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base: Qortal:v2.0.0
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Qortal:master Qortal:reticulum Qortal:auto-update-415f594b Qortal:auto-update-5fabc779 Qortal:auto-update-87897d7d Qortal:auto-update-0b37666d Qortal:auto-update-faee7c8f Qortal:auto-update-999cfafe Qortal:auto-update-c2bfa263 Qortal:auto-update-8ffb0625 Qortal:auto-update-2ce02faa Qortal:master2 Qortal:auto-update-d89f7ad4 Qortal:auto-update-83191934 Qortal:auto-update-6648c4be Qortal:revert-209-fix-unit-tests Qortal:auto-update-ec8ddf2b Qortal:auto-update-a02d1cec Qortal:auto-update-c4a7fb3b Qortal:auto-update-070f14b3 Qortal:auto-update-867fe764 Qortal:auto-update-1400e7ae Qortal:auto-update-94cfcd66 Qortal:auto-update-b0f21c2e Qortal:auto-update-033b6adb Qortal:batch-rewards Qortal:thread-limits Qortal:add-create-bytes-endpoint Qortal:optimize_ats Qortal:reindex Qortal:arbitrary-resources-cache Qortal:block-sequence Qortal:q-apps Qortal:qdn-on-chain-data Qortal:rebuild-archive Qortal:chatdb Qortal:cancel-sell-name-fixes Qortal:qdn-file-list Qortal:at-states-fix Qortal:chat-reference Qortal:null-owned-groups Qortal:BLOCK_SUMMARIES_V2 Qortal:online-accounts-mempow-v2-block-updates Qortal:shares-by-level-rework Qortal:pirate-chain Qortal:online-accounts-mempow-v2 Qortal:increase-online-timestamp-modulus Qortal:share-bin-activation Qortal:qora-holders-share Qortal:reduce-reward-shares Qortal:sync-long-tip Qortal:disable-reference Qortal:height-v3 Qortal:new-coins Qortal:qdn-direct-connections Qortal:online-accounts-mempow Qortal:lite-node Qortal:ravencoin Qortal:digibyte Qortal:EPC-fixes Qortal:name-fixes Qortal:qdn-metadata Qortal:hosted-resources-search Qortal:relay-hops Qortal:online-level-zero-accounts-api-call Qortal:block-minter-updates Qortal:trade-portal-updates Qortal:qdn Qortal:mempow-testing Qortal:protoniuman-FR-patch-1 Qortal:v2.0-beta Qortal:bootstrap Qortal:block-archive Qortal:pruning-mode Qortal:add-atstates-index Qortal:chat-rate-limiter Qortal:lists Qortal:AT-sleep-until-message Qortal:sync-multiple-blocks Qortal:networking Qortal:ignore-old-versions Qortal:block-timings Qortal:synchronization-improvements Qortal:chain-weight-consensus Qortal:prioritize-peers Qortal:blockminter-updates Qortal:block-reward-distribution-fix Qortal:trade-bot-timeout-fix Qortal:segwit Qortal:bindaddress-ipv4 Qortal:blocksig Qortal:split-DB
Qortal:v5.0.2 Qortal:v5.0.1 Qortal:v5.0.0 Qortal:v4.7.1 Qortal:v4.7.0 Qortal:v4.6.6 Qortal:v4.6.5 Qortal:v4.6.4 Qortal:v4.6.3 Qortal:v4.6.2 Qortal:v4.6.1 Qortal:v4.6.0 Qortal:v4.5.2 Qortal:v4.5.1 Qortal:v4.5.0 Qortal:v4.4.2 Qortal:v4.4.1 Qortal:v4.4.0 Qortal:v4.3.2 Qortal:v4.3.1 Qortal:v4.3.0 Qortal:v4.2.4 Qortal:v4.2.3 Qortal:v4.2.2 Qortal:v4.2.1 Qortal:v4.2.0 Qortal:v4.1.3 Qortal:v4.1.2 Qortal:v4.1.1 Qortal:v4.1.0 Qortal:v4.0.3 Qortal:v4.0.2 Qortal:v4.0.1 Qortal:v4.0.0 Qortal:v3.9.1 Qortal:v3.9.0 Qortal:v3.8.9 Qortal:v3.8.8 Qortal:v3.8.7 Qortal:v3.8.6 Qortal:v3.8.5 Qortal:v3.8.4 Qortal:v3.8.3 Qortal:v3.8.2 Qortal:v3.8.1 Qortal:v3.8.0 Qortal:v3.7.0 Qortal:v3.6.4 Qortal:v3.6.3 Qortal:v3.6.2 Qortal:v3.6.1 Qortal:v3.6.0 Qortal:v3.5.0 Qortal:v3.4.3 Qortal:v3.4.2 Qortal:v3.4.1 Qortal:v3.4.0 Qortal:v3.3.7 Qortal:v3.3.6 Qortal:v3.3.5 Qortal:v3.3.4 Qortal:v3.3.3 Qortal:v3.3.2 Qortal:v3.3.1 Qortal:v3.3.0 Qortal:v3.2.5 Qortal:v3.2.4 Qortal:v3.2.3 Qortal:v3.2.2 Qortal:v3.2.1 Qortal:v3.2.0 Qortal:v3.1.1 Qortal:v3.1.0 Qortal:v3.0.4 Qortal:v3.0.3 Qortal:v3.0.2 Qortal:v3.0.1 Qortal:v3.0.0 Qortal:v2.1.3 Qortal:v2.1.2 Qortal:v2.1.1 Qortal:v2.1.0 Qortal:v2.0.0 Qortal:v1.7.0 Qortal:v1.6.0 Qortal:v1.5.6 Qortal:v1.5.5 Qortal:v1.5.4 Qortal:v1.5.3 Qortal:v1.5.2 Qortal:v1.5.1 Qortal:v1.5.0 Qortal:v1.4.6 Qortal:v1.4.5 Qortal:v1.4.4 Qortal:v1.4.3 Qortal:v1.4.2 Qortal:v1.4.1 Qortal:v1.4.0 Qortal:v1.3.9 Qortal:v1.3.8 Qortal:v1.3.7 Qortal:v1.3.6 Qortal:v1.3.5 Qortal:v1.3.4 Qortal:v1.3.3 Qortal:v1.3.2 Qortal:v1.3.1 Qortal:v1.3.0 Qortal:v1.2.3 Qortal:v1.2.2 Qortal:v1.2.1 Qortal:v1.2.0 Qortal:v1.0.8 Qortal:v1.0.7 Qortal:v1.0.6 Qortal:v1.0.5 Qortal:v1.0.4 Qortal:v1.0.3c Qortal:v1.0.3b Qortal:v1.0.3 Qortal:v1.0.2 Qortal:v1.0.1 Qortal:v1.0
...
compare: Qortal:v2.1.3
Branches Tags
Qortal:reticulum Qortal:master Qortal:auto-update-415f594b Qortal:auto-update-5fabc779 Qortal:auto-update-87897d7d Qortal:auto-update-0b37666d Qortal:auto-update-faee7c8f Qortal:auto-update-999cfafe Qortal:auto-update-c2bfa263 Qortal:auto-update-8ffb0625 Qortal:auto-update-2ce02faa Qortal:master2 Qortal:auto-update-d89f7ad4 Qortal:auto-update-83191934 Qortal:auto-update-6648c4be Qortal:revert-209-fix-unit-tests Qortal:auto-update-ec8ddf2b Qortal:auto-update-a02d1cec Qortal:auto-update-c4a7fb3b Qortal:auto-update-070f14b3 Qortal:auto-update-867fe764 Qortal:auto-update-1400e7ae Qortal:auto-update-94cfcd66 Qortal:auto-update-b0f21c2e Qortal:auto-update-033b6adb Qortal:batch-rewards Qortal:thread-limits Qortal:add-create-bytes-endpoint Qortal:optimize_ats Qortal:reindex Qortal:arbitrary-resources-cache Qortal:block-sequence Qortal:q-apps Qortal:qdn-on-chain-data Qortal:rebuild-archive Qortal:chatdb Qortal:cancel-sell-name-fixes Qortal:qdn-file-list Qortal:at-states-fix Qortal:chat-reference Qortal:null-owned-groups Qortal:BLOCK_SUMMARIES_V2 Qortal:online-accounts-mempow-v2-block-updates Qortal:shares-by-level-rework Qortal:pirate-chain Qortal:online-accounts-mempow-v2 Qortal:increase-online-timestamp-modulus Qortal:share-bin-activation Qortal:qora-holders-share Qortal:reduce-reward-shares Qortal:sync-long-tip Qortal:disable-reference Qortal:height-v3 Qortal:new-coins Qortal:qdn-direct-connections Qortal:online-accounts-mempow Qortal:lite-node Qortal:ravencoin Qortal:digibyte Qortal:EPC-fixes Qortal:name-fixes Qortal:qdn-metadata Qortal:hosted-resources-search Qortal:relay-hops Qortal:online-level-zero-accounts-api-call Qortal:block-minter-updates Qortal:trade-portal-updates Qortal:qdn Qortal:mempow-testing Qortal:protoniuman-FR-patch-1 Qortal:v2.0-beta Qortal:bootstrap Qortal:block-archive Qortal:pruning-mode Qortal:add-atstates-index Qortal:chat-rate-limiter Qortal:lists Qortal:AT-sleep-until-message Qortal:sync-multiple-blocks Qortal:networking Qortal:ignore-old-versions Qortal:block-timings Qortal:synchronization-improvements Qortal:chain-weight-consensus Qortal:prioritize-peers Qortal:blockminter-updates Qortal:block-reward-distribution-fix Qortal:trade-bot-timeout-fix Qortal:segwit Qortal:bindaddress-ipv4 Qortal:blocksig Qortal:split-DB
Qortal:v5.0.2 Qortal:v5.0.1 Qortal:v5.0.0 Qortal:v4.7.1 Qortal:v4.7.0 Qortal:v4.6.6 Qortal:v4.6.5 Qortal:v4.6.4 Qortal:v4.6.3 Qortal:v4.6.2 Qortal:v4.6.1 Qortal:v4.6.0 Qortal:v4.5.2 Qortal:v4.5.1 Qortal:v4.5.0 Qortal:v4.4.2 Qortal:v4.4.1 Qortal:v4.4.0 Qortal:v4.3.2 Qortal:v4.3.1 Qortal:v4.3.0 Qortal:v4.2.4 Qortal:v4.2.3 Qortal:v4.2.2 Qortal:v4.2.1 Qortal:v4.2.0 Qortal:v4.1.3 Qortal:v4.1.2 Qortal:v4.1.1 Qortal:v4.1.0 Qortal:v4.0.3 Qortal:v4.0.2 Qortal:v4.0.1 Qortal:v4.0.0 Qortal:v3.9.1 Qortal:v3.9.0 Qortal:v3.8.9 Qortal:v3.8.8 Qortal:v3.8.7 Qortal:v3.8.6 Qortal:v3.8.5 Qortal:v3.8.4 Qortal:v3.8.3 Qortal:v3.8.2 Qortal:v3.8.1 Qortal:v3.8.0 Qortal:v3.7.0 Qortal:v3.6.4 Qortal:v3.6.3 Qortal:v3.6.2 Qortal:v3.6.1 Qortal:v3.6.0 Qortal:v3.5.0 Qortal:v3.4.3 Qortal:v3.4.2 Qortal:v3.4.1 Qortal:v3.4.0 Qortal:v3.3.7 Qortal:v3.3.6 Qortal:v3.3.5 Qortal:v3.3.4 Qortal:v3.3.3 Qortal:v3.3.2 Qortal:v3.3.1 Qortal:v3.3.0 Qortal:v3.2.5 Qortal:v3.2.4 Qortal:v3.2.3 Qortal:v3.2.2 Qortal:v3.2.1 Qortal:v3.2.0 Qortal:v3.1.1 Qortal:v3.1.0 Qortal:v3.0.4 Qortal:v3.0.3 Qortal:v3.0.2 Qortal:v3.0.1 Qortal:v3.0.0 Qortal:v2.1.3 Qortal:v2.1.2 Qortal:v2.1.1 Qortal:v2.1.0 Qortal:v2.0.0 Qortal:v1.7.0 Qortal:v1.6.0 Qortal:v1.5.6 Qortal:v1.5.5 Qortal:v1.5.4 Qortal:v1.5.3 Qortal:v1.5.2 Qortal:v1.5.1 Qortal:v1.5.0 Qortal:v1.4.6 Qortal:v1.4.5 Qortal:v1.4.4 Qortal:v1.4.3 Qortal:v1.4.2 Qortal:v1.4.1 Qortal:v1.4.0 Qortal:v1.3.9 Qortal:v1.3.8 Qortal:v1.3.7 Qortal:v1.3.6 Qortal:v1.3.5 Qortal:v1.3.4 Qortal:v1.3.3 Qortal:v1.3.2 Qortal:v1.3.1 Qortal:v1.3.0 Qortal:v1.2.3 Qortal:v1.2.2 Qortal:v1.2.1 Qortal:v1.2.0 Qortal:v1.0.8 Qortal:v1.0.7 Qortal:v1.0.6 Qortal:v1.0.5 Qortal:v1.0.4 Qortal:v1.0.3c Qortal:v1.0.3b Qortal:v1.0.3 Qortal:v1.0.2 Qortal:v1.0.1 Qortal:v1.0

