hash
tradeData.creatorForeignPKH = new byte[20];
dataByteBuffer.get(tradeData.creatorForeignPKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - tradeData.creatorForeignPKH.length); // skip to 32 bytes
// We don't use secret-B
tradeData.hashOfSecretB = null;
// Redeem payout
tradeData.qortAmount = dataByteBuffer.getLong();
// Expected DGB amount
tradeData.expectedForeignAmount = dataByteBuffer.getLong();
// Trade timeout
tradeData.tradeTimeout = (int) dataByteBuffer.getLong();
// Skip MESSAGE transaction type
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip expected 'trade' message length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip expected 'redeem' message length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to creator's address
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Qortal trade address
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to message sender
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip 'trade' message data offset for partner's Digibyte PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Digibyte PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip 'trade' message data offset for hash-of-secret-A
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to hash-of-secret-A
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip 'redeem' message data offset for partner's Qortal receiving address
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to message data
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip message data length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's receiving address
dataByteBuffer.position(dataByteBuffer.position() + 8);
/* End of constants / begin variables */
// Skip AT creator's address
dataByteBuffer.position(dataByteBuffer.position() + 8 * 4);
// Partner's trade address (if present)
dataByteBuffer.get(addressBytes);
String qortalRecipient = Base58.encode(addressBytes);
dataByteBuffer.position(dataByteBuffer.position() + 32 - addressBytes.length);
// Potential lockTimeA (if in trade mode)
int lockTimeA = (int) dataByteBuffer.getLong();
// AT refund timeout (probably only useful for debugging)
int refundTimeout = (int) dataByteBuffer.getLong();
// Trade-mode refund timestamp (AT 'timestamp' converted to Qortal block height)
long tradeRefundTimestamp = dataByteBuffer.getLong();
// Skip last transaction timestamp
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip block timestamp
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip transaction type
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip temporary result
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip temporary message sender
dataByteBuffer.position(dataByteBuffer.position() + 8 * 4);
// Skip message length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip temporary message data
dataByteBuffer.position(dataByteBuffer.position() + 8 * 4);
// Potential hash160 of secret A
byte[] hashOfSecretA = new byte[20];
dataByteBuffer.get(hashOfSecretA);
dataByteBuffer.position(dataByteBuffer.position() + 32 - hashOfSecretA.length); // skip to 32 bytes
// Potential partner's Digibyte PKH
byte[] partnerDigibytePKH = new byte[20];
dataByteBuffer.get(partnerDigibytePKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerDigibytePKH.length); // skip to 32 bytes
// Partner's receiving address (if present)
byte[] partnerReceivingAddress = new byte[25];
dataByteBuffer.get(partnerReceivingAddress);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerReceivingAddress.length); // skip to 32 bytes
// Trade AT's 'mode'
long modeValue = dataByteBuffer.getLong();
AcctMode mode = AcctMode.valueOf((int) (modeValue & 0xffL));
/* End of variables */
if (mode != null && mode != AcctMode.OFFERING) {
tradeData.mode = mode;
tradeData.refundTimeout = refundTimeout;
tradeData.tradeRefundHeight = new Timestamp(tradeRefundTimestamp).blockHeight;
tradeData.qortalPartnerAddress = qortalRecipient;
tradeData.hashOfSecretA = hashOfSecretA;
tradeData.partnerForeignPKH = partnerDigibytePKH;
tradeData.lockTimeA = lockTimeA;
if (mode == AcctMode.REDEEMED)
tradeData.qortalPartnerReceivingAddress = Base58.encode(partnerReceivingAddress);
} else {
tradeData.mode = AcctMode.OFFERING;
}
tradeData.duplicateDeprecated();
return tradeData;
}
/** Returns 'offer' MESSAGE payload for trade partner to send to AT creator's trade address. */
public static byte[] buildOfferMessage(byte[] partnerBitcoinPKH, byte[] hashOfSecretA, int lockTimeA) {
byte[] lockTimeABytes = BitTwiddling.toBEByteArray((long) lockTimeA);
return Bytes.concat(partnerBitcoinPKH, hashOfSecretA, lockTimeABytes);
}
/** Returns info extracted from 'offer' MESSAGE payload sent by trade partner to AT creator's trade address, or null if not valid. */
public static OfferMessageData extractOfferMessageData(byte[] messageData) {
if (messageData == null || messageData.length != OFFER_MESSAGE_LENGTH)
return null;
OfferMessageData offerMessageData = new OfferMessageData();
offerMessageData.partnerDigibytePKH = Arrays.copyOfRange(messageData, 0, 20);
offerMessageData.hashOfSecretA = Arrays.copyOfRange(messageData, 20, 40);
offerMessageData.lockTimeA = BitTwiddling.longFromBEBytes(messageData, 40);
return offerMessageData;
}
/** Returns 'trade' MESSAGE payload for AT creator to send to AT. */
public static byte[] buildTradeMessage(String partnerQortalTradeAddress, byte[] partnerBitcoinPKH, byte[] hashOfSecretA, int lockTimeA, int refundTimeout) {
byte[] data = new byte[TRADE_MESSAGE_LENGTH];
byte[] partnerQortalAddressBytes = Base58.decode(partnerQortalTradeAddress);
byte[] lockTimeABytes = BitTwiddling.toBEByteArray((long) lockTimeA);
byte[] refundTimeoutBytes = BitTwiddling.toBEByteArray((long) refundTimeout);
System.arraycopy(partnerQortalAddressBytes, 0, data, 0, partnerQortalAddressBytes.length);
System.arraycopy(partnerBitcoinPKH, 0, data, 32, partnerBitcoinPKH.length);
System.arraycopy(refundTimeoutBytes, 0, data, 56, refundTimeoutBytes.length);
System.arraycopy(hashOfSecretA, 0, data, 64, hashOfSecretA.length);
System.arraycopy(lockTimeABytes, 0, data, 88, lockTimeABytes.length);
return data;
}
/** Returns 'cancel' MESSAGE payload for AT creator to cancel trade AT. */
@Override
public byte[] buildCancelMessage(String creatorQortalAddress) {
byte[] data = new byte[CANCEL_MESSAGE_LENGTH];
byte[] creatorQortalAddressBytes = Base58.decode(creatorQortalAddress);
System.arraycopy(creatorQortalAddressBytes, 0, data, 0, creatorQortalAddressBytes.length);
return data;
}
/** Returns 'redeem' MESSAGE payload for trade partner to send to AT. */
public static byte[] buildRedeemMessage(byte[] secretA, String qortalReceivingAddress) {
byte[] data = new byte[REDEEM_MESSAGE_LENGTH];
byte[] qortalReceivingAddressBytes = Base58.decode(qortalReceivingAddress);
System.arraycopy(secretA, 0, data, 0, secretA.length);
System.arraycopy(qortalReceivingAddressBytes, 0, data, 32, qortalReceivingAddressBytes.length);
return data;
}
/** Returns refund timeout (minutes) based on trade partner's 'offer' MESSAGE timestamp and P2SH-A locktime. */
public static int calcRefundTimeout(long offerMessageTimestamp, int lockTimeA) {
// refund should be triggered halfway between offerMessageTimestamp and lockTimeA
return (int) ((lockTimeA - (offerMessageTimestamp / 1000L)) / 2L / 60L);
}
@Override
public byte[] findSecretA(Repository repository, CrossChainTradeData crossChainTradeData) throws DataException {
String atAddress = crossChainTradeData.qortalAtAddress;
String redeemerAddress = crossChainTradeData.qortalPartnerAddress;
// We don't have partner's public key so we check every message to AT
List<MessageTransactionData> messageTransactionsData = repository.getMessageRepository().getMessagesByParticipants(null, atAddress, null, null, null);
if (messageTransactionsData == null)
return null;
// Find 'redeem' message
for (MessageTransactionData messageTransactionData : messageTransactionsData) {
// Check message payload type/encryption
if (messageTransactionData.isText() || messageTransactionData.isEncrypted())
continue;
// Check message payload size
byte[] messageData = messageTransactionData.getData();
if (messageData.length != REDEEM_MESSAGE_LENGTH)
// Wrong payload length
continue;
// Check sender
if (!Crypto.toAddress(messageTransactionData.getSenderPublicKey()).equals(redeemerAddress))
// Wrong sender;
continue;
// Extract secretA
byte[] secretA = new byte[32];
System.arraycopy(messageData, 0, secretA, 0, secretA.length);
byte[] hashOfSecretA = Crypto.hash160(secretA);
if (!Arrays.equals(hashOfSecretA, crossChainTradeData.hashOfSecretA))
continue;
return secretA;
}
return null;
}
}

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src/main/java/org/qortal/crosschain/Ravencoin.java Normal file
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package org.qortal.crosschain;
import java.util.Arrays;
import java.util.Collection;
import java.util.EnumMap;
import java.util.Map;
import org.bitcoinj.core.Coin;
import org.bitcoinj.core.Context;
import org.bitcoinj.core.NetworkParameters;
import org.bitcoinj.params.RegTestParams;
import org.bitcoinj.params.TestNet3Params;
import org.libdohj.params.RavencoinMainNetParams;
import org.qortal.crosschain.ElectrumX.Server;
import org.qortal.crosschain.ElectrumX.Server.ConnectionType;
import org.qortal.settings.Settings;
public class Ravencoin extends Bitcoiny {
public static final String CURRENCY_CODE = "RVN";
private static final Coin DEFAULT_FEE_PER_KB = Coin.valueOf(1125000); // 0.01125 RVN per 1000 bytes
private static final long MINIMUM_ORDER_AMOUNT = 1000000; // 0.01 RVN minimum order, to avoid dust errors
// Temporary values until a dynamic fee system is written.
private static final long MAINNET_FEE = 1000000L;
private static final long NON_MAINNET_FEE = 1000000L; // enough for TESTNET3 and should be OK for REGTEST
private static final Map<ConnectionType, Integer> DEFAULT_ELECTRUMX_PORTS = new EnumMap<>(ConnectionType.class);
static {
DEFAULT_ELECTRUMX_PORTS.put(ConnectionType.TCP, 50001);
DEFAULT_ELECTRUMX_PORTS.put(ConnectionType.SSL, 50002);
}
public enum RavencoinNet {
MAIN {
@Override
public NetworkParameters getParams() {
return RavencoinMainNetParams.get();
}
@Override
public Collection<Server> getServers() {
return Arrays.asList(
// Servers chosen on NO BASIS WHATSOEVER from various sources!
// Status verified at https://1209k.com/bitcoin-eye/ele.php?chain=rvn
new Server("aethyn.com", ConnectionType.SSL, 50002),
new Server("electrum2.rvn.rocks", ConnectionType.SSL, 50002),
new Server("rvn-dashboard.com", ConnectionType.SSL, 50002),
new Server("rvn4lyfe.com", ConnectionType.SSL, 50002),
new Server("electrum1.cipig.net", ConnectionType.SSL, 20051),
new Server("electrum2.cipig.net", ConnectionType.SSL, 20051),
new Server("electrum3.cipig.net", ConnectionType.SSL, 20051));
}
@Override
public String getGenesisHash() {
return "0000006b444bc2f2ffe627be9d9e7e7a0730000870ef6eb6da46c8eae389df90";
}
@Override
public long getP2shFee(Long timestamp) {
// TODO: This will need to be replaced with something better in the near future!
return MAINNET_FEE;
}
},
TEST3 {
@Override
public NetworkParameters getParams() {
return TestNet3Params.get();
}
@Override
public Collection<Server> getServers() {
return Arrays.asList(); // TODO: find testnet servers
}
@Override
public String getGenesisHash() {
return "000000ecfc5e6324a079542221d00e10362bdc894d56500c414060eea8a3ad5a";
}
@Override
public long getP2shFee(Long timestamp) {
return NON_MAINNET_FEE;
}
},
REGTEST {
@Override
public NetworkParameters getParams() {
return RegTestParams.get();
}
@Override
public Collection<Server> getServers() {
return Arrays.asList(
new Server("localhost", ConnectionType.TCP, 50001),
new Server("localhost", ConnectionType.SSL, 50002));
}
@Override
public String getGenesisHash() {
// This is unique to each regtest instance
return null;
}
@Override
public long getP2shFee(Long timestamp) {
return NON_MAINNET_FEE;
}
};
public abstract NetworkParameters getParams();
public abstract Collection<Server> getServers();
public abstract String getGenesisHash();
public abstract long getP2shFee(Long timestamp) throws ForeignBlockchainException;
}
private static Ravencoin instance;
private final RavencoinNet ravencoinNet;
// Constructors and instance
private Ravencoin(RavencoinNet ravencoinNet, BitcoinyBlockchainProvider blockchain, Context bitcoinjContext, String currencyCode) {
super(blockchain, bitcoinjContext, currencyCode);
this.ravencoinNet = ravencoinNet;
LOGGER.info(() -> String.format("Starting Ravencoin support using %s", this.ravencoinNet.name()));
}
public static synchronized Ravencoin getInstance() {
if (instance == null) {
RavencoinNet ravencoinNet = Settings.getInstance().getRavencoinNet();
BitcoinyBlockchainProvider electrumX = new ElectrumX("Ravencoin-" + ravencoinNet.name(), ravencoinNet.getGenesisHash(), ravencoinNet.getServers(), DEFAULT_ELECTRUMX_PORTS);
Context bitcoinjContext = new Context(ravencoinNet.getParams());
instance = new Ravencoin(ravencoinNet, electrumX, bitcoinjContext, CURRENCY_CODE);
}
return instance;
}
// Getters & setters
public static synchronized void resetForTesting() {
instance = null;
}
// Actual useful methods for use by other classes
@Override
public Coin getFeePerKb() {
return DEFAULT_FEE_PER_KB;
}
@Override
public long getMinimumOrderAmount() {
return MINIMUM_ORDER_AMOUNT;
}
/**
* Returns estimated RVN fee, in sats per 1000bytes, optionally for historic timestamp.
*
* @param timestamp optional milliseconds since epoch, or null for 'now'
* @return sats per 1000bytes, or throws ForeignBlockchainException if something went wrong
*/
@Override
public long getP2shFee(Long timestamp) throws ForeignBlockchainException {
return this.ravencoinNet.getP2shFee(timestamp);
}
}

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src/main/java/org/qortal/crosschain/RavencoinACCTv3.java Normal file
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package org.qortal.crosschain;
import com.google.common.hash.HashCode;
import com.google.common.primitives.Bytes;
import org.apache.logging.log4j.LogManager;
import org.apache.logging.log4j.Logger;
import org.ciyam.at.*;
import org.qortal.account.Account;
import org.qortal.asset.Asset;
import org.qortal.at.QortalFunctionCode;
import org.qortal.crypto.Crypto;
import org.qortal.data.at.ATData;
import org.qortal.data.at.ATStateData;
import org.qortal.data.crosschain.CrossChainTradeData;
import org.qortal.data.transaction.MessageTransactionData;
import org.qortal.repository.DataException;
import org.qortal.repository.Repository;
import org.qortal.utils.Base58;
import org.qortal.utils.BitTwiddling;
import java.nio.ByteBuffer;
import java.util.Arrays;
import java.util.List;
import static org.ciyam.at.OpCode.calcOffset;
/**
* Cross-chain trade AT
*
* <p>
* <ul>
* <li>Bob generates Ravencoin & Qortal 'trade' keys
* <ul>
* <li>private key required to sign P2SH redeem tx</li>
* <li>private key could be used to create 'secret' (e.g. double-SHA256)</li>
* <li>encrypted private key could be stored in Qortal AT for access by Bob from any node</li>
* </ul>
* </li>
* <li>Bob deploys Qortal AT
* <ul>
* </ul>
* </li>
* <li>Alice finds Qortal AT and wants to trade
* <ul>
* <li>Alice generates Ravencoin & Qortal 'trade' keys</li>
* <li>Alice funds Ravencoin P2SH-A</li>
* <li>Alice sends 'offer' MESSAGE to Bob from her Qortal trade address, containing:
* <ul>
* <li>hash-of-secret-A</li>
* <li>her 'trade' Ravencoin PKH</li>
* </ul>
* </li>
* </ul>
* </li>
* <li>Bob receives "offer" MESSAGE
* <ul>
* <li>Checks Alice's P2SH-A</li>
* <li>Sends 'trade' MESSAGE to Qortal AT from his trade address, containing:
* <ul>
* <li>Alice's trade Qortal address</li>
* <li>Alice's trade Ravencoin PKH</li>
* <li>hash-of-secret-A</li>
* </ul>
* </li>
* </ul>
* </li>
* <li>Alice checks Qortal AT to confirm it's locked to her
* <ul>
* <li>Alice sends 'redeem' MESSAGE to Qortal AT from her trade address, containing:
* <ul>
* <li>secret-A</li>
* <li>Qortal receiving address of her chosing</li>
* </ul>
* </li>
* <li>AT's QORT funds are sent to Qortal receiving address</li>
* </ul>
* </li>
* <li>Bob checks AT, extracts secret-A
* <ul>
* <li>Bob redeems P2SH-A using his Ravencoin trade key and secret-A</li>
* <li>P2SH-A RVN funds end up at Ravencoin address determined by redeem transaction output(s)</li>
* </ul>
* </li>
* </ul>
*/
public class RavencoinACCTv3 implements ACCT {
private static final Logger LOGGER = LogManager.getLogger(RavencoinACCTv3.class);
public static final String NAME = RavencoinACCTv3.class.getSimpleName();
public static final byte[] CODE_BYTES_HASH = HashCode.fromString("91395fa1ec0dfa35beddb0a7f4cc0a1bede157c38787ddb0af0cf03dfdc10f77").asBytes(); // SHA256 of AT code bytes
public static final int SECRET_LENGTH = 32;
/** <b>Value</b> offset into AT segment where 'mode' variable (long) is stored. (Multiply by MachineState.VALUE_SIZE for byte offset). */
private static final int MODE_VALUE_OFFSET = 61;
/** <b>Byte</b> offset into AT state data where 'mode' variable (long) is stored. */
public static final int MODE_BYTE_OFFSET = MachineState.HEADER_LENGTH + (MODE_VALUE_OFFSET * MachineState.VALUE_SIZE);
public static class OfferMessageData {
public byte[] partnerRavencoinPKH;
public byte[] hashOfSecretA;
public long lockTimeA;
}
public static final int OFFER_MESSAGE_LENGTH = 20 /*partnerRavencoinPKH*/ + 20 /*hashOfSecretA*/ + 8 /*lockTimeA*/;
public static final int TRADE_MESSAGE_LENGTH = 32 /*partner's Qortal trade address (padded from 25 to 32)*/
+ 24 /*partner's Ravencoin PKH (padded from 20 to 24)*/
+ 8 /*AT trade timeout (minutes)*/
+ 24 /*hash of secret-A (padded from 20 to 24)*/
+ 8 /*lockTimeA*/;
public static final int REDEEM_MESSAGE_LENGTH = 32 /*secret-A*/ + 32 /*partner's Qortal receiving address padded from 25 to 32*/;
public static final int CANCEL_MESSAGE_LENGTH = 32 /*AT creator's Qortal address*/;
private static RavencoinACCTv3 instance;
private RavencoinACCTv3() {
}
public static synchronized RavencoinACCTv3 getInstance() {
if (instance == null)
instance = new RavencoinACCTv3();
return instance;
}
@Override
public byte[] getCodeBytesHash() {
return CODE_BYTES_HASH;
}
@Override
public int getModeByteOffset() {
return MODE_BYTE_OFFSET;
}
@Override
public ForeignBlockchain getBlockchain() {
return Ravencoin.getInstance();
}
/**
* Returns Qortal AT creation bytes for cross-chain trading AT.
* <p>
* <tt>tradeTimeout</tt> (minutes) is the time window for the trade partner to send the
* 32-byte secret to the AT, before the AT automatically refunds the AT's creator.
*
* @param creatorTradeAddress AT creator's trade Qortal address
* @param ravencoinPublicKeyHash 20-byte HASH160 of creator's trade Ravencoin public key
* @param qortAmount how much QORT to pay trade partner if they send correct 32-byte secrets to AT
* @param ravencoinAmount how much RVN the AT creator is expecting to trade
* @param tradeTimeout suggested timeout for entire trade
*/
public static byte[] buildQortalAT(String creatorTradeAddress, byte[] ravencoinPublicKeyHash, long qortAmount, long ravencoinAmount, int tradeTimeout) {
if (ravencoinPublicKeyHash.length != 20)
throw new IllegalArgumentException("Ravencoin public key hash should be 20 bytes");
// Labels for data segment addresses
int addrCounter = 0;
// Constants (with corresponding dataByteBuffer.put*() calls below)
final int addrCreatorTradeAddress1 = addrCounter++;
final int addrCreatorTradeAddress2 = addrCounter++;
final int addrCreatorTradeAddress3 = addrCounter++;
final int addrCreatorTradeAddress4 = addrCounter++;
final int addrRavencoinPublicKeyHash = addrCounter;
addrCounter += 4;
final int addrQortAmount = addrCounter++;
final int addrRavencoinAmount = addrCounter++;
final int addrTradeTimeout = addrCounter++;
final int addrMessageTxnType = addrCounter++;
final int addrExpectedTradeMessageLength = addrCounter++;
final int addrExpectedRedeemMessageLength = addrCounter++;
final int addrCreatorAddressPointer = addrCounter++;
final int addrQortalPartnerAddressPointer = addrCounter++;
final int addrMessageSenderPointer = addrCounter++;
final int addrTradeMessagePartnerRavencoinPKHOffset = addrCounter++;
final int addrPartnerRavencoinPKHPointer = addrCounter++;
final int addrTradeMessageHashOfSecretAOffset = addrCounter++;
final int addrHashOfSecretAPointer = addrCounter++;
final int addrRedeemMessageReceivingAddressOffset = addrCounter++;
final int addrMessageDataPointer = addrCounter++;
final int addrMessageDataLength = addrCounter++;
final int addrPartnerReceivingAddressPointer = addrCounter++;
final int addrEndOfConstants = addrCounter;
// Variables
final int addrCreatorAddress1 = addrCounter++;
final int addrCreatorAddress2 = addrCounter++;
final int addrCreatorAddress3 = addrCounter++;
final int addrCreatorAddress4 = addrCounter++;
final int addrQortalPartnerAddress1 = addrCounter++;
final int addrQortalPartnerAddress2 = addrCounter++;
final int addrQortalPartnerAddress3 = addrCounter++;
final int addrQortalPartnerAddress4 = addrCounter++;
final int addrLockTimeA = addrCounter++;
final int addrRefundTimeout = addrCounter++;
final int addrRefundTimestamp = addrCounter++;
final int addrLastTxnTimestamp = addrCounter++;
final int addrBlockTimestamp = addrCounter++;
final int addrTxnType = addrCounter++;
final int addrResult = addrCounter++;
final int addrMessageSender1 = addrCounter++;
final int addrMessageSender2 = addrCounter++;
final int addrMessageSender3 = addrCounter++;
final int addrMessageSender4 = addrCounter++;
final int addrMessageLength = addrCounter++;
final int addrMessageData = addrCounter;
addrCounter += 4;
final int addrHashOfSecretA = addrCounter;
addrCounter += 4;
final int addrPartnerRavencoinPKH = addrCounter;
addrCounter += 4;
final int addrPartnerReceivingAddress = addrCounter;
addrCounter += 4;
final int addrMode = addrCounter++;
assert addrMode == MODE_VALUE_OFFSET : String.format("addrMode %d does not match MODE_VALUE_OFFSET %d", addrMode, MODE_VALUE_OFFSET);
// Data segment
ByteBuffer dataByteBuffer = ByteBuffer.allocate(addrCounter * MachineState.VALUE_SIZE);
// AT creator's trade Qortal address, decoded from Base58
assert dataByteBuffer.position() == addrCreatorTradeAddress1 * MachineState.VALUE_SIZE : "addrCreatorTradeAddress1 incorrect";
byte[] creatorTradeAddressBytes = Base58.decode(creatorTradeAddress);
dataByteBuffer.put(Bytes.ensureCapacity(creatorTradeAddressBytes, 32, 0));
// Ravencoin public key hash
assert dataByteBuffer.position() == addrRavencoinPublicKeyHash * MachineState.VALUE_SIZE : "addrRavencoinPublicKeyHash incorrect";
dataByteBuffer.put(Bytes.ensureCapacity(ravencoinPublicKeyHash, 32, 0));
// Redeem Qort amount
assert dataByteBuffer.position() == addrQortAmount * MachineState.VALUE_SIZE : "addrQortAmount incorrect";
dataByteBuffer.putLong(qortAmount);
// Expected Ravencoin amount
assert dataByteBuffer.position() == addrRavencoinAmount * MachineState.VALUE_SIZE : "addrRavencoinAmount incorrect";
dataByteBuffer.putLong(ravencoinAmount);
// Suggested trade timeout (minutes)
assert dataByteBuffer.position() == addrTradeTimeout * MachineState.VALUE_SIZE : "addrTradeTimeout incorrect";
dataByteBuffer.putLong(tradeTimeout);
// We're only interested in MESSAGE transactions
assert dataByteBuffer.position() == addrMessageTxnType * MachineState.VALUE_SIZE : "addrMessageTxnType incorrect";
dataByteBuffer.putLong(API.ATTransactionType.MESSAGE.value);
// Expected length of 'trade' MESSAGE data from AT creator
assert dataByteBuffer.position() == addrExpectedTradeMessageLength * MachineState.VALUE_SIZE : "addrExpectedTradeMessageLength incorrect";
dataByteBuffer.putLong(TRADE_MESSAGE_LENGTH);
// Expected length of 'redeem' MESSAGE data from trade partner
assert dataByteBuffer.position() == addrExpectedRedeemMessageLength * MachineState.VALUE_SIZE : "addrExpectedRedeemMessageLength incorrect";
dataByteBuffer.putLong(REDEEM_MESSAGE_LENGTH);
// Index into data segment of AT creator's address, used by GET_B_IND
assert dataByteBuffer.position() == addrCreatorAddressPointer * MachineState.VALUE_SIZE : "addrCreatorAddressPointer incorrect";
dataByteBuffer.putLong(addrCreatorAddress1);
// Index into data segment of partner's Qortal address, used by SET_B_IND
assert dataByteBuffer.position() == addrQortalPartnerAddressPointer * MachineState.VALUE_SIZE : "addrQortalPartnerAddressPointer incorrect";
dataByteBuffer.putLong(addrQortalPartnerAddress1);
// Index into data segment of (temporary) transaction's sender's address, used by GET_B_IND
assert dataByteBuffer.position() == addrMessageSenderPointer * MachineState.VALUE_SIZE : "addrMessageSenderPointer incorrect";
dataByteBuffer.putLong(addrMessageSender1);
// Offset into 'trade' MESSAGE data payload for extracting partner's Ravencoin PKH
assert dataByteBuffer.position() == addrTradeMessagePartnerRavencoinPKHOffset * MachineState.VALUE_SIZE : "addrTradeMessagePartnerRavencoinPKHOffset incorrect";
dataByteBuffer.putLong(32L);
// Index into data segment of partner's Ravencoin PKH, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerRavencoinPKHPointer * MachineState.VALUE_SIZE : "addrPartnerRavencoinPKHPointer incorrect";
dataByteBuffer.putLong(addrPartnerRavencoinPKH);
// Offset into 'trade' MESSAGE data payload for extracting hash-of-secret-A
assert dataByteBuffer.position() == addrTradeMessageHashOfSecretAOffset * MachineState.VALUE_SIZE : "addrTradeMessageHashOfSecretAOffset incorrect";
dataByteBuffer.putLong(64L);
// Index into data segment to hash of secret A, used by GET_B_IND
assert dataByteBuffer.position() == addrHashOfSecretAPointer * MachineState.VALUE_SIZE : "addrHashOfSecretAPointer incorrect";
dataByteBuffer.putLong(addrHashOfSecretA);
// Offset into 'redeem' MESSAGE data payload for extracting Qortal receiving address
assert dataByteBuffer.position() == addrRedeemMessageReceivingAddressOffset * MachineState.VALUE_SIZE : "addrRedeemMessageReceivingAddressOffset incorrect";
dataByteBuffer.putLong(32L);