60 Commits
v2.0.0 ... v2.1.3

Author SHA1 Message Date
CalDescent
ace3ca0ad9 Bump version to 2.1.3 2021-12-19 21:10:24 +00:00
CalDescent
a8a498ddea Disable the names integrity check on startup by default. 
This isn't really needed and is risky leaving it enabled, as there may be other unsupported cases.
 2021-12-19 20:54:19 +00:00
CalDescent
d16663f0a9 Handle missing case in names integrity check caused by an UPDATE_NAME transaction with a blank "newName" value. 
This is a valid transaction but not one that the integrity check was handling properly. Should fix NullPointerException on node startup.
 2021-12-19 20:23:57 +00:00
QuickMythril
9ce748452d Merge pull request #64 from Qortal/protoniuman-FR-patch-1 
Protoniuman fr patch 1
 2021-12-19 05:55:37 -05:00
Proto
9263d74b75 Update TransactionValidity_fr.properties 2021-12-19 11:16:20 +01:00
Proto
9601bddc84 Update SysTray_fr.properties 2021-12-19 11:05:34 +01:00
Proto
e281e19052 Add files via upload 2021-12-19 11:02:00 +01:00
Proto
0238b78f45 Update ApiError_fr.properties 2021-12-19 10:57:57 +01:00
QuickMythril
0ccee4326d Added French translations 
credit: stchoupi
 2021-12-18 15:57:49 -05:00
CalDescent
391c3fe4c9 Added same functionality to GET /blocks/signature/{signature} 
Also renamed query string parameter to "includeOnlineSignatures" to make it clearer.
 2021-12-15 16:37:59 +00:00
CalDescent
3a7da9f13b Don't return online accounts signatures from GET /blocks/byheight/{height} unless requested using the includesignatures=true query string parameter. 
This should fix issue where it would take up to 30 seconds to return for a recent block, and would consume masses of CPU due to having to base58 encode the online accounts signatures. Base58 is very slow and made this API endpoint almost unusable for recent blocks, due to them having untrimmed online accounts signatures.
 2021-12-15 16:33:08 +00:00
CalDescent
e7fd803d19 Updated AdvancedInstaller project for v2.1.2 2021-12-11 22:16:43 +00:00
CalDescent
3b96747871 Bump version to 2.1.2 2021-12-11 21:50:54 +00:00
CalDescent
33088df07d Revert "Bump log4j-api version to 2.15.0" 
This reverts commit 6a9904fd43.
 2021-12-11 19:40:44 +00:00
CalDescent
a215714b6b Set log4j2.formatMsgNoLookups to true 2021-12-11 19:09:25 +00:00
CalDescent
6a9904fd43 Bump log4j-api version to 2.15.0 
The main log4j version cannot be increased yet due to some incompatibilities with the Qortal code.
 2021-12-10 17:54:11 +00:00
CalDescent
391d31759a Fixed small issue in GET /crosschain/trades and GET /crosschain/tradeoffers APIs where 0 was being treated as zero instead of unlimited. 
In 2.1.1, unlimited results can be requested by removing the `limit` query string parameter completely, e.g:

http://127.0.0.1:12391/crosschain/trades?foreignBlockchain=LITECOIN&minimumTimestamp=1638835200000&reverse=false
 2021-12-08 20:22:02 +00:00
CalDescent
ed2f2435d2 Updated AdvancedInstaller project for v2.1.1 2021-12-08 19:32:36 +00:00
CalDescent
6e6b2ccfa0 Bump version to 2.1.1 2021-12-08 18:39:30 +00:00
CalDescent
be9a73560d Added one more node 2021-12-08 17:23:42 +00:00
CalDescent
e82b5a4ecf Added 7 qortalnodes.live nodes to the default list. 2021-12-08 16:10:50 +00:00
CalDescent
a27d8ac828 Connect ACCTv3 trade bots to the ACCTv3 smart contracts 2021-12-08 12:52:22 +00:00
CalDescent
6267258189 Switch over to ACCTv3 for new listings 2021-12-08 12:22:26 +00:00
CalDescent
e7527f532e Added LitecoinACCTv3 and DogecoinACCTv3 to SupportedBlockchain 2021-12-08 12:21:52 +00:00
CalDescent
8b6e74d505 Added ACCTv3 trade bots. Identical to v1 and v2. 2021-12-08 12:18:22 +00:00
CalDescent
e6106c0c4e Added ACCTv3 tests, based on the same criteria as ACCTv1. Refunds are working as intended. 2021-12-08 12:10:36 +00:00
CalDescent
f52bafc014 Removed second "SLEEP_UNTIL_MESSAGE" function code call in LitecoinACCTv3 and DogecoinACCTv3. 
It turns out that when you call SLEEP_UNTIL_MESSAGE, the AT resumes from that very same line on the next execution. The original code incorrectly assumed that it would execute from the restart position (SET_PCS).

So sleeping can be thought of as pausing one execution half way through, rather than ending it.

This caused a bug, because once the AT receives a transaction it wakes up and resumes from the SLEEP_UNTIL_MESSAGE line, which is after the refund check. Even when it loops back around again it lands on labelRedeemTxnLoop = codeByteBuffer.position(); which is again after the refund check.

For now, the simplest fix is to only sleep when listed. We could have alternatively moved the SLEEP_UNTIL_MESSAGE above GET_BLOCK_TIMESTAMP, but this would still require users to send a random transaction to the AT to trigger the refund. Given that the ATs are only "alive" for 30 minutes once the trade begins, it's simpler to just execute every block and therefore allow the refunds to happen automatically.
 2021-12-08 12:08:06 +00:00
CalDescent
9e0630ea79 Added LitecoinACCTv3 and DogecoinACCTv3 - at the moment identical to ACCTv2 2021-12-08 11:55:25 +00:00
CalDescent
968bfb92d0 Fixed bugs in the GET /crosschain/tradeoffers API endpoint caused by the introduction of ACCTv2 2021-12-07 22:32:46 +00:00
CalDescent
284c9fcee2 Fixed bugs in the GET /crosschain/price API endpoint caused by the introduction of ACCTv2 2021-12-07 21:20:08 +00:00
CalDescent
5b0b939531 Fixed bugs in the GET /crosschain/trades API endpoint caused by the introduction of ACCTv2 2021-12-06 20:14:08 +00:00
CalDescent
dc52fd1dcf Only return OFFERING trades in GET /crosschain/tradeoffers 2021-12-06 19:37:30 +00:00
CalDescent
13f3aca838 Added GET /addresses/online/levels API endpoint to return the number of minters at each level 2021-12-04 19:28:28 +00:00
CalDescent
d9de27e6f2 Updated AdvancedInstaller project for v2.1.0 2021-11-24 19:39:37 +00:00
CalDescent
6930bf0200 Bump version to 2.1.0 2021-11-24 18:36:40 +00:00
CalDescent
199833bdd4 Fixed issue with GET /crosschain/trades API endpoint where the minimumTimestamp parameter returned inconsistent results. 2021-11-24 15:21:08 +00:00
CalDescent
0dcd2e6e93 Fixed bug in GET ​/crosschain​/price​/{blockchain} inverse price API endpoint when the "inverse" parameter is null. 2021-11-24 15:09:45 +00:00
CalDescent
098d7baa4d Bump version to 2.1.0-prerelease.0 2021-11-23 19:03:27 +00:00
CalDescent
59a57d3d28 Increased frequency of automatic repository maintenance attempts 
repositoryMaintenanceMinInterval reduced from 7 to 3 days
repositoryMaintenanceMaxInterval reduced from 30 to 14 days
 2021-11-23 18:47:27 +00:00
CalDescent
cce95e09de Default min level for block submissions increased to 3 
This doesn't affect minting rewards; it is simply a means of reducing block candidates. There should be no noticeable difference other than hopefully less re-orgs. We can ultimately do a hard fork and increase Blockchain.minAccountLevelToMint but this allows us to test the approach in a lower risk way.
 2021-11-23 18:45:35 +00:00
CalDescent
d018f11877 Log the initial height of the block archiver on startup 2021-11-21 09:12:32 +00:00
CalDescent
9502444bbc Prevent any kind of trading unless the blockchain is fully synced 2021-11-05 16:31:54 +00:00
CalDescent
3b914d4a7f Improved trade bot backups so that the current order being bought is included. 
This should fix any key recovery issues if the node crashes or otherwise fails when buying an offer.
 2021-11-03 19:27:56 +00:00
Scare Crowe
319d96f94e Add CWD bootstrap node 2021-11-03 11:45:47 +05:00
CalDescent
394ced9fb9 "Lists" feature is now generic. 
This means that no additional structural code is required to add new lists. The only non-generic aspect are the API endpoints - it's best to keep these specific until we have a need for user-created lists.
 2021-10-31 18:45:40 +00:00
CalDescent
314b6fc2f8 Include the initial peers when creating bootstraps 2021-10-27 08:46:52 +01:00
CalDescent
974df031a0 Added another bootstrap host 2021-10-26 21:41:22 +01:00
CalDescent
36d0292c6b Added "sleep until message" functionality to LTC ACCTv2. 2021-10-26 20:10:05 +01:00
CalDescent
7c16952c92 Added LitecoinACCTv2 and LitecoinACCTv2TradeBot 2021-10-26 19:56:33 +01:00
CalDescent
557807e3ba Initial attempt at adding "sleep until message" functionality to DOGE ACCTv2. 2021-10-26 10:59:23 +01:00
CalDescent
c1d5b2df29 Added DogecoinACCTv2 and DogecoinACCTv2TradeBot 2021-10-26 10:59:16 +01:00
CalDescent
3e0574e563 Added another missing block archive lookup relating to trade timestamps. 
Note that this is unlikely to be the cause of some of the zero timestamps issue seen on a subset of nodes - there is still likely to be another problem that needs fixing.
 2021-10-25 18:21:40 +01:00
CalDescent
69e557e70d Delete .sha256 file which was left lying around after running the bootstrap unit tests. 2021-10-25 18:20:58 +01:00
QuickMythril
49dd63af1e updated BTC electrum servers 2021-10-23 00:46:02 -04:00
CalDescent
18c6f0ccc3 Merge pull request #60 from Tocoolmh58/master 2021-10-22 18:05:38 +01:00
QuickMythril
55c50a4b5b add API option to return inverse price (#61) 2021-10-22 18:04:53 +01:00
CalDescent
1fbd5f7922 Fix for issue causing tradeTimestamp to report as 0 for trades in archived blocks. 2021-10-17 09:52:59 +01:00
CalDescent
bbb71083ef Updated AdvancedInstaller project for v2.0.0 2021-10-13 19:11:42 +01:00
Tocoolmh58
000f9ed459 Update ApiError_de.properties 2021-10-06 17:23:16 +02:00
Tocoolmh58
c5b2c0b4ec Create SysTray_de.properties 2021-10-06 17:01:52 +02:00
47 changed files with 9377 additions and 279 deletions
Expand all files Collapse all files