// Source location and length for hashing any passed secret
assert dataByteBuffer.position() == addrMessageDataPointer * MachineState.VALUE_SIZE : "addrMessageDataPointer incorrect";
dataByteBuffer.putLong(addrMessageData);
assert dataByteBuffer.position() == addrMessageDataLength * MachineState.VALUE_SIZE : "addrMessageDataLength incorrect";
dataByteBuffer.putLong(32L);
// Pointer into data segment of where to save partner's receiving Qortal address, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerReceivingAddressPointer * MachineState.VALUE_SIZE : "addrPartnerReceivingAddressPointer incorrect";
dataByteBuffer.putLong(addrPartnerReceivingAddress);
assert dataByteBuffer.position() == addrEndOfConstants * MachineState.VALUE_SIZE : "dataByteBuffer position not at end of constants";
// Code labels
Integer labelRefund = null;
Integer labelTradeTxnLoop = null;
Integer labelCheckTradeTxn = null;
Integer labelCheckCancelTxn = null;
Integer labelNotTradeNorCancelTxn = null;
Integer labelCheckNonRefundTradeTxn = null;
Integer labelTradeTxnExtract = null;
Integer labelRedeemTxnLoop = null;
Integer labelCheckRedeemTxn = null;
Integer labelCheckRedeemTxnSender = null;
Integer labelPayout = null;
ByteBuffer codeByteBuffer = ByteBuffer.allocate(768);
// Two-pass version
for (int pass = 0; pass < 2; ++pass) {
codeByteBuffer.clear();
try {
/* Initialization */
// Use AT creation 'timestamp' as starting point for finding transactions sent to AT
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_CREATION_TIMESTAMP, addrLastTxnTimestamp));
// Load B register with AT creator's address so we can save it into addrCreatorAddress1-4
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_CREATOR_INTO_B));
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrCreatorAddressPointer));
/* NOP - to ensure RAVENCOIN ACCT is unique */
codeByteBuffer.put(OpCode.NOP.compile());
// Set restart position to after this opcode
codeByteBuffer.put(OpCode.SET_PCS.compile());
/* Loop, waiting for message from AT creator's trade address containing trade partner details, or AT owner's address to cancel offer */
/* Transaction processing loop */
labelTradeTxnLoop = codeByteBuffer.position();
/* Sleep until message arrives */
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.SLEEP_UNTIL_MESSAGE.value, addrLastTxnTimestamp));
// Find next transaction (if any) to this AT since the last one (referenced by addrLastTxnTimestamp)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.PUT_TX_AFTER_TIMESTAMP_INTO_A, addrLastTxnTimestamp));
// If no transaction found, A will be zero. If A is zero, set addrResult to 1, otherwise 0.
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.CHECK_A_IS_ZERO, addrResult));
// If addrResult is zero (i.e. A is non-zero, transaction was found) then go check transaction
codeByteBuffer.put(OpCode.BZR_DAT.compile(addrResult, calcOffset(codeByteBuffer, labelCheckTradeTxn)));
// Stop and wait for next block
codeByteBuffer.put(OpCode.STP_IMD.compile());
/* Check transaction */
labelCheckTradeTxn = codeByteBuffer.position();
// Update our 'last found transaction's timestamp' using 'timestamp' from transaction
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TIMESTAMP_FROM_TX_IN_A, addrLastTxnTimestamp));
// Extract transaction type (message/payment) from transaction and save type in addrTxnType
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TYPE_FROM_TX_IN_A, addrTxnType));
// If transaction type is not MESSAGE type then go look for another transaction
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrTxnType, addrMessageTxnType, calcOffset(codeByteBuffer, labelTradeTxnLoop)));
/* Check transaction's sender. We're expecting AT creator's trade address for 'trade' message, or AT creator's own address for 'cancel' message. */
// Extract sender address from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_ADDRESS_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrMessageSender1 (as pointed to by addrMessageSenderPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrMessageSenderPointer));
// Compare each part of message sender's address with AT creator's trade address. If they don't match, check for cancel situation.
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender1, addrCreatorTradeAddress1, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender2, addrCreatorTradeAddress2, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender3, addrCreatorTradeAddress3, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender4, addrCreatorTradeAddress4, calcOffset(codeByteBuffer, labelCheckCancelTxn)));
// Message sender's address matches AT creator's trade address so go process 'trade' message
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelCheckNonRefundTradeTxn == null ? 0 : labelCheckNonRefundTradeTxn));
/* Checking message sender for possible cancel message */
labelCheckCancelTxn = codeByteBuffer.position();
// Compare each part of message sender's address with AT creator's address. If they don't match, look for another transaction.
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender1, addrCreatorAddress1, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender2, addrCreatorAddress2, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender3, addrCreatorAddress3, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender4, addrCreatorAddress4, calcOffset(codeByteBuffer, labelNotTradeNorCancelTxn)));
// Partner address is AT creator's address, so cancel offer and finish.
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.CANCELLED.value));
// We're finished forever (finishing auto-refunds remaining balance to AT creator)
codeByteBuffer.put(OpCode.FIN_IMD.compile());
/* Not trade nor cancel message */
labelNotTradeNorCancelTxn = codeByteBuffer.position();
// Loop to find another transaction
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelTradeTxnLoop == null ? 0 : labelTradeTxnLoop));
/* Possible switch-to-trade-mode message */
labelCheckNonRefundTradeTxn = codeByteBuffer.position();
// Check 'trade' message we received has expected number of message bytes
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(QortalFunctionCode.GET_MESSAGE_LENGTH_FROM_TX_IN_A.value, addrMessageLength));
// If message length matches, branch to info extraction code
codeByteBuffer.put(OpCode.BEQ_DAT.compile(addrMessageLength, addrExpectedTradeMessageLength, calcOffset(codeByteBuffer, labelTradeTxnExtract)));
// Message length didn't match - go back to finding another 'trade' MESSAGE transaction
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelTradeTxnLoop == null ? 0 : labelTradeTxnLoop));
/* Extracting info from 'trade' MESSAGE transaction */
labelTradeTxnExtract = codeByteBuffer.position();
// Extract message from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_MESSAGE_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrQortalPartnerAddress1 (as pointed to by addrQortalPartnerAddressPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrQortalPartnerAddressPointer));
// Extract trade partner's Ravencoin public key hash (PKH) from message into B
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.PUT_PARTIAL_MESSAGE_FROM_TX_IN_A_INTO_B.value, addrTradeMessagePartnerRavencoinPKHOffset));
// Store partner's Ravencoin PKH (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerRavencoinPKHPointer));
// Extract AT trade timeout (minutes) (from B4)
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_B4, addrRefundTimeout));
// Grab next 32 bytes
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.PUT_PARTIAL_MESSAGE_FROM_TX_IN_A_INTO_B.value, addrTradeMessageHashOfSecretAOffset));
// Extract hash-of-secret-A (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrHashOfSecretAPointer));
// Extract lockTime-A (from B4)
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_B4, addrLockTimeA));
// Calculate trade timeout refund 'timestamp' by adding addrRefundTimeout minutes to this transaction's 'timestamp', then save into addrRefundTimestamp
codeByteBuffer.put(OpCode.EXT_FUN_RET_DAT_2.compile(FunctionCode.ADD_MINUTES_TO_TIMESTAMP, addrRefundTimestamp, addrLastTxnTimestamp, addrRefundTimeout));
/* We are in 'trade mode' */
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.TRADING.value));
// Set restart position to after this opcode
codeByteBuffer.put(OpCode.SET_PCS.compile());
/* Loop, waiting for trade timeout or 'redeem' MESSAGE from Qortal trade partner */
// Fetch current block 'timestamp'
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_BLOCK_TIMESTAMP, addrBlockTimestamp));
// If we're not past refund 'timestamp' then look for next transaction
codeByteBuffer.put(OpCode.BLT_DAT.compile(addrBlockTimestamp, addrRefundTimestamp, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
// We're past refund 'timestamp' so go refund everything back to AT creator
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelRefund == null ? 0 : labelRefund));
/* Transaction processing loop */
labelRedeemTxnLoop = codeByteBuffer.position();
// Find next transaction to this AT since the last one (if any)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.PUT_TX_AFTER_TIMESTAMP_INTO_A, addrLastTxnTimestamp));
// If no transaction found, A will be zero. If A is zero, set addrComparator to 1, otherwise 0.
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.CHECK_A_IS_ZERO, addrResult));
// If addrResult is zero (i.e. A is non-zero, transaction was found) then go check transaction
codeByteBuffer.put(OpCode.BZR_DAT.compile(addrResult, calcOffset(codeByteBuffer, labelCheckRedeemTxn)));
// Stop and wait for next block
codeByteBuffer.put(OpCode.STP_IMD.compile());
/* Check transaction */
labelCheckRedeemTxn = codeByteBuffer.position();
// Update our 'last found transaction's timestamp' using 'timestamp' from transaction
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TIMESTAMP_FROM_TX_IN_A, addrLastTxnTimestamp));
// Extract transaction type (message/payment) from transaction and save type in addrTxnType
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(FunctionCode.GET_TYPE_FROM_TX_IN_A, addrTxnType));
// If transaction type is not MESSAGE type then go look for another transaction
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrTxnType, addrMessageTxnType, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
/* Check message payload length */
codeByteBuffer.put(OpCode.EXT_FUN_RET.compile(QortalFunctionCode.GET_MESSAGE_LENGTH_FROM_TX_IN_A.value, addrMessageLength));
// If message length matches, branch to sender checking code
codeByteBuffer.put(OpCode.BEQ_DAT.compile(addrMessageLength, addrExpectedRedeemMessageLength, calcOffset(codeByteBuffer, labelCheckRedeemTxnSender)));
// Message length didn't match - go back to finding another 'redeem' MESSAGE transaction
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelRedeemTxnLoop == null ? 0 : labelRedeemTxnLoop));
/* Check transaction's sender */
labelCheckRedeemTxnSender = codeByteBuffer.position();
// Extract sender address from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_ADDRESS_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrMessageSender1 (as pointed to by addrMessageSenderPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrMessageSenderPointer));
// Compare each part of transaction's sender's address with expected address. If they don't match, look for another transaction.
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender1, addrQortalPartnerAddress1, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender2, addrQortalPartnerAddress2, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender3, addrQortalPartnerAddress3, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
codeByteBuffer.put(OpCode.BNE_DAT.compile(addrMessageSender4, addrQortalPartnerAddress4, calcOffset(codeByteBuffer, labelRedeemTxnLoop)));
/* Check 'secret-A' in transaction's message */
// Extract secret-A from first 32 bytes of message from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN.compile(FunctionCode.PUT_MESSAGE_FROM_TX_IN_A_INTO_B));
// Save B register into data segment starting at addrMessageData (as pointed to by addrMessageDataPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrMessageDataPointer));
// Load B register with expected hash result (as pointed to by addrHashOfSecretAPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.SET_B_IND, addrHashOfSecretAPointer));
// Perform HASH160 using source data at addrMessageData. (Location and length specified via addrMessageDataPointer and addrMessageDataLength).