6
WindowsInstaller/Qortal.aip
View File

@@ -17,10 +17,10 @@
<ROW Property="Manufacturer" Value="Qortal"/>
<ROW Property="MsiLogging" MultiBuildValue="DefaultBuild:vp"/>
<ROW Property="NTP_GOOD" Value="false"/>
<ROW Property="ProductCode" Value="1033:{7B3C1C09-F01F-4E39-91D5-A8CF83FF5A54} 1049:{F7FB426D-E66F-4C45-ACE2-189D9DD9252F} 2052:{D0A1DC46-0E82-46A1-A882-05E3A66D1198} 2057:{4C08BD8D-ADB4-4E4B-853E-426926C32D6D} " Type="16"/>
<ROW Property="ProductCode" Value="1033:{D45BD9F0-1D22-46A2-9990-8BB3598D8AD3} 1049:{21BCBDEC-4BF2-41D6-9426-E906042FD61F} 2052:{95F43BE3-58B4-4422-BCCF-D77F4BBFD7A4} 2057:{4C4D611E-3AF5-4216-952A-CA9E5EC32C19} " Type="16"/>
<ROW Property="ProductLanguage" Value="2057"/>
<ROW Property="ProductName" Value="Qortal"/>
<ROW Property="ProductVersion" Value="1.7.0" Type="32"/>
<ROW Property="ProductVersion" Value="2.1.2" Type="32"/>
<ROW Property="RECONFIG_NTP" Value="true"/>
<ROW Property="REMOVE_BLOCKCHAIN" Value="YES" Type="4"/>
<ROW Property="REPAIR_BLOCKCHAIN" Value="YES" Type="4"/>
@@ -212,7 +212,7 @@
<ROW Component="ADDITIONAL_LICENSE_INFO_71" ComponentId="{12A3ADBE-BB7A-496C-8869-410681E6232F}" Directory_="jdk.zipfs_Dir" Attributes="0" KeyPath="ADDITIONAL_LICENSE_INFO_71" Type="0"/>
<ROW Component="ADDITIONAL_LICENSE_INFO_8" ComponentId="{D53AD95E-CF96-4999-80FC-5812277A7456}" Directory_="java.naming_Dir" Attributes="0" KeyPath="ADDITIONAL_LICENSE_INFO_8" Type="0"/>
<ROW Component="ADDITIONAL_LICENSE_INFO_9" ComponentId="{6B7EA9B0-5D17-47A8-B78C-FACE86D15E01}" Directory_="java.net.http_Dir" Attributes="0" KeyPath="ADDITIONAL_LICENSE_INFO_9" Type="0"/>
<ROW Component="AI_CustomARPName" ComponentId="{45C3C526-BCC9-4E9A-9260-A5EEA10A03C8}" Directory_="APPDIR" Attributes="260" KeyPath="DisplayName" Options="1"/>
<ROW Component="AI_CustomARPName" ComponentId="{5109CB00-40C0-499E-875B-9364F2075410}" Directory_="APPDIR" Attributes="260" KeyPath="DisplayName" Options="1"/>
<ROW Component="AI_ExePath" ComponentId="{3644948D-AE0B-41BB-9FAF-A79E70490A08}" Directory_="APPDIR" Attributes="260" KeyPath="AI_ExePath"/>
<ROW Component="APPDIR" ComponentId="{680DFDDE-3FB4-47A5-8FF5-934F576C6F91}" Directory_="APPDIR" Attributes="0"/>
<ROW Component="AccessBridgeCallbacks.h" ComponentId="{288055D1-1062-47A3-AA44-5601B4E38AED}" Directory_="bridge_Dir" Attributes="0" KeyPath="AccessBridgeCallbacks.h" Type="0"/>

2
pom.xml
View File

@@ -3,7 +3,7 @@
<modelVersion>4.0.0</modelVersion>
<groupId>org.qortal</groupId>
<artifactId>qortal</artifactId>
<version>2.0.0</version>
<version>2.1.3</version>
<packaging>jar</packaging>
<properties>
<skipTests>true</skipTests>

8
src/main/java/org/qortal/api/model/AddressListRequest.java → src/main/java/org/qortal/api/model/ListRequest.java
View File

@@ -7,12 +7,12 @@ import javax.xml.bind.annotation.XmlAccessorType;
import java.util.List;
@XmlAccessorType(XmlAccessType.FIELD)
public class AddressListRequest {
public class ListRequest {
@Schema(description = "A list of addresses")
public List<String> addresses;
@Schema(description = "A list of items")
public List<String> items;
public AddressListRequest() {
public ListRequest() {
}
}

62
src/main/java/org/qortal/api/resource/AddressesResource.java
View File

@@ -12,6 +12,7 @@ import io.swagger.v3.oas.annotations.tags.Tag;
import java.math.BigDecimal;
import java.util.ArrayList;
import java.util.Comparator;
import java.util.List;
import javax.servlet.http.HttpServletRequest;
@@ -38,6 +39,7 @@ import org.qortal.crypto.Crypto;
import org.qortal.data.account.AccountData;
import org.qortal.data.account.RewardShareData;
import org.qortal.data.network.OnlineAccountData;
import org.qortal.data.network.OnlineAccountLevel;
import org.qortal.data.transaction.PublicizeTransactionData;
import org.qortal.data.transaction.RewardShareTransactionData;
import org.qortal.data.transaction.TransactionData;
@@ -180,6 +182,66 @@ public class AddressesResource {
}
}
@GET
@Path("/online/levels")
@Operation(
summary = "Return currently 'online' accounts counts, grouped by level",
responses = {
@ApiResponse(
description = "online accounts",
content = @Content(mediaType = MediaType.APPLICATION_JSON, array = @ArraySchema(schema = @Schema(implementation = ApiOnlineAccount.class)))
)
}
)
@ApiErrors({ApiError.PUBLIC_KEY_NOT_FOUND, ApiError.REPOSITORY_ISSUE})
public List<OnlineAccountLevel> getOnlineAccountsByLevel() {
List<OnlineAccountData> onlineAccounts = Controller.getInstance().getOnlineAccounts();
try (final Repository repository = RepositoryManager.getRepository()) {
List<OnlineAccountLevel> onlineAccountLevels = new ArrayList<>();
for (OnlineAccountData onlineAccountData : onlineAccounts) {
try {
final int minterLevel = Account.getRewardShareEffectiveMintingLevel(repository, onlineAccountData.getPublicKey());
OnlineAccountLevel onlineAccountLevel = onlineAccountLevels.stream()
.filter(a -> a.getLevel() == minterLevel)
.findFirst().orElse(null);
// Note: I don't think we can use the level as the List index here because there will be gaps.
// So we are forced to manually look up the existing item each time.
// There's probably a nice shorthand java way of doing this, but this approach gets the same result.
if (onlineAccountLevel == null) {
// No entry exists for this level yet, so create one
onlineAccountLevel = new OnlineAccountLevel(minterLevel, 1);
onlineAccountLevels.add(onlineAccountLevel);
}
else {
// Already exists - so increment the count
int existingCount = onlineAccountLevel.getCount();
onlineAccountLevel.setCount(++existingCount);
// Then replace the existing item
int index = onlineAccountLevels.indexOf(onlineAccountLevel);
onlineAccountLevels.set(index, onlineAccountLevel);
}
} catch (DataException e) {
continue;
}
}
// Sort by level
onlineAccountLevels.sort(Comparator.comparingInt(OnlineAccountLevel::getLevel));
return onlineAccountLevels;
} catch (DataException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.REPOSITORY_ISSUE, e);
}
}
@GET
@Path("/balance/{address}")
@Operation(

18
src/main/java/org/qortal/api/resource/BlocksResource.java
View File

@@ -75,7 +75,8 @@ public class BlocksResource {
@ApiErrors({
ApiError.INVALID_SIGNATURE, ApiError.BLOCK_UNKNOWN, ApiError.REPOSITORY_ISSUE
})
public BlockData getBlock(@PathParam("signature") String signature58) {
public BlockData getBlock(@PathParam("signature") String signature58,
@QueryParam("includeOnlineSignatures") Boolean includeOnlineSignatures) {
// Decode signature
byte[] signature;
try {
@@ -88,12 +89,18 @@ public class BlocksResource {
// Check the database first
BlockData blockData = repository.getBlockRepository().fromSignature(signature);
if (blockData != null) {
if (includeOnlineSignatures == null || includeOnlineSignatures == false) {
blockData.setOnlineAccountsSignatures(null);
}
return blockData;
}
// Not found, so try the block archive
blockData = repository.getBlockArchiveRepository().fromSignature(signature);
if (blockData != null) {
if (includeOnlineSignatures == null || includeOnlineSignatures == false) {
blockData.setOnlineAccountsSignatures(null);
}
return blockData;
}
@@ -423,17 +430,24 @@ public class BlocksResource {
@ApiErrors({
ApiError.BLOCK_UNKNOWN, ApiError.REPOSITORY_ISSUE
})
public BlockData getByHeight(@PathParam("height") int height) {
public BlockData getByHeight(@PathParam("height") int height,
@QueryParam("includeOnlineSignatures") Boolean includeOnlineSignatures) {
try (final Repository repository = RepositoryManager.getRepository()) {
// Firstly check the database
BlockData blockData = repository.getBlockRepository().fromHeight(height);
if (blockData != null) {
if (includeOnlineSignatures == null || includeOnlineSignatures == false) {
blockData.setOnlineAccountsSignatures(null);
}
return blockData;
}
// Not found, so try the archive
blockData = repository.getBlockArchiveRepository().fromHeight(height);
if (blockData != null) {
if (includeOnlineSignatures == null || includeOnlineSignatures == false) {
blockData.setOnlineAccountsSignatures(null);
}
return blockData;
}

97
src/main/java/org/qortal/api/resource/CrossChainResource.java
View File

@@ -1,5 +1,6 @@
package org.qortal.api.resource;
import com.google.common.primitives.Longs;
import io.swagger.v3.oas.annotations.Operation;
import io.swagger.v3.oas.annotations.Parameter;
import io.swagger.v3.oas.annotations.media.ArraySchema;
@@ -10,12 +11,7 @@ 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.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.List;
import java.util.Map;
import java.util.Random;
import java.util.*;
import java.util.function.Supplier;
import javax.servlet.http.HttpServletRequest;
@@ -95,7 +91,7 @@ public class CrossChainResource {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
final boolean isExecutable = true;
List<CrossChainTradeData> crossChainTradesData = new ArrayList<>();
List<CrossChainTradeData> crossChainTrades = new ArrayList<>();
try (final Repository repository = RepositoryManager.getRepository()) {
Map<ByteArray, Supplier<ACCT>> acctsByCodeHash = SupportedBlockchain.getFilteredAcctMap(foreignBlockchain);
@@ -108,11 +104,27 @@ public class CrossChainResource {
for (ATData atData : atsData) {
CrossChainTradeData crossChainTradeData = acct.populateTradeData(repository, atData);
crossChainTradesData.add(crossChainTradeData);
if (crossChainTradeData.mode == AcctMode.OFFERING) {
crossChainTrades.add(crossChainTradeData);
}
}
}
return crossChainTradesData;
// Sort the trades by timestamp
if (reverse != null && reverse) {
crossChainTrades.sort((a, b) -> Longs.compare(b.creationTimestamp, a.creationTimestamp));
}
else {
crossChainTrades.sort((a, b) -> Longs.compare(a.creationTimestamp, b.creationTimestamp));
}
if (limit != null && limit > 0) {
// Make sure to not return more than the limit
int upperLimit = Math.min(limit, crossChainTrades.size());
crossChainTrades = crossChainTrades.subList(0, upperLimit);
}
return crossChainTrades;
} catch (DataException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.REPOSITORY_ISSUE, e);
}
@@ -195,6 +207,11 @@ public class CrossChainResource {
if (minimumTimestamp != null) {
minimumFinalHeight = repository.getBlockRepository().getHeightFromTimestamp(minimumTimestamp);
// If not found in the block repository it will return either 0 or 1
if (minimumFinalHeight == 0 || minimumFinalHeight == 1) {
// Try the archive
minimumFinalHeight = repository.getBlockArchiveRepository().getHeightFromTimestamp(minimumTimestamp);
}
if (minimumFinalHeight == 0)
// We don't have any blocks since minimumTimestamp, let alone trades, so nothing to return
@@ -222,12 +239,30 @@ public class CrossChainResource {
// We also need block timestamp for use as trade timestamp
long timestamp = repository.getBlockRepository().getTimestampFromHeight(atState.getHeight());
if (timestamp == 0) {
// Try the archive
timestamp = repository.getBlockArchiveRepository().getTimestampFromHeight(atState.getHeight());
}
CrossChainTradeSummary crossChainTradeSummary = new CrossChainTradeSummary(crossChainTradeData, timestamp);
crossChainTrades.add(crossChainTradeSummary);
}
}
// Sort the trades by timestamp
if (reverse != null && reverse) {
crossChainTrades.sort((a, b) -> Longs.compare(b.getTradeTimestamp(), a.getTradeTimestamp()));
}
else {
crossChainTrades.sort((a, b) -> Longs.compare(a.getTradeTimestamp(), b.getTradeTimestamp()));
}
if (limit != null && limit > 0) {
// Make sure to not return more than the limit
int upperLimit = Math.min(limit, crossChainTrades.size());
crossChainTrades = crossChainTrades.subList(0, upperLimit);
}
return crossChainTrades;
} catch (DataException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.REPOSITORY_ISSUE, e);
@@ -260,7 +295,12 @@ public class CrossChainResource {
description = "Maximum number of trades to include in price calculation",
example = "10",
schema = @Schema(type = "integer", defaultValue = "10")
) @QueryParam("maxtrades") Integer maxtrades) {
) @QueryParam("maxtrades") Integer maxtrades,
@Parameter(
description = "Display price in terms of foreign currency per unit QORT",
example = "false",
schema = @Schema(type = "boolean", defaultValue = "false")
) @QueryParam("inverse") Boolean inverse) {
// foreignBlockchain is required
if (foreignBlockchain == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
@@ -270,6 +310,7 @@ public class CrossChainResource {
int maximumCount = maxtrades != null ? maxtrades : 10;
long minimumPeriod = 4 * 60 * 60 * 1000L; // ms
Boolean isFinished = Boolean.TRUE;
boolean useInversePrice = (inverse != null && inverse == true);
try (final Repository repository = RepositoryManager.getRepository()) {
Map<ByteArray, Supplier<ACCT>> acctsByCodeHash = SupportedBlockchain.getFilteredAcctMap(foreignBlockchain);
@@ -277,6 +318,9 @@ public class CrossChainResource {
long totalForeign = 0;
long totalQort = 0;
Map<Long, CrossChainTradeData> reverseSortedTradeData = new TreeMap<>(Collections.reverseOrder());
// Collect recent AT states for each ACCT version
for (Map.Entry<ByteArray, Supplier<ACCT>> acctInfo : acctsByCodeHash.entrySet()) {
byte[] codeHash = acctInfo.getKey().value;
ACCT acct = acctInfo.getValue().get();
@@ -285,13 +329,38 @@ public class CrossChainResource {
isFinished, acct.getModeByteOffset(), (long) AcctMode.REDEEMED.value, minimumCount, maximumCount, minimumPeriod);
for (ATStateData atState : atStates) {
// We also need block timestamp for use as trade timestamp
long timestamp = repository.getBlockRepository().getTimestampFromHeight(atState.getHeight());
if (timestamp == 0) {
// Try the archive
timestamp = repository.getBlockArchiveRepository().getTimestampFromHeight(atState.getHeight());
}
CrossChainTradeData crossChainTradeData = acct.populateTradeData(repository, atState);
totalForeign += crossChainTradeData.expectedForeignAmount;
totalQort += crossChainTradeData.qortAmount;
reverseSortedTradeData.put(timestamp, crossChainTradeData);
}
}
return Amounts.scaledDivide(totalQort, totalForeign);
// Loop through the sorted map and calculate the average price
// Also remove elements beyond the maxtrades limit
Set set = reverseSortedTradeData.entrySet();
Iterator i = set.iterator();
int index = 0;
while (i.hasNext()) {
Map.Entry tradeDataMap = (Map.Entry)i.next();
CrossChainTradeData crossChainTradeData = (CrossChainTradeData) tradeDataMap.getValue();
if (maxtrades != null && index >= maxtrades) {
// We've reached the limit
break;
}
totalForeign += crossChainTradeData.expectedForeignAmount;
totalQort += crossChainTradeData.qortAmount;
index++;
}
return useInversePrice ? Amounts.scaledDivide(totalForeign, totalQort) : Amounts.scaledDivide(totalQort, totalForeign);
} catch (DataException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.REPOSITORY_ISSUE, e);
}
@@ -421,4 +490,4 @@ public class CrossChainResource {
}
}
}
}

7
src/main/java/org/qortal/api/resource/CrossChainTradeBotResource.java
View File

@@ -30,6 +30,7 @@ import org.qortal.api.Security;
import org.qortal.api.model.crosschain.TradeBotCreateRequest;
import org.qortal.api.model.crosschain.TradeBotRespondRequest;
import org.qortal.asset.Asset;
import org.qortal.controller.Controller;
import org.qortal.controller.tradebot.AcctTradeBot;
import org.qortal.controller.tradebot.TradeBot;
import org.qortal.crosschain.ForeignBlockchain;
@@ -136,6 +137,9 @@ public class CrossChainTradeBotResource {
if (tradeBotCreateRequest.qortAmount <= 0 || tradeBotCreateRequest.fundingQortAmount <= 0)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.ORDER_SIZE_TOO_SMALL);
if (!Controller.getInstance().isUpToDate())
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.BLOCKCHAIN_NEEDS_SYNC);
try (final Repository repository = RepositoryManager.getRepository()) {
// Do some simple checking first
Account creator = new PublicKeyAccount(repository, tradeBotCreateRequest.creatorPublicKey);
@@ -193,6 +197,9 @@ public class CrossChainTradeBotResource {
if (tradeBotRespondRequest.receivingAddress == null || !Crypto.isValidAddress(tradeBotRespondRequest.receivingAddress))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_ADDRESS);
if (!Controller.getInstance().isUpToDate())
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.BLOCKCHAIN_NEEDS_SYNC);
// Extract data from cross-chain trading AT
try (final Repository repository = RepositoryManager.getRepository()) {
ATData atData = fetchAtDataWithChecking(repository, atAddress);

131
src/main/java/org/qortal/api/resource/ListsResource.java
View File

@@ -9,7 +9,7 @@ import io.swagger.v3.oas.annotations.responses.ApiResponse;
import io.swagger.v3.oas.annotations.tags.Tag;
import org.qortal.api.*;
import org.qortal.api.model.AddressListRequest;
import org.qortal.api.model.ListRequest;
import org.qortal.crypto.Crypto;
import org.qortal.data.account.AccountData;
import org.qortal.list.ResourceListManager;
@@ -29,39 +29,9 @@ public class ListsResource {
@Context
HttpServletRequest request;
@POST
@Path("/blacklist/address/{address}")
@Operation(
summary = "Add a QORT address to the local blacklist",
responses = {
@ApiResponse(
description = "Returns true on success, or an exception on failure",
content = @Content(mediaType = MediaType.TEXT_PLAIN, schema = @Schema(type = "boolean"))
)
}
)
@ApiErrors({ApiError.INVALID_ADDRESS, ApiError.ADDRESS_UNKNOWN, ApiError.REPOSITORY_ISSUE})
public String addAddressToBlacklist(@PathParam("address") String address) {
Security.checkApiCallAllowed(request);
if (!Crypto.isValidAddress(address))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_ADDRESS);
try (final Repository repository = RepositoryManager.getRepository()) {
AccountData accountData = repository.getAccountRepository().getAccount(address);
// Not found?
if (accountData == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.ADDRESS_UNKNOWN);
// Valid address, so go ahead and blacklist it
boolean success = ResourceListManager.getInstance().addAddressToBlacklist(address, true);
return success ? "true" : "false";
} catch (DataException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.REPOSITORY_ISSUE, e);
}
}
/* Address blacklist */
@POST
@Path("/blacklist/addresses")
@@ -72,7 +42,7 @@ public class ListsResource {
content = @Content(
mediaType = MediaType.APPLICATION_JSON,
schema = @Schema(
implementation = AddressListRequest.class
implementation = ListRequest.class
)
)
),
@@ -86,10 +56,10 @@ public class ListsResource {
}
)
@ApiErrors({ApiError.INVALID_ADDRESS, ApiError.ADDRESS_UNKNOWN, ApiError.REPOSITORY_ISSUE})
public String addAddressesToBlacklist(AddressListRequest addressListRequest) {
public String addAddressesToBlacklist(ListRequest listRequest) {
Security.checkApiCallAllowed(request);
if (addressListRequest == null || addressListRequest.addresses == null) {
if (listRequest == null || listRequest.items == null) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
}
@@ -98,7 +68,7 @@ public class ListsResource {
try (final Repository repository = RepositoryManager.getRepository()) {
for (String address : addressListRequest.addresses) {
for (String address : listRequest.items) {
if (!Crypto.isValidAddress(address)) {
errorCount++;
@@ -113,7 +83,7 @@ public class ListsResource {
}
// Valid address, so go ahead and blacklist it
boolean success = ResourceListManager.getInstance().addAddressToBlacklist(address, false);
boolean success = ResourceListManager.getInstance().addToList("blacklist", "addresses", address, false);
if (success) {
successCount++;
}
@@ -127,50 +97,16 @@ public class ListsResource {
if (successCount > 0 && errorCount == 0) {
// All were successful, so save the blacklist
ResourceListManager.getInstance().saveBlacklist();
ResourceListManager.getInstance().saveList("blacklist", "addresses");
return "true";
}
else {
// Something went wrong, so revert
ResourceListManager.getInstance().revertBlacklist();
ResourceListManager.getInstance().revertList("blacklist", "addresses");
return "false";
}
}
@DELETE
@Path("/blacklist/address/{address}")
@Operation(
summary = "Remove a QORT address from the local blacklist",
responses = {
@ApiResponse(
description = "Returns true on success, or an exception on failure",
content = @Content(mediaType = MediaType.TEXT_PLAIN, schema = @Schema(type = "boolean"))
)
}
)
@ApiErrors({ApiError.INVALID_ADDRESS, ApiError.ADDRESS_UNKNOWN, ApiError.REPOSITORY_ISSUE})
public String removeAddressFromBlacklist(@PathParam("address") String address) {
Security.checkApiCallAllowed(request);
if (!Crypto.isValidAddress(address))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_ADDRESS);
try (final Repository repository = RepositoryManager.getRepository()) {
AccountData accountData = repository.getAccountRepository().getAccount(address);
// Not found?
if (accountData == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.ADDRESS_UNKNOWN);
// Valid address, so go ahead and blacklist it
boolean success = ResourceListManager.getInstance().removeAddressFromBlacklist(address, true);
return success ? "true" : "false";
} catch (DataException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.REPOSITORY_ISSUE, e);
}
}
@DELETE
@Path("/blacklist/addresses")
@Operation(
@@ -180,7 +116,7 @@ public class ListsResource {
content = @Content(
mediaType = MediaType.APPLICATION_JSON,
schema = @Schema(
implementation = AddressListRequest.class
implementation = ListRequest.class
)
)
),
@@ -194,10 +130,10 @@ public class ListsResource {
}
)
@ApiErrors({ApiError.INVALID_ADDRESS, ApiError.ADDRESS_UNKNOWN, ApiError.REPOSITORY_ISSUE})
public String removeAddressesFromBlacklist(AddressListRequest addressListRequest) {
public String removeAddressesFromBlacklist(ListRequest listRequest) {
Security.checkApiCallAllowed(request);
if (addressListRequest == null || addressListRequest.addresses == null) {
if (listRequest == null || listRequest.items == null) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_CRITERIA);
}
@@ -206,7 +142,7 @@ public class ListsResource {
try (final Repository repository = RepositoryManager.getRepository()) {
for (String address : addressListRequest.addresses) {
for (String address : listRequest.items) {
if (!Crypto.isValidAddress(address)) {
errorCount++;
@@ -222,7 +158,7 @@ public class ListsResource {
// Valid address, so go ahead and blacklist it
// Don't save as we will do this at the end of the process
boolean success = ResourceListManager.getInstance().removeAddressFromBlacklist(address, false);
boolean success = ResourceListManager.getInstance().removeFromList("blacklist", "addresses", address, false);
if (success) {
successCount++;
}
@@ -236,12 +172,12 @@ public class ListsResource {
if (successCount > 0 && errorCount == 0) {
// All were successful, so save the blacklist
ResourceListManager.getInstance().saveBlacklist();
ResourceListManager.getInstance().saveList("blacklist", "addresses");
return "true";
}
else {
// Something went wrong, so revert
ResourceListManager.getInstance().revertBlacklist();
ResourceListManager.getInstance().revertList("blacklist", "addresses");
return "false";
}
}
@@ -259,40 +195,7 @@ public class ListsResource {
)
public String getAddressBlacklist() {
Security.checkApiCallAllowed(request);
return ResourceListManager.getInstance().getBlacklistJSONString();
}
@GET
@Path("/blacklist/address/{address}")
@Operation(
summary = "Check if an address is present in the local blacklist",
responses = {
@ApiResponse(
description = "Returns true or false if the list was queried, or an exception on failure",
content = @Content(mediaType = MediaType.TEXT_PLAIN, schema = @Schema(type = "boolean"))
)
}
)
@ApiErrors({ApiError.INVALID_ADDRESS, ApiError.ADDRESS_UNKNOWN, ApiError.REPOSITORY_ISSUE})
public String checkAddressInBlacklist(@PathParam("address") String address) {
Security.checkApiCallAllowed(request);
if (!Crypto.isValidAddress(address))
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.INVALID_ADDRESS);
try (final Repository repository = RepositoryManager.getRepository()) {
AccountData accountData = repository.getAccountRepository().getAccount(address);
// Not found?
if (accountData == null)
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.ADDRESS_UNKNOWN);
// Valid address, so go ahead and blacklist it
boolean blacklisted = ResourceListManager.getInstance().isAddressInBlacklist(address);
return blacklisted ? "true" : "false";
} catch (DataException e) {
throw ApiExceptionFactory.INSTANCE.createException(request, ApiError.REPOSITORY_ISSUE, e);
}
return ResourceListManager.getInstance().getJSONStringForList("blacklist", "addresses");
}
}