// Save the equality result (1 if they match, 0 otherwise) into addrResult.
codeByteBuffer.put(OpCode.EXT_FUN_RET_DAT_2.compile(FunctionCode.CHECK_HASH160_WITH_B, addrResult, addrMessageDataPointer, addrMessageDataLength));
// If hashes don't match, addrResult will be zero so go find another transaction
codeByteBuffer.put(OpCode.BNZ_DAT.compile(addrResult, calcOffset(codeByteBuffer, labelPayout)));
codeByteBuffer.put(OpCode.JMP_ADR.compile(labelRedeemTxnLoop == null ? 0 : labelRedeemTxnLoop));
/* Success! Pay arranged amount to receiving address */
labelPayout = codeByteBuffer.position();
// Extract Qortal receiving address from next 32 bytes of message from transaction into B register
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.PUT_PARTIAL_MESSAGE_FROM_TX_IN_A_INTO_B.value, addrRedeemMessageReceivingAddressOffset));
// Save B register into data segment starting at addrPartnerReceivingAddress (as pointed to by addrPartnerReceivingAddressPointer)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerReceivingAddressPointer));
// Pay AT's balance to receiving address
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.PAY_TO_ADDRESS_IN_B, addrQortAmount));
// Set redeemed mode
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.REDEEMED.value));
// We're finished forever (finishing auto-refunds remaining balance to AT creator)
codeByteBuffer.put(OpCode.FIN_IMD.compile());
// Fall-through to refunding any remaining balance back to AT creator
/* Refund balance back to AT creator */
labelRefund = codeByteBuffer.position();
// Set refunded mode
codeByteBuffer.put(OpCode.SET_VAL.compile(addrMode, AcctMode.REFUNDED.value));
// We're finished forever (finishing auto-refunds remaining balance to AT creator)
codeByteBuffer.put(OpCode.FIN_IMD.compile());
} catch (CompilationException e) {
throw new IllegalStateException("Unable to compile RVN-QORT ACCT?", e);
}
}
codeByteBuffer.flip();
byte[] codeBytes = new byte[codeByteBuffer.limit()];
codeByteBuffer.get(codeBytes);
assert Arrays.equals(Crypto.digest(codeBytes), RavencoinACCTv3.CODE_BYTES_HASH)
: String.format("BTCACCT.CODE_BYTES_HASH mismatch: expected %s, actual %s", HashCode.fromBytes(CODE_BYTES_HASH), HashCode.fromBytes(Crypto.digest(codeBytes)));
final short ciyamAtVersion = 2;
final short numCallStackPages = 0;
final short numUserStackPages = 0;
final long minActivationAmount = 0L;
return MachineState.toCreationBytes(ciyamAtVersion, codeBytes, dataByteBuffer.array(), numCallStackPages, numUserStackPages, minActivationAmount);
}
/**
* Returns CrossChainTradeData with useful info extracted from AT.
*/
@Override
public CrossChainTradeData populateTradeData(Repository repository, ATData atData) throws DataException {
ATStateData atStateData = repository.getATRepository().getLatestATState(atData.getATAddress());
return populateTradeData(repository, atData.getCreatorPublicKey(), atData.getCreation(), atStateData);
}
/**
* Returns CrossChainTradeData with useful info extracted from AT.
*/
@Override
public CrossChainTradeData populateTradeData(Repository repository, ATStateData atStateData) throws DataException {
ATData atData = repository.getATRepository().fromATAddress(atStateData.getATAddress());
return populateTradeData(repository, atData.getCreatorPublicKey(), atData.getCreation(), atStateData);
}
/**
* Returns CrossChainTradeData with useful info extracted from AT.
*/
public CrossChainTradeData populateTradeData(Repository repository, byte[] creatorPublicKey, long creationTimestamp, ATStateData atStateData) throws DataException {
byte[] addressBytes = new byte[25]; // for general use
String atAddress = atStateData.getATAddress();
CrossChainTradeData tradeData = new CrossChainTradeData();
tradeData.foreignBlockchain = SupportedBlockchain.RAVENCOIN.name();
tradeData.acctName = NAME;
tradeData.qortalAtAddress = atAddress;
tradeData.qortalCreator = Crypto.toAddress(creatorPublicKey);
tradeData.creationTimestamp = creationTimestamp;
Account atAccount = new Account(repository, atAddress);
tradeData.qortBalance = atAccount.getConfirmedBalance(Asset.QORT);
byte[] stateData = atStateData.getStateData();
ByteBuffer dataByteBuffer = ByteBuffer.wrap(stateData);
dataByteBuffer.position(MachineState.HEADER_LENGTH);
/* Constants */
// Skip creator's trade address
dataByteBuffer.get(addressBytes);
tradeData.qortalCreatorTradeAddress = Base58.encode(addressBytes);
dataByteBuffer.position(dataByteBuffer.position() + 32 - addressBytes.length);
// Creator's Ravencoin/foreign public key hash
tradeData.creatorForeignPKH = new byte[20];
dataByteBuffer.get(tradeData.creatorForeignPKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - tradeData.creatorForeignPKH.length); // skip to 32 bytes
// We don't use secret-B
tradeData.hashOfSecretB = null;
// Redeem payout
tradeData.qortAmount = dataByteBuffer.getLong();
// Expected RVN amount
tradeData.expectedForeignAmount = dataByteBuffer.getLong();
// Trade timeout
tradeData.tradeTimeout = (int) dataByteBuffer.getLong();
// Skip MESSAGE transaction type
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip expected 'trade' message length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip expected 'redeem' message length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to creator's address
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Qortal trade address
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to message sender
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip 'trade' message data offset for partner's Ravencoin PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Ravencoin PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip 'trade' message data offset for hash-of-secret-A
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to hash-of-secret-A
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip 'redeem' message data offset for partner's Qortal receiving address
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to message data
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip message data length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's receiving address
dataByteBuffer.position(dataByteBuffer.position() + 8);
/* End of constants / begin variables */
// Skip AT creator's address
dataByteBuffer.position(dataByteBuffer.position() + 8 * 4);
// Partner's trade address (if present)
dataByteBuffer.get(addressBytes);
String qortalRecipient = Base58.encode(addressBytes);
dataByteBuffer.position(dataByteBuffer.position() + 32 - addressBytes.length);
// Potential lockTimeA (if in trade mode)
int lockTimeA = (int) dataByteBuffer.getLong();
// AT refund timeout (probably only useful for debugging)
int refundTimeout = (int) dataByteBuffer.getLong();
// Trade-mode refund timestamp (AT 'timestamp' converted to Qortal block height)
long tradeRefundTimestamp = dataByteBuffer.getLong();
// Skip last transaction timestamp
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip block timestamp
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip transaction type
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip temporary result
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip temporary message sender
dataByteBuffer.position(dataByteBuffer.position() + 8 * 4);
// Skip message length
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip temporary message data
dataByteBuffer.position(dataByteBuffer.position() + 8 * 4);
// Potential hash160 of secret A
byte[] hashOfSecretA = new byte[20];
dataByteBuffer.get(hashOfSecretA);
dataByteBuffer.position(dataByteBuffer.position() + 32 - hashOfSecretA.length); // skip to 32 bytes
// Potential partner's Ravencoin PKH
byte[] partnerRavencoinPKH = new byte[20];
dataByteBuffer.get(partnerRavencoinPKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerRavencoinPKH.length); // skip to 32 bytes
// Partner's receiving address (if present)
byte[] partnerReceivingAddress = new byte[25];
dataByteBuffer.get(partnerReceivingAddress);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerReceivingAddress.length); // skip to 32 bytes
// Trade AT's 'mode'
long modeValue = dataByteBuffer.getLong();
AcctMode mode = AcctMode.valueOf((int) (modeValue & 0xffL));
/* End of variables */
if (mode != null && mode != AcctMode.OFFERING) {
tradeData.mode = mode;
tradeData.refundTimeout = refundTimeout;
tradeData.tradeRefundHeight = new Timestamp(tradeRefundTimestamp).blockHeight;
tradeData.qortalPartnerAddress = qortalRecipient;
tradeData.hashOfSecretA = hashOfSecretA;
tradeData.partnerForeignPKH = partnerRavencoinPKH;
tradeData.lockTimeA = lockTimeA;
if (mode == AcctMode.REDEEMED)
tradeData.qortalPartnerReceivingAddress = Base58.encode(partnerReceivingAddress);
} else {
tradeData.mode = AcctMode.OFFERING;
}
tradeData.duplicateDeprecated();
return tradeData;
}
/** Returns 'offer' MESSAGE payload for trade partner to send to AT creator's trade address. */
public static byte[] buildOfferMessage(byte[] partnerBitcoinPKH, byte[] hashOfSecretA, int lockTimeA) {
byte[] lockTimeABytes = BitTwiddling.toBEByteArray((long) lockTimeA);
return Bytes.concat(partnerBitcoinPKH, hashOfSecretA, lockTimeABytes);
}
/** Returns info extracted from 'offer' MESSAGE payload sent by trade partner to AT creator's trade address, or null if not valid. */
public static OfferMessageData extractOfferMessageData(byte[] messageData) {
if (messageData == null || messageData.length != OFFER_MESSAGE_LENGTH)
return null;
OfferMessageData offerMessageData = new OfferMessageData();
offerMessageData.partnerRavencoinPKH = Arrays.copyOfRange(messageData, 0, 20);
offerMessageData.hashOfSecretA = Arrays.copyOfRange(messageData, 20, 40);
offerMessageData.lockTimeA = BitTwiddling.longFromBEBytes(messageData, 40);
return offerMessageData;
}
/** Returns 'trade' MESSAGE payload for AT creator to send to AT. */
public static byte[] buildTradeMessage(String partnerQortalTradeAddress, byte[] partnerBitcoinPKH, byte[] hashOfSecretA, int lockTimeA, int refundTimeout) {
byte[] data = new byte[TRADE_MESSAGE_LENGTH];
byte[] partnerQortalAddressBytes = Base58.decode(partnerQortalTradeAddress);
byte[] lockTimeABytes = BitTwiddling.toBEByteArray((long) lockTimeA);
byte[] refundTimeoutBytes = BitTwiddling.toBEByteArray((long) refundTimeout);
System.arraycopy(partnerQortalAddressBytes, 0, data, 0, partnerQortalAddressBytes.length);
System.arraycopy(partnerBitcoinPKH, 0, data, 32, partnerBitcoinPKH.length);
System.arraycopy(refundTimeoutBytes, 0, data, 56, refundTimeoutBytes.length);
System.arraycopy(hashOfSecretA, 0, data, 64, hashOfSecretA.length);
System.arraycopy(lockTimeABytes, 0, data, 88, lockTimeABytes.length);
return data;
}
/** Returns 'cancel' MESSAGE payload for AT creator to cancel trade AT. */
@Override
public byte[] buildCancelMessage(String creatorQortalAddress) {
byte[] data = new byte[CANCEL_MESSAGE_LENGTH];
byte[] creatorQortalAddressBytes = Base58.decode(creatorQortalAddress);
System.arraycopy(creatorQortalAddressBytes, 0, data, 0, creatorQortalAddressBytes.length);
return data;
}
/** Returns 'redeem' MESSAGE payload for trade partner to send to AT. */
public static byte[] buildRedeemMessage(byte[] secretA, String qortalReceivingAddress) {
byte[] data = new byte[REDEEM_MESSAGE_LENGTH];
byte[] qortalReceivingAddressBytes = Base58.decode(qortalReceivingAddress);
System.arraycopy(secretA, 0, data, 0, secretA.length);
System.arraycopy(qortalReceivingAddressBytes, 0, data, 32, qortalReceivingAddressBytes.length);
return data;
}
/** Returns refund timeout (minutes) based on trade partner's 'offer' MESSAGE timestamp and P2SH-A locktime. */
public static int calcRefundTimeout(long offerMessageTimestamp, int lockTimeA) {
// refund should be triggered halfway between offerMessageTimestamp and lockTimeA
return (int) ((lockTimeA - (offerMessageTimestamp / 1000L)) / 2L / 60L);
}
@Override
public byte[] findSecretA(Repository repository, CrossChainTradeData crossChainTradeData) throws DataException {
String atAddress = crossChainTradeData.qortalAtAddress;
String redeemerAddress = crossChainTradeData.qortalPartnerAddress;
// We don't have partner's public key so we check every message to AT
List<MessageTransactionData> messageTransactionsData = repository.getMessageRepository().getMessagesByParticipants(null, atAddress, null, null, null);
if (messageTransactionsData == null)
return null;
// Find 'redeem' message
for (MessageTransactionData messageTransactionData : messageTransactionsData) {
// Check message payload type/encryption
if (messageTransactionData.isText() || messageTransactionData.isEncrypted())
continue;
// Check message payload size
byte[] messageData = messageTransactionData.getData();
if (messageData.length != REDEEM_MESSAGE_LENGTH)
// Wrong payload length
continue;
// Check sender
if (!Crypto.toAddress(messageTransactionData.getSenderPublicKey()).equals(redeemerAddress))
// Wrong sender;
continue;
// Extract secretA