16
src/main/java/org/qortal/controller/BlockMinter.java
View File

@@ -16,6 +16,7 @@ import org.qortal.account.PrivateKeyAccount;
import org.qortal.block.Block;
import org.qortal.block.Block.ValidationResult;
import org.qortal.block.BlockChain;
import org.qortal.data.account.AccountData;
import org.qortal.data.account.MintingAccountData;
import org.qortal.data.account.RewardShareData;
import org.qortal.data.block.BlockData;
@@ -47,6 +48,11 @@ public class BlockMinter extends Thread {
// Recovery
public static final long INVALID_BLOCK_RECOVERY_TIMEOUT = 10 * 60 * 1000L; // ms
// Min account level to submit blocks
// This is an unvalidated version of Blockchain.minAccountLevelToMint
// and exists only to reduce block candidates by default.
private static int MIN_LEVEL_FOR_BLOCK_SUBMISSION = 3;
// Constructors
public BlockMinter() {
@@ -130,6 +136,16 @@ public class BlockMinter extends Thread {
madi.remove();
continue;
}
// Optional (non-validated) prevention of block submissions below a defined level
AccountData accountData = repository.getAccountRepository().getAccount(mintingAccount.getAddress());
if (accountData != null) {
Integer level = accountData.getLevel();
if (level != null && level < MIN_LEVEL_FOR_BLOCK_SUBMISSION) {
madi.remove();
continue;
}
}
}
List<Peer> peers = Network.getInstance().getHandshakedPeers();

7
src/main/java/org/qortal/controller/Controller.java
View File

@@ -103,6 +103,7 @@ public class Controller extends Thread {
static {
// This must go before any calls to LogManager/Logger
System.setProperty("log4j2.formatMsgNoLookups", "true");
System.setProperty("java.util.logging.manager", "org.apache.logging.log4j.jul.LogManager");
}
@@ -437,10 +438,12 @@ public class Controller extends Thread {
return; // Not System.exit() so that GUI can display error
}
// Rebuild Names table and check database integrity
// Rebuild Names table and check database integrity (if enabled)
NamesDatabaseIntegrityCheck namesDatabaseIntegrityCheck = new NamesDatabaseIntegrityCheck();
namesDatabaseIntegrityCheck.rebuildAllNames();
namesDatabaseIntegrityCheck.runIntegrityCheck();
if (Settings.getInstance().isNamesIntegrityCheckEnabled()) {
namesDatabaseIntegrityCheck.runIntegrityCheck();
}
LOGGER.info("Validating blockchain");
try {

2
src/main/java/org/qortal/controller/repository/BlockArchiver.java
View File

@@ -38,7 +38,7 @@ public class BlockArchiver implements Runnable {
return;
}
LOGGER.info("Starting block archiver...");
LOGGER.info("Starting block archiver from height {}...", startHeight);
while (!Controller.isStopping()) {
repository.discardChanges();

7
src/main/java/org/qortal/controller/repository/NamesDatabaseIntegrityCheck.java
View File

@@ -187,7 +187,12 @@ public class NamesDatabaseIntegrityCheck {
// The old name will then be unregistered, or re-registered.
// FUTURE: check database integrity for names that have been updated and then the original name re-registered
else if (Objects.equals(updateNameTransactionData.getName(), registeredName)) {
NameData newNameData = repository.getNameRepository().fromName(updateNameTransactionData.getNewName());
String newName = updateNameTransactionData.getNewName();
if (newName == null || newName.length() == 0) {
// If new name is blank (or maybe null, just to be safe), it means that it stayed the same
newName = registeredName;
}
NameData newNameData = repository.getNameRepository().fromName(newName);
if (!Objects.equals(creator.getAddress(), newNameData.getOwner())) {
LOGGER.info("Error: registered name {} is owned by {}, but it should be {}",
updateNameTransactionData.getNewName(), newNameData.getOwner(), creator.getAddress());

5
src/main/java/org/qortal/controller/tradebot/DogecoinACCTv1TradeBot.java
View File

@@ -201,7 +201,7 @@ public class DogecoinACCTv1TradeBot implements AcctTradeBot {
TradeBot.updateTradeBotState(repository, tradeBotData, () -> String.format("Built AT %s. Waiting for deployment", atAddress));
// Attempt to backup the trade bot data
TradeBot.backupTradeBotData(repository);
TradeBot.backupTradeBotData(repository, null);
// Return to user for signing and broadcast as we don't have their Qortal private key
try {
@@ -276,7 +276,8 @@ public class DogecoinACCTv1TradeBot implements AcctTradeBot {
crossChainTradeData.expectedForeignAmount, xprv58, null, lockTimeA, receivingPublicKeyHash);
// Attempt to backup the trade bot data
TradeBot.backupTradeBotData(repository);
// 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;

884
src/main/java/org/qortal/controller/tradebot/DogecoinACCTv2TradeBot.java Normal file
View File

@@ -0,0 +1,884 @@
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 DogecoinACCTv2TradeBot implements AcctTradeBot {
private static final Logger LOGGER = LogManager.getLogger(DogecoinACCTv2TradeBot.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 DogecoinACCTv2TradeBot 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 DogecoinACCTv2TradeBot() {
}
public static synchronized DogecoinACCTv2TradeBot getInstance() {
if (instance == null)
instance = new DogecoinACCTv2TradeBot();
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 DOGE.
* <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 Dogecoin) 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'/Dogecoin public key hash - used by Alice's P2SH scripts to allow redeem</li>
* <li>QORT amount on offer by Bob</li>
* <li>DOGE 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 Dogecoin receiving address into public key hash (we only support P2PKH at this time)
Address dogecoinReceivingAddress;
try {
dogecoinReceivingAddress = Address.fromString(Dogecoin.getInstance().getNetworkParameters(), tradeBotCreateRequest.receivingAddress);
} catch (AddressFormatException e) {
throw new DataException("Unsupported Dogecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
}
if (dogecoinReceivingAddress.getOutputScriptType() != ScriptType.P2PKH)
throw new DataException("Unsupported Dogecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
byte[] dogecoinReceivingAccountInfo = dogecoinReceivingAddress.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/DOGE ACCT";
String description = "QORT/DOGE cross-chain trade";
String aTType = "ACCT";
String tags = "ACCT QORT DOGE";
byte[] creationBytes = DogecoinACCTv2.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, DogecoinACCTv2.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.DOGECOIN.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
tradeBotCreateRequest.foreignAmount, null, null, null, dogecoinReceivingAccountInfo);
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 DOGE to an existing offer.
* <p>
* Requires a chosen trade offer from Bob, passed by <tt>crossChainTradeData</tt>
* and access to a Dogecoin 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 Dogecoin 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 Dogecoin main-net)
* or 'tprv' for (Dogecoin 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 Dogecoin amount expected by 'Bob'.
* <p>
* If the Dogecoin 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 Dogecoin 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, DogecoinACCTv2.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.DOGECOIN.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 = Dogecoin.getInstance().getP2shFee(now);
} catch (ForeignBlockchainException e) {
LOGGER.debug("Couldn't estimate Dogecoin 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 = Dogecoin.getInstance().deriveP2shAddress(redeemScriptBytes);
// Build transaction for funding P2SH-A
Transaction p2shFundingTransaction = Dogecoin.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 {
Dogecoin.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 = DogecoinACCTv2.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:
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 = DogecoinACCTv2.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 Dogecoin 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;
}
Dogecoin dogecoin = Dogecoin.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 Dogecoin pubkeyhash and lockTime-A
byte[] messageData = messageTransactionData.getData();
DogecoinACCTv2.OfferMessageData offerMessageData = DogecoinACCTv2.extractOfferMessageData(messageData);
if (offerMessageData == null)
continue;
byte[] aliceForeignPublicKeyHash = offerMessageData.partnerDogecoinPKH;
byte[] hashOfSecretA = offerMessageData.hashOfSecretA;
int lockTimeA = (int) offerMessageData.lockTimeA;
long messageTimestamp = messageTransactionData.getTimestamp();
int refundTimeout = DogecoinACCTv2.calcRefundTimeout(messageTimestamp, lockTimeA);
// Determine P2SH-A address and confirm funded
byte[] redeemScriptA = BitcoinyHTLC.buildScript(aliceForeignPublicKeyHash, lockTimeA, tradeBotData.getTradeForeignPublicKeyHash(), hashOfSecretA);
String p2shAddressA = dogecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
final long minimumAmountA = tradeBotData.getForeignAmount() + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = DogecoinACCTv2.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 DOGE 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;
Dogecoin dogecoin = Dogecoin.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 = dogecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = DogecoinACCTv2.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 = DogecoinACCTv2.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 DOGE 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 DOGE funds from P2SH-A
* to Bob's 'foreign'/Dogecoin trade legacy-format address, as derived from trade private key.
* <p>
* (This could potentially be 'improved' to send DOGE 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 DOGE
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s has auto-refunded - trade aborted", tradeBotData.getAtAddress()));
return;
}
byte[] secretA = DogecoinACCTv2.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
Dogecoin dogecoin = Dogecoin.getInstance();
byte[] receivingAccountInfo = tradeBotData.getReceivingAccountInfo();
int lockTimeA = crossChainTradeData.lockTimeA;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(crossChainTradeData.partnerForeignPKH, lockTimeA, crossChainTradeData.creatorForeignPKH, crossChainTradeData.hashOfSecretA);
String p2shAddressA = dogecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = dogecoin.getUnspentOutputs(p2shAddressA);
Transaction p2shRedeemTransaction = BitcoinyHTLC.buildRedeemTransaction(dogecoin.getNetworkParameters(), redeemAmount, redeemKey,
fundingOutputs, redeemScriptA, secretA, receivingAccountInfo);
dogecoin.broadcastTransaction(p2shRedeemTransaction);
break;
}
}
String receivingAddress = dogecoin.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;
Dogecoin dogecoin = Dogecoin.getInstance();
// We can't refund P2SH-A until median block time has passed lockTime-A (see BIP113)
int medianBlockTime = dogecoin.getMedianBlockTime();
if (medianBlockTime <= lockTimeA)
return;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = dogecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = dogecoin.getUnspentOutputs(p2shAddressA);
// Determine receive address for refund
String receiveAddress = dogecoin.getUnusedReceiveAddress(tradeBotData.getForeignKey());
Address receiving = Address.fromString(dogecoin.getNetworkParameters(), receiveAddress);
Transaction p2shRefundTransaction = BitcoinyHTLC.buildRefundTransaction(dogecoin.getNetworkParameters(), refundAmount, refundKey,
fundingOutputs, redeemScriptA, lockTimeA, receiving.getHash());
dogecoin.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/DogecoinACCTv3TradeBot.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 DogecoinACCTv3TradeBot implements AcctTradeBot {
private static final Logger LOGGER = LogManager.getLogger(DogecoinACCTv3TradeBot.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 DogecoinACCTv3TradeBot 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 DogecoinACCTv3TradeBot() {
}
public static synchronized DogecoinACCTv3TradeBot getInstance() {
if (instance == null)
instance = new DogecoinACCTv3TradeBot();
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 DOGE.
* <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 Dogecoin) 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'/Dogecoin public key hash - used by Alice's P2SH scripts to allow redeem</li>
* <li>QORT amount on offer by Bob</li>
* <li>DOGE 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 Dogecoin receiving address into public key hash (we only support P2PKH at this time)
Address dogecoinReceivingAddress;
try {
dogecoinReceivingAddress = Address.fromString(Dogecoin.getInstance().getNetworkParameters(), tradeBotCreateRequest.receivingAddress);
} catch (AddressFormatException e) {
throw new DataException("Unsupported Dogecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
}
if (dogecoinReceivingAddress.getOutputScriptType() != ScriptType.P2PKH)
throw new DataException("Unsupported Dogecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
byte[] dogecoinReceivingAccountInfo = dogecoinReceivingAddress.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/DOGE ACCT";
String description = "QORT/DOGE cross-chain trade";
String aTType = "ACCT";
String tags = "ACCT QORT DOGE";
byte[] creationBytes = DogecoinACCTv3.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, DogecoinACCTv3.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.DOGECOIN.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
tradeBotCreateRequest.foreignAmount, null, null, null, dogecoinReceivingAccountInfo);
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 DOGE to an existing offer.
* <p>
* Requires a chosen trade offer from Bob, passed by <tt>crossChainTradeData</tt>
* and access to a Dogecoin 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 Dogecoin 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 Dogecoin main-net)
* or 'tprv' for (Dogecoin 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 Dogecoin amount expected by 'Bob'.
* <p>
* If the Dogecoin 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 Dogecoin 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, DogecoinACCTv3.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.DOGECOIN.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 = Dogecoin.getInstance().getP2shFee(now);
} catch (ForeignBlockchainException e) {
LOGGER.debug("Couldn't estimate Dogecoin 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 = Dogecoin.getInstance().deriveP2shAddress(redeemScriptBytes);
// Build transaction for funding P2SH-A
Transaction p2shFundingTransaction = Dogecoin.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 {
Dogecoin.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 = DogecoinACCTv3.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 = DogecoinACCTv3.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 Dogecoin 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;
}
Dogecoin dogecoin = Dogecoin.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 Dogecoin pubkeyhash and lockTime-A
byte[] messageData = messageTransactionData.getData();
DogecoinACCTv3.OfferMessageData offerMessageData = DogecoinACCTv3.extractOfferMessageData(messageData);
if (offerMessageData == null)
continue;
byte[] aliceForeignPublicKeyHash = offerMessageData.partnerDogecoinPKH;
byte[] hashOfSecretA = offerMessageData.hashOfSecretA;
int lockTimeA = (int) offerMessageData.lockTimeA;
long messageTimestamp = messageTransactionData.getTimestamp();
int refundTimeout = DogecoinACCTv3.calcRefundTimeout(messageTimestamp, lockTimeA);
// Determine P2SH-A address and confirm funded
byte[] redeemScriptA = BitcoinyHTLC.buildScript(aliceForeignPublicKeyHash, lockTimeA, tradeBotData.getTradeForeignPublicKeyHash(), hashOfSecretA);
String p2shAddressA = dogecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
final long minimumAmountA = tradeBotData.getForeignAmount() + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = DogecoinACCTv3.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 DOGE 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;
Dogecoin dogecoin = Dogecoin.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 = dogecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = DogecoinACCTv3.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 = DogecoinACCTv3.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 DOGE 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 DOGE funds from P2SH-A
* to Bob's 'foreign'/Dogecoin trade legacy-format address, as derived from trade private key.
* <p>
* (This could potentially be 'improved' to send DOGE 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 DOGE
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s has auto-refunded - trade aborted", tradeBotData.getAtAddress()));
return;
}
byte[] secretA = DogecoinACCTv3.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
Dogecoin dogecoin = Dogecoin.getInstance();
byte[] receivingAccountInfo = tradeBotData.getReceivingAccountInfo();
int lockTimeA = crossChainTradeData.lockTimeA;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(crossChainTradeData.partnerForeignPKH, lockTimeA, crossChainTradeData.creatorForeignPKH, crossChainTradeData.hashOfSecretA);
String p2shAddressA = dogecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = dogecoin.getUnspentOutputs(p2shAddressA);
Transaction p2shRedeemTransaction = BitcoinyHTLC.buildRedeemTransaction(dogecoin.getNetworkParameters(), redeemAmount, redeemKey,
fundingOutputs, redeemScriptA, secretA, receivingAccountInfo);
dogecoin.broadcastTransaction(p2shRedeemTransaction);
break;
}
}
String receivingAddress = dogecoin.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;
Dogecoin dogecoin = Dogecoin.getInstance();
// We can't refund P2SH-A until median block time has passed lockTime-A (see BIP113)
int medianBlockTime = dogecoin.getMedianBlockTime();
if (medianBlockTime <= lockTimeA)
return;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = dogecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Dogecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(dogecoin.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 = dogecoin.getUnspentOutputs(p2shAddressA);
// Determine receive address for refund
String receiveAddress = dogecoin.getUnusedReceiveAddress(tradeBotData.getForeignKey());
Address receiving = Address.fromString(dogecoin.getNetworkParameters(), receiveAddress);
Transaction p2shRefundTransaction = BitcoinyHTLC.buildRefundTransaction(dogecoin.getNetworkParameters(), refundAmount, refundKey,
fundingOutputs, redeemScriptA, lockTimeA, receiving.getHash());
dogecoin.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;
}
}

5
src/main/java/org/qortal/controller/tradebot/LitecoinACCTv1TradeBot.java
View File

@@ -212,7 +212,7 @@ public class LitecoinACCTv1TradeBot implements AcctTradeBot {
TradeBot.updateTradeBotState(repository, tradeBotData, () -> String.format("Built AT %s. Waiting for deployment", atAddress));
// Attempt to backup the trade bot data
TradeBot.backupTradeBotData(repository);
TradeBot.backupTradeBotData(repository, null);
// Return to user for signing and broadcast as we don't have their Qortal private key
try {
@@ -287,7 +287,8 @@ public class LitecoinACCTv1TradeBot implements AcctTradeBot {
crossChainTradeData.expectedForeignAmount, xprv58, null, lockTimeA, receivingPublicKeyHash);
// Attempt to backup the trade bot data
TradeBot.backupTradeBotData(repository);
// 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;

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src/main/java/org/qortal/controller/tradebot/LitecoinACCTv2TradeBot.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 LitecoinACCTv2TradeBot implements AcctTradeBot {
private static final Logger LOGGER = LogManager.getLogger(LitecoinACCTv2TradeBot.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 LitecoinACCTv2TradeBot 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 LitecoinACCTv2TradeBot() {
}
public static synchronized LitecoinACCTv2TradeBot getInstance() {
if (instance == null)
instance = new LitecoinACCTv2TradeBot();
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 LTC.
* <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 Litecoin) 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'/Litecoin public key hash - used by Alice's P2SH scripts to allow redeem</li>
* <li>QORT amount on offer by Bob</li>
* <li>LTC 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 Litecoin receiving address into public key hash (we only support P2PKH at this time)
Address litecoinReceivingAddress;
try {
litecoinReceivingAddress = Address.fromString(Litecoin.getInstance().getNetworkParameters(), tradeBotCreateRequest.receivingAddress);
} catch (AddressFormatException e) {
throw new DataException("Unsupported Litecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
}
if (litecoinReceivingAddress.getOutputScriptType() != ScriptType.P2PKH)
throw new DataException("Unsupported Litecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
byte[] litecoinReceivingAccountInfo = litecoinReceivingAddress.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/LTC ACCT";
String description = "QORT/LTC cross-chain trade";
String aTType = "ACCT";
String tags = "ACCT QORT LTC";
byte[] creationBytes = LitecoinACCTv2.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, LitecoinACCTv2.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.LITECOIN.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
tradeBotCreateRequest.foreignAmount, null, null, null, litecoinReceivingAccountInfo);
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 LTC to an existing offer.
* <p>
* Requires a chosen trade offer from Bob, passed by <tt>crossChainTradeData</tt>
* and access to a Litecoin 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 Litecoin 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 Litecoin main-net)
* or 'tprv' for (Litecoin 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 Litecoin amount expected by 'Bob'.
* <p>
* If the Litecoin 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 Litecoin 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, LitecoinACCTv2.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.LITECOIN.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 = Litecoin.getInstance().getP2shFee(now);
} catch (ForeignBlockchainException e) {
LOGGER.debug("Couldn't estimate Litecoin 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 = Litecoin.getInstance().deriveP2shAddress(redeemScriptBytes);
// Build transaction for funding P2SH-A
Transaction p2shFundingTransaction = Litecoin.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 {
Litecoin.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 = LitecoinACCTv2.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 = LitecoinACCTv2.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 Litecoin 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;
}
Litecoin litecoin = Litecoin.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 Litecoin pubkeyhash and lockTime-A
byte[] messageData = messageTransactionData.getData();
LitecoinACCTv2.OfferMessageData offerMessageData = LitecoinACCTv2.extractOfferMessageData(messageData);
if (offerMessageData == null)
continue;
byte[] aliceForeignPublicKeyHash = offerMessageData.partnerLitecoinPKH;
byte[] hashOfSecretA = offerMessageData.hashOfSecretA;
int lockTimeA = (int) offerMessageData.lockTimeA;
long messageTimestamp = messageTransactionData.getTimestamp();
int refundTimeout = LitecoinACCTv2.calcRefundTimeout(messageTimestamp, lockTimeA);
// Determine P2SH-A address and confirm funded
byte[] redeemScriptA = BitcoinyHTLC.buildScript(aliceForeignPublicKeyHash, lockTimeA, tradeBotData.getTradeForeignPublicKeyHash(), hashOfSecretA);
String p2shAddressA = litecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
final long minimumAmountA = tradeBotData.getForeignAmount() + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = LitecoinACCTv2.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 LTC 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;
Litecoin litecoin = Litecoin.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 = litecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = LitecoinACCTv2.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 = LitecoinACCTv2.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 LTC 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 LTC funds from P2SH-A
* to Bob's 'foreign'/Litecoin trade legacy-format address, as derived from trade private key.
* <p>
* (This could potentially be 'improved' to send LTC 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 LTC
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s has auto-refunded - trade aborted", tradeBotData.getAtAddress()));
return;
}
byte[] secretA = LitecoinACCTv2.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
Litecoin litecoin = Litecoin.getInstance();
byte[] receivingAccountInfo = tradeBotData.getReceivingAccountInfo();
int lockTimeA = crossChainTradeData.lockTimeA;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(crossChainTradeData.partnerForeignPKH, lockTimeA, crossChainTradeData.creatorForeignPKH, crossChainTradeData.hashOfSecretA);
String p2shAddressA = litecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = litecoin.getUnspentOutputs(p2shAddressA);
Transaction p2shRedeemTransaction = BitcoinyHTLC.buildRedeemTransaction(litecoin.getNetworkParameters(), redeemAmount, redeemKey,
fundingOutputs, redeemScriptA, secretA, receivingAccountInfo);
litecoin.broadcastTransaction(p2shRedeemTransaction);
break;
}
}
String receivingAddress = litecoin.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;
Litecoin litecoin = Litecoin.getInstance();
// We can't refund P2SH-A until median block time has passed lockTime-A (see BIP113)
int medianBlockTime = litecoin.getMedianBlockTime();
if (medianBlockTime <= lockTimeA)
return;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = litecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = litecoin.getUnspentOutputs(p2shAddressA);
// Determine receive address for refund
String receiveAddress = litecoin.getUnusedReceiveAddress(tradeBotData.getForeignKey());
Address receiving = Address.fromString(litecoin.getNetworkParameters(), receiveAddress);
Transaction p2shRefundTransaction = BitcoinyHTLC.buildRefundTransaction(litecoin.getNetworkParameters(), refundAmount, refundKey,
fundingOutputs, redeemScriptA, lockTimeA, receiving.getHash());
litecoin.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/LitecoinACCTv3TradeBot.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 LitecoinACCTv3TradeBot implements AcctTradeBot {
private static final Logger LOGGER = LogManager.getLogger(LitecoinACCTv3TradeBot.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 LitecoinACCTv3TradeBot 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 LitecoinACCTv3TradeBot() {
}
public static synchronized LitecoinACCTv3TradeBot getInstance() {
if (instance == null)
instance = new LitecoinACCTv3TradeBot();
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 LTC.
* <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 Litecoin) 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'/Litecoin public key hash - used by Alice's P2SH scripts to allow redeem</li>
* <li>QORT amount on offer by Bob</li>
* <li>LTC 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 Litecoin receiving address into public key hash (we only support P2PKH at this time)
Address litecoinReceivingAddress;
try {
litecoinReceivingAddress = Address.fromString(Litecoin.getInstance().getNetworkParameters(), tradeBotCreateRequest.receivingAddress);
} catch (AddressFormatException e) {
throw new DataException("Unsupported Litecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
}
if (litecoinReceivingAddress.getOutputScriptType() != ScriptType.P2PKH)
throw new DataException("Unsupported Litecoin receiving address: " + tradeBotCreateRequest.receivingAddress);
byte[] litecoinReceivingAccountInfo = litecoinReceivingAddress.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/LTC ACCT";
String description = "QORT/LTC cross-chain trade";
String aTType = "ACCT";
String tags = "ACCT QORT LTC";
byte[] creationBytes = LitecoinACCTv3.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, LitecoinACCTv3.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.LITECOIN.name(),
tradeForeignPublicKey, tradeForeignPublicKeyHash,
tradeBotCreateRequest.foreignAmount, null, null, null, litecoinReceivingAccountInfo);
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 LTC to an existing offer.
* <p>
* Requires a chosen trade offer from Bob, passed by <tt>crossChainTradeData</tt>
* and access to a Litecoin 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 Litecoin 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 Litecoin main-net)
* or 'tprv' for (Litecoin 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 Litecoin amount expected by 'Bob'.
* <p>
* If the Litecoin 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 Litecoin 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, LitecoinACCTv3.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.LITECOIN.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 = Litecoin.getInstance().getP2shFee(now);
} catch (ForeignBlockchainException e) {
LOGGER.debug("Couldn't estimate Litecoin 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 = Litecoin.getInstance().deriveP2shAddress(redeemScriptBytes);
// Build transaction for funding P2SH-A
Transaction p2shFundingTransaction = Litecoin.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 {
Litecoin.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 = LitecoinACCTv3.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 = LitecoinACCTv3.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 Litecoin 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;
}
Litecoin litecoin = Litecoin.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 Litecoin pubkeyhash and lockTime-A
byte[] messageData = messageTransactionData.getData();
LitecoinACCTv3.OfferMessageData offerMessageData = LitecoinACCTv3.extractOfferMessageData(messageData);
if (offerMessageData == null)
continue;
byte[] aliceForeignPublicKeyHash = offerMessageData.partnerLitecoinPKH;
byte[] hashOfSecretA = offerMessageData.hashOfSecretA;
int lockTimeA = (int) offerMessageData.lockTimeA;
long messageTimestamp = messageTransactionData.getTimestamp();
int refundTimeout = LitecoinACCTv3.calcRefundTimeout(messageTimestamp, lockTimeA);
// Determine P2SH-A address and confirm funded
byte[] redeemScriptA = BitcoinyHTLC.buildScript(aliceForeignPublicKeyHash, lockTimeA, tradeBotData.getTradeForeignPublicKeyHash(), hashOfSecretA);
String p2shAddressA = litecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
final long minimumAmountA = tradeBotData.getForeignAmount() + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = LitecoinACCTv3.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 LTC 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;
Litecoin litecoin = Litecoin.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 = litecoin.deriveP2shAddress(redeemScriptA);
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = LitecoinACCTv3.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 = LitecoinACCTv3.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 LTC 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 LTC funds from P2SH-A
* to Bob's 'foreign'/Litecoin trade legacy-format address, as derived from trade private key.
* <p>
* (This could potentially be 'improved' to send LTC 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 LTC
TradeBot.updateTradeBotState(repository, tradeBotData, State.BOB_REFUNDED,
() -> String.format("AT %s has auto-refunded - trade aborted", tradeBotData.getAtAddress()));
return;
}
byte[] secretA = LitecoinACCTv3.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
Litecoin litecoin = Litecoin.getInstance();
byte[] receivingAccountInfo = tradeBotData.getReceivingAccountInfo();
int lockTimeA = crossChainTradeData.lockTimeA;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(crossChainTradeData.partnerForeignPKH, lockTimeA, crossChainTradeData.creatorForeignPKH, crossChainTradeData.hashOfSecretA);
String p2shAddressA = litecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = litecoin.getUnspentOutputs(p2shAddressA);
Transaction p2shRedeemTransaction = BitcoinyHTLC.buildRedeemTransaction(litecoin.getNetworkParameters(), redeemAmount, redeemKey,
fundingOutputs, redeemScriptA, secretA, receivingAccountInfo);
litecoin.broadcastTransaction(p2shRedeemTransaction);
break;
}
}
String receivingAddress = litecoin.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;
Litecoin litecoin = Litecoin.getInstance();
// We can't refund P2SH-A until median block time has passed lockTime-A (see BIP113)
int medianBlockTime = litecoin.getMedianBlockTime();
if (medianBlockTime <= lockTimeA)
return;
byte[] redeemScriptA = BitcoinyHTLC.buildScript(tradeBotData.getTradeForeignPublicKeyHash(), lockTimeA, crossChainTradeData.creatorForeignPKH, tradeBotData.getHashOfSecret());
String p2shAddressA = litecoin.deriveP2shAddress(redeemScriptA);
// Fee for redeem/refund is subtracted from P2SH-A balance.
long feeTimestamp = calcFeeTimestamp(lockTimeA, crossChainTradeData.tradeTimeout);
long p2shFee = Litecoin.getInstance().getP2shFee(feeTimestamp);
long minimumAmountA = crossChainTradeData.expectedForeignAmount + p2shFee;
BitcoinyHTLC.Status htlcStatusA = BitcoinyHTLC.determineHtlcStatus(litecoin.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 = litecoin.getUnspentOutputs(p2shAddressA);
// Determine receive address for refund
String receiveAddress = litecoin.getUnusedReceiveAddress(tradeBotData.getForeignKey());
Address receiving = Address.fromString(litecoin.getNetworkParameters(), receiveAddress);
Transaction p2shRefundTransaction = BitcoinyHTLC.buildRefundTransaction(litecoin.getNetworkParameters(), refundAmount, refundKey,
fundingOutputs, redeemScriptA, lockTimeA, receiving.getHash());
litecoin.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;
}
}