byte[] secretA = new byte[32];
System.arraycopy(messageData, 0, secretA, 0, secretA.length);
byte[] hashOfSecretA = Crypto.hash160(secretA);
if (!Arrays.equals(hashOfSecretA, crossChainTradeData.hashOfSecretA))
continue;
return secretA;
}
return null;
}
}

28
src/main/java/org/qortal/crosschain/SupportedBlockchain.java
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@ -57,6 +57,34 @@ public enum SupportedBlockchain {
public ACCT getLatestAcct() { public ACCT getLatestAcct() {
return DogecoinACCTv3.getInstance(); return DogecoinACCTv3.getInstance();
} }
},
DIGIBYTE(Arrays.asList(
Triple.valueOf(DigibyteACCTv3.NAME, DigibyteACCTv3.CODE_BYTES_HASH, DigibyteACCTv3::getInstance)
)) {
@Override
public ForeignBlockchain getInstance() {
return Digibyte.getInstance();
}
@Override
public ACCT getLatestAcct() {
return DigibyteACCTv3.getInstance();
}
},
RAVENCOIN(Arrays.asList(
Triple.valueOf(RavencoinACCTv3.NAME, RavencoinACCTv3.CODE_BYTES_HASH, RavencoinACCTv3::getInstance)
)) {
@Override
public ForeignBlockchain getInstance() {
return Ravencoin.getInstance();
}
@Override
public ACCT getLatestAcct() {
return RavencoinACCTv3.getInstance();
}
}; };
private static final Map<ByteArray, Supplier<ACCT>> supportedAcctsByCodeHash = Arrays.stream(SupportedBlockchain.values()) private static final Map<ByteArray, Supplier<ACCT>> supportedAcctsByCodeHash = Arrays.stream(SupportedBlockchain.values())

4
src/main/java/org/qortal/network/Network.java
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@ -701,8 +701,8 @@ public class Network {
} }
public boolean connectPeer(Peer newPeer) throws InterruptedException { public boolean connectPeer(Peer newPeer) throws InterruptedException {
// NOT CORRECT: // Also checked before creating PeerConnectTask
if (getImmutableConnectedPeers().size() >= minOutboundPeers) if (getImmutableOutboundHandshakedPeers().size() >= minOutboundPeers)
return false; return false;
SocketChannel socketChannel = newPeer.connect(); SocketChannel socketChannel = newPeer.connect();

12
src/main/java/org/qortal/settings/Settings.java
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@ -26,6 +26,8 @@ import org.qortal.controller.arbitrary.ArbitraryDataStorageManager.*;
import org.qortal.crosschain.Bitcoin.BitcoinNet; import org.qortal.crosschain.Bitcoin.BitcoinNet;
import org.qortal.crosschain.Litecoin.LitecoinNet; import org.qortal.crosschain.Litecoin.LitecoinNet;
import org.qortal.crosschain.Dogecoin.DogecoinNet; import org.qortal.crosschain.Dogecoin.DogecoinNet;
import org.qortal.crosschain.Digibyte.DigibyteNet;
import org.qortal.crosschain.Ravencoin.RavencoinNet;
import org.qortal.utils.EnumUtils; import org.qortal.utils.EnumUtils;
// All properties to be converted to JSON via JAXB // All properties to be converted to JSON via JAXB
@ -224,6 +226,8 @@ public class Settings {
private BitcoinNet bitcoinNet = BitcoinNet.MAIN; private BitcoinNet bitcoinNet = BitcoinNet.MAIN;
private LitecoinNet litecoinNet = LitecoinNet.MAIN; private LitecoinNet litecoinNet = LitecoinNet.MAIN;
private DogecoinNet dogecoinNet = DogecoinNet.MAIN; private DogecoinNet dogecoinNet = DogecoinNet.MAIN;
private DigibyteNet digibyteNet = DigibyteNet.MAIN;
private RavencoinNet ravencoinNet = RavencoinNet.MAIN;
// Also crosschain-related: // Also crosschain-related:
/** Whether to show SysTray pop-up notifications when trade-bot entries change state */ /** Whether to show SysTray pop-up notifications when trade-bot entries change state */
private boolean tradebotSystrayEnabled = false; private boolean tradebotSystrayEnabled = false;
@ -682,6 +686,14 @@ public class Settings {
return this.dogecoinNet; return this.dogecoinNet;
} }
public DigibyteNet getDigibyteNet() {
return this.digibyteNet;
}
public RavencoinNet getRavencoinNet() {
return this.ravencoinNet;
}
public boolean isTradebotSystrayEnabled() { public boolean isTradebotSystrayEnabled() {
return this.tradebotSystrayEnabled; return this.tradebotSystrayEnabled;
} }

115
src/test/java/org/qortal/test/crosschain/DigibyteTests.java Normal file
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@ -0,0 +1,115 @@
package org.qortal.test.crosschain;
import static org.junit.Assert.*;
import java.util.Arrays;
import org.bitcoinj.core.Transaction;
import org.bitcoinj.store.BlockStoreException;
import org.junit.After;
import org.junit.Before;
import org.junit.Ignore;
import org.junit.Test;
import org.qortal.crosschain.ForeignBlockchainException;
import org.qortal.crosschain.Digibyte;
import org.qortal.crosschain.BitcoinyHTLC;
import org.qortal.repository.DataException;
import org.qortal.test.common.Common;
public class DigibyteTests extends Common {
private Digibyte digibyte;
@Before
public void beforeTest() throws DataException {
Common.useDefaultSettings(); // TestNet3
digibyte = Digibyte.getInstance();
}
@After
public void afterTest() {
Digibyte.resetForTesting();
digibyte = null;
}
@Test
public void testGetMedianBlockTime() throws BlockStoreException, ForeignBlockchainException {
long before = System.currentTimeMillis();
System.out.println(String.format("Digibyte median blocktime: %d", digibyte.getMedianBlockTime()));
long afterFirst = System.currentTimeMillis();
System.out.println(String.format("Digibyte median blocktime: %d", digibyte.getMedianBlockTime()));
long afterSecond = System.currentTimeMillis();
long firstPeriod = afterFirst - before;
long secondPeriod = afterSecond - afterFirst;
System.out.println(String.format("1st call: %d ms, 2nd call: %d ms", firstPeriod, secondPeriod));
assertTrue("2nd call should be quicker than 1st", secondPeriod < firstPeriod);
assertTrue("2nd call should take less than 5 seconds", secondPeriod < 5000L);
}
@Test
@Ignore(value = "Doesn't work, to be fixed later")
public void testFindHtlcSecret() throws ForeignBlockchainException {
// This actually exists on TEST3 but can take a while to fetch
String p2shAddress = "2N8WCg52ULCtDSMjkgVTm5mtPdCsUptkHWE";
byte[] expectedSecret = "This string is exactly 32 bytes!".getBytes();
byte[] secret = BitcoinyHTLC.findHtlcSecret(digibyte, p2shAddress);
assertNotNull("secret not found", secret);
assertTrue("secret incorrect", Arrays.equals(expectedSecret, secret));
}
@Test
@Ignore(value = "No testnet nodes available, so we can't regularly test buildSpend yet")
public void testBuildSpend() {
String xprv58 = "tprv8ZgxMBicQKsPdahhFSrCdvC1bsWyzHHZfTneTVqUXN6s1wEtZLwAkZXzFP6TYLg2aQMecZLXLre5bTVGajEB55L1HYJcawpdFG66STVAWPJ";
String recipient = "2N8WCg52ULCtDSMjkgVTm5mtPdCsUptkHWE";
long amount = 1000L;
Transaction transaction = digibyte.buildSpend(xprv58, recipient, amount);
assertNotNull("insufficient funds", transaction);
// Check spent key caching doesn't affect outcome
transaction = digibyte.buildSpend(xprv58, recipient, amount);
assertNotNull("insufficient funds", transaction);
}
@Test
public void testGetWalletBalance() {
String xprv58 = "tprv8ZgxMBicQKsPdahhFSrCdvC1bsWyzHHZfTneTVqUXN6s1wEtZLwAkZXzFP6TYLg2aQMecZLXLre5bTVGajEB55L1HYJcawpdFG66STVAWPJ";
Long balance = digibyte.getWalletBalance(xprv58);
assertNotNull(balance);
System.out.println(digibyte.format(balance));
// Check spent key caching doesn't affect outcome
Long repeatBalance = digibyte.getWalletBalance(xprv58);
assertNotNull(repeatBalance);
System.out.println(digibyte.format(repeatBalance));
assertEquals(balance, repeatBalance);
}
@Test
public void testGetUnusedReceiveAddress() throws ForeignBlockchainException {
String xprv58 = "tprv8ZgxMBicQKsPdahhFSrCdvC1bsWyzHHZfTneTVqUXN6s1wEtZLwAkZXzFP6TYLg2aQMecZLXLre5bTVGajEB55L1HYJcawpdFG66STVAWPJ";
String address = digibyte.getUnusedReceiveAddress(xprv58);
assertNotNull(address);
System.out.println(address);
}
}

115
src/test/java/org/qortal/test/crosschain/RavencoinTests.java Normal file
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@ -0,0 +1,115 @@
package org.qortal.test.crosschain;
import static org.junit.Assert.*;
import java.util.Arrays;
import org.bitcoinj.core.Transaction;
import org.bitcoinj.store.BlockStoreException;
import org.junit.After;
import org.junit.Before;
import org.junit.Ignore;
import org.junit.Test;
import org.qortal.crosschain.ForeignBlockchainException;
import org.qortal.crosschain.Ravencoin;
import org.qortal.crosschain.BitcoinyHTLC;
import org.qortal.repository.DataException;
import org.qortal.test.common.Common;
public class RavencoinTests extends Common {
private Ravencoin ravencoin;
@Before
public void beforeTest() throws DataException {
Common.useDefaultSettings(); // TestNet3
ravencoin = Ravencoin.getInstance();
}
@After
public void afterTest() {
Ravencoin.resetForTesting();
ravencoin = null;
}
@Test
public void testGetMedianBlockTime() throws BlockStoreException, ForeignBlockchainException {
long before = System.currentTimeMillis();
System.out.println(String.format("Ravencoin median blocktime: %d", ravencoin.getMedianBlockTime()));
long afterFirst = System.currentTimeMillis();
System.out.println(String.format("Ravencoin median blocktime: %d", ravencoin.getMedianBlockTime()));
long afterSecond = System.currentTimeMillis();
long firstPeriod = afterFirst - before;
long secondPeriod = afterSecond - afterFirst;
System.out.println(String.format("1st call: %d ms, 2nd call: %d ms", firstPeriod, secondPeriod));
assertTrue("2nd call should be quicker than 1st", secondPeriod < firstPeriod);
assertTrue("2nd call should take less than 5 seconds", secondPeriod < 5000L);
}
@Test
@Ignore(value = "Doesn't work, to be fixed later")
public void testFindHtlcSecret() throws ForeignBlockchainException {
// This actually exists on TEST3 but can take a while to fetch
String p2shAddress = "2N8WCg52ULCtDSMjkgVTm5mtPdCsUptkHWE";
byte[] expectedSecret = "This string is exactly 32 bytes!".getBytes();
byte[] secret = BitcoinyHTLC.findHtlcSecret(ravencoin, p2shAddress);
assertNotNull("secret not found", secret);
assertTrue("secret incorrect", Arrays.equals(expectedSecret, secret));
}
@Test
@Ignore(value = "No testnet nodes available, so we can't regularly test buildSpend yet")
public void testBuildSpend() {
String xprv58 = "tprv8ZgxMBicQKsPdahhFSrCdvC1bsWyzHHZfTneTVqUXN6s1wEtZLwAkZXzFP6TYLg2aQMecZLXLre5bTVGajEB55L1HYJcawpdFG66STVAWPJ";
String recipient = "2N8WCg52ULCtDSMjkgVTm5mtPdCsUptkHWE";
long amount = 1000L;
Transaction transaction = ravencoin.buildSpend(xprv58, recipient, amount);
assertNotNull("insufficient funds", transaction);
// Check spent key caching doesn't affect outcome
transaction = ravencoin.buildSpend(xprv58, recipient, amount);
assertNotNull("insufficient funds", transaction);
}
@Test
public void testGetWalletBalance() {
String xprv58 = "tprv8ZgxMBicQKsPdahhFSrCdvC1bsWyzHHZfTneTVqUXN6s1wEtZLwAkZXzFP6TYLg2aQMecZLXLre5bTVGajEB55L1HYJcawpdFG66STVAWPJ";
Long balance = ravencoin.getWalletBalance(xprv58);
assertNotNull(balance);
System.out.println(ravencoin.format(balance));
// Check spent key caching doesn't affect outcome
Long repeatBalance = ravencoin.getWalletBalance(xprv58);
assertNotNull(repeatBalance);
System.out.println(ravencoin.format(repeatBalance));
assertEquals(balance, repeatBalance);
}
@Test
public void testGetUnusedReceiveAddress() throws ForeignBlockchainException {
String xprv58 = "tprv8ZgxMBicQKsPdahhFSrCdvC1bsWyzHHZfTneTVqUXN6s1wEtZLwAkZXzFP6TYLg2aQMecZLXLre5bTVGajEB55L1HYJcawpdFG66STVAWPJ";
String address = ravencoin.getUnusedReceiveAddress(xprv58);
assertNotNull(address);
System.out.println(address);
}
}

769
src/test/java/org/qortal/test/crosschain/digibytev3/DigibyteACCTv3Tests.java Normal file
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@ -0,0 +1,769 @@
package org.qortal.test.crosschain.digibytev3;
import com.google.common.hash.HashCode;
import com.google.common.primitives.Bytes;
import org.junit.Before;
import org.junit.Test;
import org.qortal.account.Account;
import org.qortal.account.PrivateKeyAccount;
import org.qortal.asset.Asset;
import org.qortal.block.Block;
import org.qortal.crosschain.AcctMode;
import org.qortal.crosschain.DigibyteACCTv3;
import org.qortal.crypto.Crypto;
import org.qortal.data.at.ATData;
import org.qortal.data.at.ATStateData;
import org.qortal.data.crosschain.CrossChainTradeData;
import org.qortal.data.transaction.BaseTransactionData;
import org.qortal.data.transaction.DeployAtTransactionData;
import org.qortal.data.transaction.MessageTransactionData;
import org.qortal.data.transaction.TransactionData;
import org.qortal.group.Group;
import org.qortal.repository.DataException;
import org.qortal.repository.Repository;
import org.qortal.repository.RepositoryManager;
import org.qortal.test.common.BlockUtils;
import org.qortal.test.common.Common;
import org.qortal.test.common.TransactionUtils;
import org.qortal.transaction.DeployAtTransaction;
import org.qortal.transaction.MessageTransaction;
import org.qortal.utils.Amounts;
import java.time.Instant;
import java.time.LocalDateTime;
import java.time.ZoneOffset;
import java.time.format.DateTimeFormatter;
import java.time.format.FormatStyle;