9
src/main/java/org/qortal/controller/tradebot/TradeBot.java
View File

@@ -31,6 +31,7 @@ import org.qortal.gui.SysTray;
import org.qortal.repository.DataException;
import org.qortal.repository.Repository;
import org.qortal.repository.RepositoryManager;
import org.qortal.repository.hsqldb.HSQLDBImportExport;
import org.qortal.settings.Settings;
import org.qortal.transaction.PresenceTransaction;
import org.qortal.transaction.PresenceTransaction.PresenceType;
@@ -76,7 +77,11 @@ public class TradeBot implements Listener {
static {
acctTradeBotSuppliers.put(BitcoinACCTv1.class, BitcoinACCTv1TradeBot::getInstance);
acctTradeBotSuppliers.put(LitecoinACCTv1.class, LitecoinACCTv1TradeBot::getInstance);
acctTradeBotSuppliers.put(LitecoinACCTv2.class, LitecoinACCTv2TradeBot::getInstance);
acctTradeBotSuppliers.put(LitecoinACCTv3.class, LitecoinACCTv3TradeBot::getInstance);
acctTradeBotSuppliers.put(DogecoinACCTv1.class, DogecoinACCTv1TradeBot::getInstance);
acctTradeBotSuppliers.put(DogecoinACCTv2.class, DogecoinACCTv2TradeBot::getInstance);
acctTradeBotSuppliers.put(DogecoinACCTv3.class, DogecoinACCTv3TradeBot::getInstance);
}
private static TradeBot instance;
@@ -265,11 +270,11 @@ public class TradeBot implements Listener {
return secret;
}
/*package*/ static void backupTradeBotData(Repository repository) {
/*package*/ static void backupTradeBotData(Repository repository, List<TradeBotData> additional) {
// Attempt to backup the trade bot data. This an optional step and doesn't impact trading, so don't throw an exception on failure
try {
LOGGER.info("About to backup trade bot data...");
repository.exportNodeLocalData();
HSQLDBImportExport.backupTradeBotStates(repository, additional);
} catch (DataException e) {
LOGGER.info(String.format("Repository issue when exporting trade bot data: %s", e.getMessage()));
}

34
src/main/java/org/qortal/crosschain/Bitcoin.java
View File

@@ -42,36 +42,30 @@ public class Bitcoin extends Bitcoiny {
public Collection<ElectrumX.Server> getServers() {
return Arrays.asList(
// Servers chosen on NO BASIS WHATSOEVER from various sources!
new Server("128.0.190.26", Server.ConnectionType.SSL, 50002),
new Server("hodlers.beer", Server.ConnectionType.SSL, 50002),
new Server("electrumx.erbium.eu", Server.ConnectionType.TCP, 50001),
new Server("electrumx.erbium.eu", Server.ConnectionType.SSL, 50002),
new Server("btc.lastingcoin.net", Server.ConnectionType.SSL, 50002),
new Server("electrum.bitaroo.net", Server.ConnectionType.SSL, 50002),
new Server("bitcoin.grey.pw", Server.ConnectionType.SSL, 50002),
new Server("2electrumx.hopto.me", Server.ConnectionType.SSL, 56022),
new Server("185.64.116.15", Server.ConnectionType.SSL, 50002),
new Server("kirsche.emzy.de", Server.ConnectionType.SSL, 50002),
new Server("alviss.coinjoined.com", Server.ConnectionType.SSL, 50002),
new Server("electrum.emzy.de", Server.ConnectionType.SSL, 50002),
new Server("electrum.emzy.de", Server.ConnectionType.TCP, 50001),
new Server("vmd71287.contaboserver.net", Server.ConnectionType.SSL, 50002),
new Server("btc.litepay.ch", Server.ConnectionType.SSL, 50002),
new Server("electrum.stippy.com", Server.ConnectionType.SSL, 50002),
new Server("xtrum.com", Server.ConnectionType.SSL, 50002),
new Server("electrum.acinq.co", Server.ConnectionType.SSL, 50002),
new Server("electrum2.taborsky.cz", Server.ConnectionType.SSL, 50002),
new Server("vmd63185.contaboserver.net", Server.ConnectionType.SSL, 50002),
new Server("electrum2.privateservers.network", Server.ConnectionType.SSL, 50002),
new Server("electrumx.alexridevski.net", Server.ConnectionType.SSL, 50002),
new Server("192.166.219.200", Server.ConnectionType.SSL, 50002),
new Server("2ex.digitaleveryware.com", Server.ConnectionType.SSL, 50002),
new Server("dxm.no-ip.biz", Server.ConnectionType.SSL, 50002),
new Server("caleb.vegas", Server.ConnectionType.SSL, 50002),
new Server("ecdsa.net", Server.ConnectionType.SSL, 110),
new Server("electrum.hsmiths.com", Server.ConnectionType.SSL, 995),
new Server("elec.luggs.co", Server.ConnectionType.SSL, 443),
new Server("btc.smsys.me", Server.ConnectionType.SSL, 995));
new Server("electrum.coinext.com.br", Server.ConnectionType.TCP, 50001),
new Server("korea.electrum-server.com", Server.ConnectionType.TCP, 50001),
new Server("eai.coincited.net", Server.ConnectionType.TCP, 50001),
new Server("electrum.coinext.com.br", Server.ConnectionType.SSL, 50002),
new Server("node1.btccuracao.com", Server.ConnectionType.SSL, 50002),
new Server("korea.electrum-server.com", Server.ConnectionType.SSL, 50002),
new Server("btce.iiiiiii.biz", Server.ConnectionType.SSL, 50002),
new Server("bitcoin.lukechilds.co", Server.ConnectionType.SSL, 50002),
new Server("guichet.centure.cc", Server.ConnectionType.SSL, 50002),
new Server("electrumx.hodlwallet.com", Server.ConnectionType.SSL, 50002),
new Server("eai.coincited.net", Server.ConnectionType.SSL, 50002),
new Server("prospero.bitsrc.net", Server.ConnectionType.SSL, 50002),
new Server("gd42.org", Server.ConnectionType.SSL, 50002),
new Server("electrum.pabu.io", Server.ConnectionType.SSL, 50002));
}
@Override