import java.util.Arrays;
import java.util.List;
import java.util.Random;
import java.util.function.Function;
import static org.junit.Assert.*;
public class DigibyteACCTv3Tests extends Common {
public static final byte[] secretA = "This string is exactly 32 bytes!".getBytes();
public static final byte[] hashOfSecretA = Crypto.hash160(secretA); // daf59884b4d1aec8c1b17102530909ee43c0151a
public static final byte[] digibytePublicKeyHash = HashCode.fromString("bb00bb11bb22bb33bb44bb55bb66bb77bb88bb99").asBytes();
public static final int tradeTimeout = 20; // blocks
public static final long redeemAmount = 80_40200000L;
public static final long fundingAmount = 123_45600000L;
public static final long digibyteAmount = 864200L; // 0.00864200 DGB
private static final Random RANDOM = new Random();
@Before
public void beforeTest() throws DataException {
Common.useDefaultSettings();
}
@Test
public void testCompile() {
PrivateKeyAccount tradeAccount = createTradeAccount(null);
byte[] creationBytes = DigibyteACCTv3.buildQortalAT(tradeAccount.getAddress(), digibytePublicKeyHash, redeemAmount, digibyteAmount, tradeTimeout);
assertNotNull(creationBytes);
System.out.println("AT creation bytes: " + HashCode.fromBytes(creationBytes).toString());
}
@Test
public void testDeploy() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
long expectedBalance = deployersInitialBalance - fundingAmount - deployAtTransaction.getTransactionData().getFee();
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = fundingAmount;
actualBalance = deployAtTransaction.getATAccount().getConfirmedBalance(Asset.QORT);
assertEquals("AT's post-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = partnersInitialBalance;
actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-deployment balance incorrect", expectedBalance, actualBalance);
// Test orphaning
BlockUtils.orphanLastBlock(repository);
expectedBalance = deployersInitialBalance;
actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = 0;
actualBalance = deployAtTransaction.getATAccount().getConfirmedBalance(Asset.QORT);
assertEquals("AT's post-orphan/pre-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = partnersInitialBalance;
actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-orphan/pre-deployment balance incorrect", expectedBalance, actualBalance);
}
}
@SuppressWarnings("unused")
@Test
public void testOfferCancel() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
// Send creator's address to AT, instead of typical partner's address
byte[] messageData = DigibyteACCTv3.getInstance().buildCancelMessage(deployer.getAddress());
MessageTransaction messageTransaction = sendMessage(repository, deployer, messageData, atAddress);
long messageFee = messageTransaction.getTransactionData().getFee();
// AT should process 'cancel' message in next block
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in CANCELLED mode
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.CANCELLED, tradeData.mode);
// Check balances
long expectedMinimumBalance = deployersPostDeploymentBalance;
long expectedMaximumBalance = deployersInitialBalance - deployAtFee - messageFee;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertTrue(String.format("Deployer's balance %s should be above minimum %s", actualBalance, expectedMinimumBalance), actualBalance > expectedMinimumBalance);
assertTrue(String.format("Deployer's balance %s should be below maximum %s", actualBalance, expectedMaximumBalance), actualBalance < expectedMaximumBalance);
// Test orphaning
BlockUtils.orphanLastBlock(repository);
// Check balances
long expectedBalance = deployersPostDeploymentBalance - messageFee;
actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-refund balance incorrect", expectedBalance, actualBalance);
}
}
@SuppressWarnings("unused")
@Test
public void testOfferCancelInvalidLength() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
// Instead of sending creator's address to AT, send too-short/invalid message
byte[] messageData = new byte[7];
RANDOM.nextBytes(messageData);
MessageTransaction messageTransaction = sendMessage(repository, deployer, messageData, atAddress);
long messageFee = messageTransaction.getTransactionData().getFee();
// AT should process 'cancel' message in next block
// As message is too short, it will be padded to 32bytes but cancel code doesn't care about message content, so should be ok
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in CANCELLED mode
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.CANCELLED, tradeData.mode);
}
}
@SuppressWarnings("unused")
@Test
public void testTradingInfoProcessing() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DigibyteACCTv3.buildTradeMessage(partner.getAddress(), digibytePublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
Block postDeploymentBlock = BlockUtils.mintBlock(repository);
int postDeploymentBlockHeight = postDeploymentBlock.getBlockData().getHeight();
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
describeAt(repository, atAddress);
ATData atData = repository.getATRepository().fromATAddress(atAddress);
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
// AT should be in TRADE mode
assertEquals(AcctMode.TRADING, tradeData.mode);
// Check hashOfSecretA was extracted correctly
assertTrue(Arrays.equals(hashOfSecretA, tradeData.hashOfSecretA));
// Check trade partner Qortal address was extracted correctly
assertEquals(partner.getAddress(), tradeData.qortalPartnerAddress);
// Check trade partner's digibyte PKH was extracted correctly
assertTrue(Arrays.equals(digibytePublicKeyHash, tradeData.partnerForeignPKH));
// Test orphaning
BlockUtils.orphanToBlock(repository, postDeploymentBlockHeight);
// Check balances
long expectedBalance = deployersPostDeploymentBalance;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-refund balance incorrect", expectedBalance, actualBalance);
}
}
// TEST SENDING TRADING INFO BUT NOT FROM AT CREATOR (SHOULD BE IGNORED)
@SuppressWarnings("unused")
@Test
public void testIncorrectTradeSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
PrivateKeyAccount bystander = Common.getTestAccount(repository, "bob");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT BUT NOT FROM AT CREATOR
byte[] messageData = DigibyteACCTv3.buildTradeMessage(partner.getAddress(), digibytePublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, bystander, messageData, atAddress);
BlockUtils.mintBlock(repository);
long expectedBalance = partnersInitialBalance;
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-initial-payout balance incorrect", expectedBalance, actualBalance);
describeAt(repository, atAddress);
ATData atData = repository.getATRepository().fromATAddress(atAddress);
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
// AT should still be in OFFER mode
assertEquals(AcctMode.OFFERING, tradeData.mode);
}
}
@SuppressWarnings("unused")
@Test
public void testAutomaticTradeRefund() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DigibyteACCTv3.buildTradeMessage(partner.getAddress(), digibytePublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
Block postDeploymentBlock = BlockUtils.mintBlock(repository);
int postDeploymentBlockHeight = postDeploymentBlock.getBlockData().getHeight();
// Check refund
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
checkTradeRefund(repository, deployer, deployersInitialBalance, deployAtFee);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in REFUNDED mode
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.REFUNDED, tradeData.mode);
// Test orphaning
BlockUtils.orphanToBlock(repository, postDeploymentBlockHeight);
// Check balances
long expectedBalance = deployersPostDeploymentBalance;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-refund balance incorrect", expectedBalance, actualBalance);
}
}
@SuppressWarnings("unused")
@Test
public void testCorrectSecretCorrectSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DigibyteACCTv3.buildTradeMessage(partner.getAddress(), digibytePublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send correct secret to AT, from correct account
messageData = DigibyteACCTv3.buildRedeemMessage(secretA, partner.getAddress());
messageTransaction = sendMessage(repository, partner, messageData, atAddress);
// AT should send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in REDEEMED mode
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.REDEEMED, tradeData.mode);
// Check balances
long expectedBalance = partnersInitialBalance - messageTransaction.getTransactionData().getFee() + redeemAmount;
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-redeem balance incorrect", expectedBalance, actualBalance);
// Orphan redeem
BlockUtils.orphanLastBlock(repository);
// Check balances
expectedBalance = partnersInitialBalance - messageTransaction.getTransactionData().getFee();
actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-orphan/pre-redeem balance incorrect", expectedBalance, actualBalance);
// Check AT state
ATStateData postOrphanAtStateData = repository.getATRepository().getLatestATState(atAddress);
assertTrue("AT states mismatch", Arrays.equals(preRedeemAtStateData.getStateData(), postOrphanAtStateData.getStateData()));
}
}
@SuppressWarnings("unused")
@Test
public void testCorrectSecretIncorrectSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
PrivateKeyAccount bystander = Common.getTestAccount(repository, "bob");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DigibyteACCTv3.buildTradeMessage(partner.getAddress(), digibytePublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send correct secret to AT, but from wrong account
messageData = DigibyteACCTv3.buildRedeemMessage(secretA, partner.getAddress());
messageTransaction = sendMessage(repository, bystander, messageData, atAddress);
// AT should NOT send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is NOT finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertFalse(atData.getIsFinished());
// AT should still be in TRADE mode
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.TRADING, tradeData.mode);
// Check balances
long expectedBalance = partnersInitialBalance;
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's balance incorrect", expectedBalance, actualBalance);
// Check eventual refund
checkTradeRefund(repository, deployer, deployersInitialBalance, deployAtFee);
}
}
@SuppressWarnings("unused")
@Test
public void testIncorrectSecretCorrectSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DigibyteACCTv3.buildTradeMessage(partner.getAddress(), digibytePublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send incorrect secret to AT, from correct account
byte[] wrongSecret = new byte[32];
RANDOM.nextBytes(wrongSecret);
messageData = DigibyteACCTv3.buildRedeemMessage(wrongSecret, partner.getAddress());
messageTransaction = sendMessage(repository, partner, messageData, atAddress);
// AT should NOT send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is NOT finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertFalse(atData.getIsFinished());
// AT should still be in TRADE mode
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.TRADING, tradeData.mode);
long expectedBalance = partnersInitialBalance - messageTransaction.getTransactionData().getFee();
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's balance incorrect", expectedBalance, actualBalance);
// Check eventual refund
checkTradeRefund(repository, deployer, deployersInitialBalance, deployAtFee);
}
}
@SuppressWarnings("unused")
@Test
public void testCorrectSecretCorrectSenderInvalidMessageLength() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = DigibyteACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DigibyteACCTv3.buildTradeMessage(partner.getAddress(), digibytePublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send correct secret to AT, from correct account, but missing receive address, hence incorrect length
messageData = Bytes.concat(secretA);
messageTransaction = sendMessage(repository, partner, messageData, atAddress);
// AT should NOT send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is NOT finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertFalse(atData.getIsFinished());
// AT should be in TRADING mode
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.TRADING, tradeData.mode);
}
}
@SuppressWarnings("unused")
@Test
public void testDescribeDeployed() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
List<ATData> executableAts = repository.getATRepository().getAllExecutableATs();
for (ATData atData : executableAts) {
String atAddress = atData.getATAddress();
byte[] codeBytes = atData.getCodeBytes();
byte[] codeHash = Crypto.digest(codeBytes);
System.out.println(String.format("%s: code length: %d byte%s, code hash: %s",
atAddress,
codeBytes.length,
(codeBytes.length != 1 ? "s": ""),
HashCode.fromBytes(codeHash)));
// Not one of ours?
if (!Arrays.equals(codeHash, DigibyteACCTv3.CODE_BYTES_HASH))
continue;
describeAt(repository, atAddress);
}
}
}
private int calcTestLockTimeA(long messageTimestamp) {
return (int) (messageTimestamp / 1000L + tradeTimeout * 60);
}
private DeployAtTransaction doDeploy(Repository repository, PrivateKeyAccount deployer, String tradeAddress) throws DataException {
byte[] creationBytes = DigibyteACCTv3.buildQortalAT(tradeAddress, digibytePublicKeyHash, redeemAmount, digibyteAmount, tradeTimeout);
long txTimestamp = System.currentTimeMillis();
byte[] lastReference = deployer.getLastReference();
if (lastReference == null) {
System.err.println(String.format("Qortal account %s has no last reference", deployer.getAddress()));
System.exit(2);
}
Long fee = null;
String name = "QORT-DGB cross-chain trade";
String description = String.format("Qortal-Digibyte cross-chain trade");
String atType = "ACCT";
String tags = "QORT-DGB ACCT";
BaseTransactionData baseTransactionData = new BaseTransactionData(txTimestamp, Group.NO_GROUP, lastReference, deployer.getPublicKey(), fee, null);
TransactionData deployAtTransactionData = new DeployAtTransactionData(baseTransactionData, name, description, atType, tags, creationBytes, fundingAmount, Asset.QORT);
DeployAtTransaction deployAtTransaction = new DeployAtTransaction(repository, deployAtTransactionData);
fee = deployAtTransaction.calcRecommendedFee();
deployAtTransactionData.setFee(fee);
TransactionUtils.signAndMint(repository, deployAtTransactionData, deployer);
return deployAtTransaction;
}
private MessageTransaction sendMessage(Repository repository, PrivateKeyAccount sender, byte[] data, String recipient) throws DataException {
long txTimestamp = System.currentTimeMillis();
byte[] lastReference = sender.getLastReference();
if (lastReference == null) {
System.err.println(String.format("Qortal account %s has no last reference", sender.getAddress()));
System.exit(2);
}
Long fee = null;
int version = 4;
int nonce = 0;
long amount = 0;
Long assetId = null; // because amount is zero
BaseTransactionData baseTransactionData = new BaseTransactionData(txTimestamp, Group.NO_GROUP, lastReference, sender.getPublicKey(), fee, null);
TransactionData messageTransactionData = new MessageTransactionData(baseTransactionData, version, nonce, recipient, amount, assetId, data, false, false);
MessageTransaction messageTransaction = new MessageTransaction(repository, messageTransactionData);
fee = messageTransaction.calcRecommendedFee();
messageTransactionData.setFee(fee);
TransactionUtils.signAndMint(repository, messageTransactionData, sender);
return messageTransaction;
}
private void checkTradeRefund(Repository repository, Account deployer, long deployersInitialBalance, long deployAtFee) throws DataException {
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
int refundTimeout = tradeTimeout / 2 + 1; // close enough
// AT should automatically refund deployer after 'refundTimeout' blocks
for (int blockCount = 0; blockCount <= refundTimeout; ++blockCount)
BlockUtils.mintBlock(repository);
// We don't bother to exactly calculate QORT spent running AT for several blocks, but we do know the expected range
long expectedMinimumBalance = deployersPostDeploymentBalance;
long expectedMaximumBalance = deployersInitialBalance - deployAtFee;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertTrue(String.format("Deployer's balance %s should be above minimum %s", actualBalance, expectedMinimumBalance), actualBalance > expectedMinimumBalance);
assertTrue(String.format("Deployer's balance %s should be below maximum %s", actualBalance, expectedMaximumBalance), actualBalance < expectedMaximumBalance);
}
private void describeAt(Repository repository, String atAddress) throws DataException {
ATData atData = repository.getATRepository().fromATAddress(atAddress);
CrossChainTradeData tradeData = DigibyteACCTv3.getInstance().populateTradeData(repository, atData);
Function<Long, String> epochMilliFormatter = (timestamp) -> LocalDateTime.ofInstant(Instant.ofEpochMilli(timestamp), ZoneOffset.UTC).format(DateTimeFormatter.ofLocalizedDateTime(FormatStyle.MEDIUM));
int currentBlockHeight = repository.getBlockRepository().getBlockchainHeight();
System.out.print(String.format("%s:\n"
+ "\tmode: %s\n"
+ "\tcreator: %s,\n"
+ "\tcreation timestamp: %s,\n"
+ "\tcurrent balance: %s QORT,\n"
+ "\tis finished: %b,\n"
+ "\tredeem payout: %s QORT,\n"
+ "\texpected digibyte: %s DGB,\n"
+ "\tcurrent block height: %d,\n",
tradeData.qortalAtAddress,
tradeData.mode,
tradeData.qortalCreator,
epochMilliFormatter.apply(tradeData.creationTimestamp),
Amounts.prettyAmount(tradeData.qortBalance),
atData.getIsFinished(),
Amounts.prettyAmount(tradeData.qortAmount),
Amounts.prettyAmount(tradeData.expectedForeignAmount),
currentBlockHeight));
if (tradeData.mode != AcctMode.OFFERING && tradeData.mode != AcctMode.CANCELLED) {
System.out.println(String.format("\trefund timeout: %d minutes,\n"
+ "\trefund height: block %d,\n"
+ "\tHASH160 of secret-A: %s,\n"
+ "\tDigibyte P2SH-A nLockTime: %d (%s),\n"
+ "\ttrade partner: %s\n"
+ "\tpartner's receiving address: %s",
tradeData.refundTimeout,
tradeData.tradeRefundHeight,
HashCode.fromBytes(tradeData.hashOfSecretA).toString().substring(0, 40),
tradeData.lockTimeA, epochMilliFormatter.apply(tradeData.lockTimeA * 1000L),
tradeData.qortalPartnerAddress,
tradeData.qortalPartnerReceivingAddress));
}
}
private PrivateKeyAccount createTradeAccount(Repository repository) {
// We actually use a known test account with funds to avoid PoW compute
return Common.getTestAccount(repository, "alice");
}
}

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package org.qortal.test.crosschain.ravencoinv3;
import com.google.common.hash.HashCode;
import com.google.common.primitives.Bytes;
import org.junit.Before;
import org.junit.Test;
import org.qortal.account.Account;
import org.qortal.account.PrivateKeyAccount;
import org.qortal.asset.Asset;
import org.qortal.block.Block;
import org.qortal.crosschain.AcctMode;
import org.qortal.crosschain.RavencoinACCTv3;
import org.qortal.crypto.Crypto;
import org.qortal.data.at.ATData;
import org.qortal.data.at.ATStateData;
import org.qortal.data.crosschain.CrossChainTradeData;
import org.qortal.data.transaction.BaseTransactionData;
import org.qortal.data.transaction.DeployAtTransactionData;
import org.qortal.data.transaction.MessageTransactionData;
import org.qortal.data.transaction.TransactionData;
import org.qortal.group.Group;
import org.qortal.repository.DataException;
import org.qortal.repository.Repository;
import org.qortal.repository.RepositoryManager;
import org.qortal.test.common.BlockUtils;
import org.qortal.test.common.Common;
import org.qortal.test.common.TransactionUtils;
import org.qortal.transaction.DeployAtTransaction;
import org.qortal.transaction.MessageTransaction;
import org.qortal.utils.Amounts;
import java.time.Instant;
import java.time.LocalDateTime;
import java.time.ZoneOffset;
import java.time.format.DateTimeFormatter;
import java.time.format.FormatStyle;
import java.util.Arrays;
import java.util.List;
import java.util.Random;
import java.util.function.Function;
import static org.junit.Assert.*;
public class RavencoinACCTv3Tests extends Common {
public static final byte[] secretA = "This string is exactly 32 bytes!".getBytes();
public static final byte[] hashOfSecretA = Crypto.hash160(secretA); // daf59884b4d1aec8c1b17102530909ee43c0151a
public static final byte[] ravencoinPublicKeyHash = HashCode.fromString("bb00bb11bb22bb33bb44bb55bb66bb77bb88bb99").asBytes();
public static final int tradeTimeout = 20; // blocks
public static final long redeemAmount = 80_40200000L;
public static final long fundingAmount = 123_45600000L;
public static final long ravencoinAmount = 864200L; // 0.00864200 RVN
private static final Random RANDOM = new Random();
@Before
public void beforeTest() throws DataException {
Common.useDefaultSettings();
}
@Test
public void testCompile() {
PrivateKeyAccount tradeAccount = createTradeAccount(null);
byte[] creationBytes = RavencoinACCTv3.buildQortalAT(tradeAccount.getAddress(), ravencoinPublicKeyHash, redeemAmount, ravencoinAmount, tradeTimeout);
assertNotNull(creationBytes);
System.out.println("AT creation bytes: " + HashCode.fromBytes(creationBytes).toString());
}
@Test
public void testDeploy() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
long expectedBalance = deployersInitialBalance - fundingAmount - deployAtTransaction.getTransactionData().getFee();
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = fundingAmount;
actualBalance = deployAtTransaction.getATAccount().getConfirmedBalance(Asset.QORT);
assertEquals("AT's post-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = partnersInitialBalance;
actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-deployment balance incorrect", expectedBalance, actualBalance);
// Test orphaning
BlockUtils.orphanLastBlock(repository);
expectedBalance = deployersInitialBalance;
actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = 0;
actualBalance = deployAtTransaction.getATAccount().getConfirmedBalance(Asset.QORT);
assertEquals("AT's post-orphan/pre-deployment balance incorrect", expectedBalance, actualBalance);
expectedBalance = partnersInitialBalance;
actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-orphan/pre-deployment balance incorrect", expectedBalance, actualBalance);
}
}
@SuppressWarnings("unused")
@Test
public void testOfferCancel() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
// Send creator's address to AT, instead of typical partner's address
byte[] messageData = RavencoinACCTv3.getInstance().buildCancelMessage(deployer.getAddress());
MessageTransaction messageTransaction = sendMessage(repository, deployer, messageData, atAddress);
long messageFee = messageTransaction.getTransactionData().getFee();
// AT should process 'cancel' message in next block
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in CANCELLED mode
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.CANCELLED, tradeData.mode);
// Check balances
long expectedMinimumBalance = deployersPostDeploymentBalance;
long expectedMaximumBalance = deployersInitialBalance - deployAtFee - messageFee;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertTrue(String.format("Deployer's balance %s should be above minimum %s", actualBalance, expectedMinimumBalance), actualBalance > expectedMinimumBalance);
assertTrue(String.format("Deployer's balance %s should be below maximum %s", actualBalance, expectedMaximumBalance), actualBalance < expectedMaximumBalance);
// Test orphaning
BlockUtils.orphanLastBlock(repository);
// Check balances
long expectedBalance = deployersPostDeploymentBalance - messageFee;
actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-refund balance incorrect", expectedBalance, actualBalance);
}
}
@SuppressWarnings("unused")
@Test
public void testOfferCancelInvalidLength() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
// Instead of sending creator's address to AT, send too-short/invalid message
byte[] messageData = new byte[7];
RANDOM.nextBytes(messageData);
MessageTransaction messageTransaction = sendMessage(repository, deployer, messageData, atAddress);
long messageFee = messageTransaction.getTransactionData().getFee();
// AT should process 'cancel' message in next block
// As message is too short, it will be padded to 32bytes but cancel code doesn't care about message content, so should be ok
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in CANCELLED mode
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.CANCELLED, tradeData.mode);
}
}
@SuppressWarnings("unused")
@Test
public void testTradingInfoProcessing() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = RavencoinACCTv3.buildTradeMessage(partner.getAddress(), ravencoinPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
Block postDeploymentBlock = BlockUtils.mintBlock(repository);
int postDeploymentBlockHeight = postDeploymentBlock.getBlockData().getHeight();
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
describeAt(repository, atAddress);
ATData atData = repository.getATRepository().fromATAddress(atAddress);
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
// AT should be in TRADE mode
assertEquals(AcctMode.TRADING, tradeData.mode);
// Check hashOfSecretA was extracted correctly
assertTrue(Arrays.equals(hashOfSecretA, tradeData.hashOfSecretA));
// Check trade partner Qortal address was extracted correctly
assertEquals(partner.getAddress(), tradeData.qortalPartnerAddress);
// Check trade partner's ravencoin PKH was extracted correctly
assertTrue(Arrays.equals(ravencoinPublicKeyHash, tradeData.partnerForeignPKH));
// Test orphaning
BlockUtils.orphanToBlock(repository, postDeploymentBlockHeight);
// Check balances
long expectedBalance = deployersPostDeploymentBalance;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-refund balance incorrect", expectedBalance, actualBalance);
}
}
// TEST SENDING TRADING INFO BUT NOT FROM AT CREATOR (SHOULD BE IGNORED)
@SuppressWarnings("unused")
@Test
public void testIncorrectTradeSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
PrivateKeyAccount bystander = Common.getTestAccount(repository, "bob");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT BUT NOT FROM AT CREATOR
byte[] messageData = RavencoinACCTv3.buildTradeMessage(partner.getAddress(), ravencoinPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, bystander, messageData, atAddress);
BlockUtils.mintBlock(repository);
long expectedBalance = partnersInitialBalance;
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-initial-payout balance incorrect", expectedBalance, actualBalance);
describeAt(repository, atAddress);
ATData atData = repository.getATRepository().fromATAddress(atAddress);
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
// AT should still be in OFFER mode
assertEquals(AcctMode.OFFERING, tradeData.mode);
}
}
@SuppressWarnings("unused")
@Test
public void testAutomaticTradeRefund() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = RavencoinACCTv3.buildTradeMessage(partner.getAddress(), ravencoinPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
Block postDeploymentBlock = BlockUtils.mintBlock(repository);
int postDeploymentBlockHeight = postDeploymentBlock.getBlockData().getHeight();
// Check refund
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
checkTradeRefund(repository, deployer, deployersInitialBalance, deployAtFee);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in REFUNDED mode
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.REFUNDED, tradeData.mode);
// Test orphaning
BlockUtils.orphanToBlock(repository, postDeploymentBlockHeight);
// Check balances
long expectedBalance = deployersPostDeploymentBalance;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertEquals("Deployer's post-orphan/pre-refund balance incorrect", expectedBalance, actualBalance);
}
}
@SuppressWarnings("unused")
@Test
public void testCorrectSecretCorrectSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = RavencoinACCTv3.buildTradeMessage(partner.getAddress(), ravencoinPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send correct secret to AT, from correct account
messageData = RavencoinACCTv3.buildRedeemMessage(secretA, partner.getAddress());
messageTransaction = sendMessage(repository, partner, messageData, atAddress);
// AT should send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertTrue(atData.getIsFinished());
// AT should be in REDEEMED mode
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.REDEEMED, tradeData.mode);
// Check balances
long expectedBalance = partnersInitialBalance - messageTransaction.getTransactionData().getFee() + redeemAmount;
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-redeem balance incorrect", expectedBalance, actualBalance);
// Orphan redeem
BlockUtils.orphanLastBlock(repository);
// Check balances
expectedBalance = partnersInitialBalance - messageTransaction.getTransactionData().getFee();
actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's post-orphan/pre-redeem balance incorrect", expectedBalance, actualBalance);
// Check AT state
ATStateData postOrphanAtStateData = repository.getATRepository().getLatestATState(atAddress);
assertTrue("AT states mismatch", Arrays.equals(preRedeemAtStateData.getStateData(), postOrphanAtStateData.getStateData()));
}
}
@SuppressWarnings("unused")
@Test
public void testCorrectSecretIncorrectSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
PrivateKeyAccount bystander = Common.getTestAccount(repository, "bob");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = RavencoinACCTv3.buildTradeMessage(partner.getAddress(), ravencoinPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send correct secret to AT, but from wrong account
messageData = RavencoinACCTv3.buildRedeemMessage(secretA, partner.getAddress());
messageTransaction = sendMessage(repository, bystander, messageData, atAddress);
// AT should NOT send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is NOT finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertFalse(atData.getIsFinished());
// AT should still be in TRADE mode
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.TRADING, tradeData.mode);
// Check balances
long expectedBalance = partnersInitialBalance;
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's balance incorrect", expectedBalance, actualBalance);
// Check eventual refund
checkTradeRefund(repository, deployer, deployersInitialBalance, deployAtFee);
}
}
@SuppressWarnings("unused")
@Test
public void testIncorrectSecretCorrectSender() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
long deployAtFee = deployAtTransaction.getTransactionData().getFee();
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = RavencoinACCTv3.buildTradeMessage(partner.getAddress(), ravencoinPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send incorrect secret to AT, from correct account
byte[] wrongSecret = new byte[32];
RANDOM.nextBytes(wrongSecret);
messageData = RavencoinACCTv3.buildRedeemMessage(wrongSecret, partner.getAddress());
messageTransaction = sendMessage(repository, partner, messageData, atAddress);
// AT should NOT send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is NOT finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertFalse(atData.getIsFinished());
// AT should still be in TRADE mode
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.TRADING, tradeData.mode);
long expectedBalance = partnersInitialBalance - messageTransaction.getTransactionData().getFee();
long actualBalance = partner.getConfirmedBalance(Asset.QORT);
assertEquals("Partner's balance incorrect", expectedBalance, actualBalance);
// Check eventual refund
checkTradeRefund(repository, deployer, deployersInitialBalance, deployAtFee);
}
}
@SuppressWarnings("unused")
@Test
public void testCorrectSecretCorrectSenderInvalidMessageLength() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
Account at = deployAtTransaction.getATAccount();
String atAddress = at.getAddress();
long partnersOfferMessageTransactionTimestamp = System.currentTimeMillis();
int lockTimeA = calcTestLockTimeA(partnersOfferMessageTransactionTimestamp);
int refundTimeout = RavencoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = RavencoinACCTv3.buildTradeMessage(partner.getAddress(), ravencoinPublicKeyHash, hashOfSecretA, lockTimeA, refundTimeout);
MessageTransaction messageTransaction = sendMessage(repository, tradeAccount, messageData, atAddress);
// Give AT time to process message
BlockUtils.mintBlock(repository);
// Send correct secret to AT, from correct account, but missing receive address, hence incorrect length
messageData = Bytes.concat(secretA);
messageTransaction = sendMessage(repository, partner, messageData, atAddress);
// AT should NOT send funds in the next block
ATStateData preRedeemAtStateData = repository.getATRepository().getLatestATState(atAddress);
BlockUtils.mintBlock(repository);
describeAt(repository, atAddress);
// Check AT is NOT finished
ATData atData = repository.getATRepository().fromATAddress(atAddress);
assertFalse(atData.getIsFinished());
// AT should be in TRADING mode
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
assertEquals(AcctMode.TRADING, tradeData.mode);
}
}
@SuppressWarnings("unused")
@Test
public void testDescribeDeployed() throws DataException {
try (final Repository repository = RepositoryManager.getRepository()) {
PrivateKeyAccount deployer = Common.getTestAccount(repository, "chloe");
PrivateKeyAccount tradeAccount = createTradeAccount(repository);
PrivateKeyAccount partner = Common.getTestAccount(repository, "dilbert");
long deployersInitialBalance = deployer.getConfirmedBalance(Asset.QORT);
long partnersInitialBalance = partner.getConfirmedBalance(Asset.QORT);
DeployAtTransaction deployAtTransaction = doDeploy(repository, deployer, tradeAccount.getAddress());
List<ATData> executableAts = repository.getATRepository().getAllExecutableATs();
for (ATData atData : executableAts) {
String atAddress = atData.getATAddress();
byte[] codeBytes = atData.getCodeBytes();
byte[] codeHash = Crypto.digest(codeBytes);
System.out.println(String.format("%s: code length: %d byte%s, code hash: %s",
atAddress,
codeBytes.length,
(codeBytes.length != 1 ? "s": ""),
HashCode.fromBytes(codeHash)));
// Not one of ours?
if (!Arrays.equals(codeHash, RavencoinACCTv3.CODE_BYTES_HASH))
continue;
describeAt(repository, atAddress);
}
}
}
private int calcTestLockTimeA(long messageTimestamp) {
return (int) (messageTimestamp / 1000L + tradeTimeout * 60);
}
private DeployAtTransaction doDeploy(Repository repository, PrivateKeyAccount deployer, String tradeAddress) throws DataException {
byte[] creationBytes = RavencoinACCTv3.buildQortalAT(tradeAddress, ravencoinPublicKeyHash, redeemAmount, ravencoinAmount, tradeTimeout);
long txTimestamp = System.currentTimeMillis();
byte[] lastReference = deployer.getLastReference();
if (lastReference == null) {
System.err.println(String.format("Qortal account %s has no last reference", deployer.getAddress()));
System.exit(2);
}
Long fee = null;
String name = "QORT-RVN cross-chain trade";
String description = String.format("Qortal-Ravencoin cross-chain trade");
String atType = "ACCT";
String tags = "QORT-RVN ACCT";
BaseTransactionData baseTransactionData = new BaseTransactionData(txTimestamp, Group.NO_GROUP, lastReference, deployer.getPublicKey(), fee, null);
TransactionData deployAtTransactionData = new DeployAtTransactionData(baseTransactionData, name, description, atType, tags, creationBytes, fundingAmount, Asset.QORT);
DeployAtTransaction deployAtTransaction = new DeployAtTransaction(repository, deployAtTransactionData);
fee = deployAtTransaction.calcRecommendedFee();
deployAtTransactionData.setFee(fee);
TransactionUtils.signAndMint(repository, deployAtTransactionData, deployer);
return deployAtTransaction;
}
private MessageTransaction sendMessage(Repository repository, PrivateKeyAccount sender, byte[] data, String recipient) throws DataException {
long txTimestamp = System.currentTimeMillis();
byte[] lastReference = sender.getLastReference();
if (lastReference == null) {
System.err.println(String.format("Qortal account %s has no last reference", sender.getAddress()));
System.exit(2);
}
Long fee = null;
int version = 4;
int nonce = 0;
long amount = 0;
Long assetId = null; // because amount is zero
BaseTransactionData baseTransactionData = new BaseTransactionData(txTimestamp, Group.NO_GROUP, lastReference, sender.getPublicKey(), fee, null);
TransactionData messageTransactionData = new MessageTransactionData(baseTransactionData, version, nonce, recipient, amount, assetId, data, false, false);
MessageTransaction messageTransaction = new MessageTransaction(repository, messageTransactionData);
fee = messageTransaction.calcRecommendedFee();
messageTransactionData.setFee(fee);
TransactionUtils.signAndMint(repository, messageTransactionData, sender);
return messageTransaction;
}
private void checkTradeRefund(Repository repository, Account deployer, long deployersInitialBalance, long deployAtFee) throws DataException {
long deployersPostDeploymentBalance = deployersInitialBalance - fundingAmount - deployAtFee;
int refundTimeout = tradeTimeout / 2 + 1; // close enough
// AT should automatically refund deployer after 'refundTimeout' blocks
for (int blockCount = 0; blockCount <= refundTimeout; ++blockCount)
BlockUtils.mintBlock(repository);
// We don't bother to exactly calculate QORT spent running AT for several blocks, but we do know the expected range
long expectedMinimumBalance = deployersPostDeploymentBalance;
long expectedMaximumBalance = deployersInitialBalance - deployAtFee;
long actualBalance = deployer.getConfirmedBalance(Asset.QORT);
assertTrue(String.format("Deployer's balance %s should be above minimum %s", actualBalance, expectedMinimumBalance), actualBalance > expectedMinimumBalance);
assertTrue(String.format("Deployer's balance %s should be below maximum %s", actualBalance, expectedMaximumBalance), actualBalance < expectedMaximumBalance);
}
private void describeAt(Repository repository, String atAddress) throws DataException {
ATData atData = repository.getATRepository().fromATAddress(atAddress);
CrossChainTradeData tradeData = RavencoinACCTv3.getInstance().populateTradeData(repository, atData);
Function<Long, String> epochMilliFormatter = (timestamp) -> LocalDateTime.ofInstant(Instant.ofEpochMilli(timestamp), ZoneOffset.UTC).format(DateTimeFormatter.ofLocalizedDateTime(FormatStyle.MEDIUM));
int currentBlockHeight = repository.getBlockRepository().getBlockchainHeight();
System.out.print(String.format("%s:\n"
+ "\tmode: %s\n"
+ "\tcreator: %s,\n"
+ "\tcreation timestamp: %s,\n"
+ "\tcurrent balance: %s QORT,\n"
+ "\tis finished: %b,\n"
+ "\tredeem payout: %s QORT,\n"
+ "\texpected ravencoin: %s RVN,\n"
+ "\tcurrent block height: %d,\n",
tradeData.qortalAtAddress,
tradeData.mode,
tradeData.qortalCreator,
epochMilliFormatter.apply(tradeData.creationTimestamp),
Amounts.prettyAmount(tradeData.qortBalance),
atData.getIsFinished(),
Amounts.prettyAmount(tradeData.qortAmount),
Amounts.prettyAmount(tradeData.expectedForeignAmount),
currentBlockHeight));
if (tradeData.mode != AcctMode.OFFERING && tradeData.mode != AcctMode.CANCELLED) {
System.out.println(String.format("\trefund timeout: %d minutes,\n"
+ "\trefund height: block %d,\n"
+ "\tHASH160 of secret-A: %s,\n"
+ "\tRavencoin P2SH-A nLockTime: %d (%s),\n"
+ "\ttrade partner: %s\n"
+ "\tpartner's receiving address: %s",
tradeData.refundTimeout,
tradeData.tradeRefundHeight,
HashCode.fromBytes(tradeData.hashOfSecretA).toString().substring(0, 40),
tradeData.lockTimeA, epochMilliFormatter.apply(tradeData.lockTimeA * 1000L),
tradeData.qortalPartnerAddress,
tradeData.qortalPartnerReceivingAddress));
}
}
private PrivateKeyAccount createTradeAccount(Repository repository) {
// We actually use a known test account with funds to avoid PoW compute
return Common.getTestAccount(repository, "alice");
}
}