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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 Dogecoin & 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 Dogecoin & Qortal 'trade' keys</li>
* <li>Alice funds Dogecoin 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' Dogecoin 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 Dogecoin 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 Dogecoin trade key and secret-A</li>
* <li>P2SH-A DOGE funds end up at Dogecoin address determined by redeem transaction output(s)</li>
* </ul>
* </li>
* </ul>
*/
public class DogecoinACCTv2 implements ACCT {
private static final Logger LOGGER = LogManager.getLogger(DogecoinACCTv2.class);
public static final String NAME = DogecoinACCTv2.class.getSimpleName();
public static final byte[] CODE_BYTES_HASH = HashCode.fromString("6fff38d6eeb06568a9c879c5628527730319844aa0de53f5f4ffab5506efe885").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[] partnerDogecoinPKH;
public byte[] hashOfSecretA;
public long lockTimeA;
}
public static final int OFFER_MESSAGE_LENGTH = 20 /*partnerDogecoinPKH*/ + 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 Dogecoin 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 DogecoinACCTv2 instance;
private DogecoinACCTv2() {
}
public static synchronized DogecoinACCTv2 getInstance() {
if (instance == null)
instance = new DogecoinACCTv2();
return instance;
}
@Override
public byte[] getCodeBytesHash() {
return CODE_BYTES_HASH;
}
@Override
public int getModeByteOffset() {
return MODE_BYTE_OFFSET;
}
@Override
public ForeignBlockchain getBlockchain() {
return Dogecoin.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 dogecoinPublicKeyHash 20-byte HASH160 of creator's trade Dogecoin public key
* @param qortAmount how much QORT to pay trade partner if they send correct 32-byte secrets to AT
* @param dogecoinAmount how much DOGE the AT creator is expecting to trade
* @param tradeTimeout suggested timeout for entire trade
*/
public static byte[] buildQortalAT(String creatorTradeAddress, byte[] dogecoinPublicKeyHash, long qortAmount, long dogecoinAmount, int tradeTimeout) {
if (dogecoinPublicKeyHash.length != 20)
throw new IllegalArgumentException("Dogecoin 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 addrDogecoinPublicKeyHash = addrCounter;
addrCounter += 4;
final int addrQortAmount = addrCounter++;
final int addrDogecoinAmount = 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 addrTradeMessagePartnerDogecoinPKHOffset = addrCounter++;
final int addrPartnerDogecoinPKHPointer = 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 addrPartnerDogecoinPKH = 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));
// Dogecoin public key hash
assert dataByteBuffer.position() == addrDogecoinPublicKeyHash * MachineState.VALUE_SIZE : "addrDogecoinPublicKeyHash incorrect";
dataByteBuffer.put(Bytes.ensureCapacity(dogecoinPublicKeyHash, 32, 0));
// Redeem Qort amount
assert dataByteBuffer.position() == addrQortAmount * MachineState.VALUE_SIZE : "addrQortAmount incorrect";
dataByteBuffer.putLong(qortAmount);
// Expected Dogecoin amount
assert dataByteBuffer.position() == addrDogecoinAmount * MachineState.VALUE_SIZE : "addrDogecoinAmount incorrect";
dataByteBuffer.putLong(dogecoinAmount);
// 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 Dogecoin PKH
assert dataByteBuffer.position() == addrTradeMessagePartnerDogecoinPKHOffset * MachineState.VALUE_SIZE : "addrTradeMessagePartnerDogecoinPKHOffset incorrect";
dataByteBuffer.putLong(32L);
// Index into data segment of partner's Dogecoin PKH, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerDogecoinPKHPointer * MachineState.VALUE_SIZE : "addrPartnerDogecoinPKHPointer incorrect";
dataByteBuffer.putLong(addrPartnerDogecoinPKH);
// 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 */
/* NOP - to ensure DOGECOIN ACCT is unique */
codeByteBuffer.put(OpCode.NOP.compile());
// 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));
// 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 Dogecoin 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, addrTradeMessagePartnerDogecoinPKHOffset));
// Store partner's Dogecoin PKH (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerDogecoinPKHPointer));
// 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();
/* Sleep until message arrives */
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.SLEEP_UNTIL_MESSAGE.value, addrLastTxnTimestamp));
// 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 DOGE-QORT ACCT?", e);
}
}
codeByteBuffer.flip();
byte[] codeBytes = new byte[codeByteBuffer.limit()];
codeByteBuffer.get(codeBytes);
assert Arrays.equals(Crypto.digest(codeBytes), DogecoinACCTv2.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.DOGECOIN.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 Dogecoin/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 DOGE 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 Dogecoin PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Dogecoin 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 Dogecoin PKH
byte[] partnerDogecoinPKH = new byte[20];
dataByteBuffer.get(partnerDogecoinPKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerDogecoinPKH.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 = partnerDogecoinPKH;
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.partnerDogecoinPKH = 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/DogecoinACCTv3.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 Dogecoin & 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 Dogecoin & Qortal 'trade' keys</li>
* <li>Alice funds Dogecoin 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' Dogecoin 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 Dogecoin 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 Dogecoin trade key and secret-A</li>
* <li>P2SH-A DOGE funds end up at Dogecoin address determined by redeem transaction output(s)</li>
* </ul>
* </li>
* </ul>
*/
public class DogecoinACCTv3 implements ACCT {
private static final Logger LOGGER = LogManager.getLogger(DogecoinACCTv3.class);
public static final String NAME = DogecoinACCTv3.class.getSimpleName();
public static final byte[] CODE_BYTES_HASH = HashCode.fromString("03b44087f6325463eb745aa32d9a782add03148bcfbe73ffd8854ce55ff863d4").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[] partnerDogecoinPKH;
public byte[] hashOfSecretA;
public long lockTimeA;
}
public static final int OFFER_MESSAGE_LENGTH = 20 /*partnerDogecoinPKH*/ + 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 Dogecoin 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 DogecoinACCTv3 instance;
private DogecoinACCTv3() {
}
public static synchronized DogecoinACCTv3 getInstance() {
if (instance == null)
instance = new DogecoinACCTv3();
return instance;
}
@Override
public byte[] getCodeBytesHash() {
return CODE_BYTES_HASH;
}
@Override
public int getModeByteOffset() {
return MODE_BYTE_OFFSET;
}
@Override
public ForeignBlockchain getBlockchain() {
return Dogecoin.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 dogecoinPublicKeyHash 20-byte HASH160 of creator's trade Dogecoin public key
* @param qortAmount how much QORT to pay trade partner if they send correct 32-byte secrets to AT
* @param dogecoinAmount how much DOGE the AT creator is expecting to trade
* @param tradeTimeout suggested timeout for entire trade
*/
public static byte[] buildQortalAT(String creatorTradeAddress, byte[] dogecoinPublicKeyHash, long qortAmount, long dogecoinAmount, int tradeTimeout) {
if (dogecoinPublicKeyHash.length != 20)
throw new IllegalArgumentException("Dogecoin 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 addrDogecoinPublicKeyHash = addrCounter;
addrCounter += 4;
final int addrQortAmount = addrCounter++;
final int addrDogecoinAmount = 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 addrTradeMessagePartnerDogecoinPKHOffset = addrCounter++;
final int addrPartnerDogecoinPKHPointer = 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 addrPartnerDogecoinPKH = 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));
// Dogecoin public key hash
assert dataByteBuffer.position() == addrDogecoinPublicKeyHash * MachineState.VALUE_SIZE : "addrDogecoinPublicKeyHash incorrect";
dataByteBuffer.put(Bytes.ensureCapacity(dogecoinPublicKeyHash, 32, 0));
// Redeem Qort amount
assert dataByteBuffer.position() == addrQortAmount * MachineState.VALUE_SIZE : "addrQortAmount incorrect";
dataByteBuffer.putLong(qortAmount);
// Expected Dogecoin amount
assert dataByteBuffer.position() == addrDogecoinAmount * MachineState.VALUE_SIZE : "addrDogecoinAmount incorrect";
dataByteBuffer.putLong(dogecoinAmount);
// 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 Dogecoin PKH
assert dataByteBuffer.position() == addrTradeMessagePartnerDogecoinPKHOffset * MachineState.VALUE_SIZE : "addrTradeMessagePartnerDogecoinPKHOffset incorrect";
dataByteBuffer.putLong(32L);
// Index into data segment of partner's Dogecoin PKH, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerDogecoinPKHPointer * MachineState.VALUE_SIZE : "addrPartnerDogecoinPKHPointer incorrect";
dataByteBuffer.putLong(addrPartnerDogecoinPKH);
// 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 */
/* NOP - to ensure DOGECOIN ACCT is unique */
codeByteBuffer.put(OpCode.NOP.compile());
// 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));
// 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 Dogecoin 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, addrTradeMessagePartnerDogecoinPKHOffset));
// Store partner's Dogecoin PKH (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerDogecoinPKHPointer));
// 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 DOGE-QORT ACCT?", e);
}
}
codeByteBuffer.flip();
byte[] codeBytes = new byte[codeByteBuffer.limit()];
codeByteBuffer.get(codeBytes);
assert Arrays.equals(Crypto.digest(codeBytes), DogecoinACCTv3.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.DOGECOIN.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 Dogecoin/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 DOGE 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 Dogecoin PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Dogecoin 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 Dogecoin PKH
byte[] partnerDogecoinPKH = new byte[20];
dataByteBuffer.get(partnerDogecoinPKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerDogecoinPKH.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 = partnerDogecoinPKH;
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.partnerDogecoinPKH = 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/LitecoinACCTv2.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.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 Litecoin & 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 Litecoin & Qortal 'trade' keys</li>
* <li>Alice funds Litecoin 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' Litecoin 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 Litecoin 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 Litecoin trade key and secret-A</li>
* <li>P2SH-A LTC funds end up at Litecoin address determined by redeem transaction output(s)</li>
* </ul>
* </li>
* </ul>
*/
public class LitecoinACCTv2 implements ACCT {
public static final String NAME = LitecoinACCTv2.class.getSimpleName();
public static final byte[] CODE_BYTES_HASH = HashCode.fromString("d5ea386a41441180c854ca8d7bbc620bfd53a97df2650a2b162b52324caf6e19").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[] partnerLitecoinPKH;
public byte[] hashOfSecretA;
public long lockTimeA;
}
public static final int OFFER_MESSAGE_LENGTH = 20 /*partnerLitecoinPKH*/ + 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 Litecoin 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 LitecoinACCTv2 instance;
private LitecoinACCTv2() {
}
public static synchronized LitecoinACCTv2 getInstance() {
if (instance == null)
instance = new LitecoinACCTv2();
return instance;
}
@Override
public byte[] getCodeBytesHash() {
return CODE_BYTES_HASH;
}
@Override
public int getModeByteOffset() {
return MODE_BYTE_OFFSET;
}
@Override
public ForeignBlockchain getBlockchain() {
return Litecoin.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 litecoinPublicKeyHash 20-byte HASH160 of creator's trade Litecoin public key
* @param qortAmount how much QORT to pay trade partner if they send correct 32-byte secrets to AT
* @param litecoinAmount how much LTC the AT creator is expecting to trade
* @param tradeTimeout suggested timeout for entire trade
*/
public static byte[] buildQortalAT(String creatorTradeAddress, byte[] litecoinPublicKeyHash, long qortAmount, long litecoinAmount, int tradeTimeout) {
if (litecoinPublicKeyHash.length != 20)
throw new IllegalArgumentException("Litecoin 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 addrLitecoinPublicKeyHash = addrCounter;
addrCounter += 4;
final int addrQortAmount = addrCounter++;
final int addrLitecoinAmount = 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 addrTradeMessagePartnerLitecoinPKHOffset = addrCounter++;
final int addrPartnerLitecoinPKHPointer = 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 addrPartnerLitecoinPKH = 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));
// Litecoin public key hash
assert dataByteBuffer.position() == addrLitecoinPublicKeyHash * MachineState.VALUE_SIZE : "addrLitecoinPublicKeyHash incorrect";
dataByteBuffer.put(Bytes.ensureCapacity(litecoinPublicKeyHash, 32, 0));
// Redeem Qort amount
assert dataByteBuffer.position() == addrQortAmount * MachineState.VALUE_SIZE : "addrQortAmount incorrect";
dataByteBuffer.putLong(qortAmount);
// Expected Litecoin amount
assert dataByteBuffer.position() == addrLitecoinAmount * MachineState.VALUE_SIZE : "addrLitecoinAmount incorrect";
dataByteBuffer.putLong(litecoinAmount);
// 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 Litecoin PKH
assert dataByteBuffer.position() == addrTradeMessagePartnerLitecoinPKHOffset * MachineState.VALUE_SIZE : "addrTradeMessagePartnerLitecoinPKHOffset incorrect";
dataByteBuffer.putLong(32L);
// Index into data segment of partner's Litecoin PKH, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerLitecoinPKHPointer * MachineState.VALUE_SIZE : "addrPartnerLitecoinPKHPointer incorrect";
dataByteBuffer.putLong(addrPartnerLitecoinPKH);
// 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));
// 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 Litecoin 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, addrTradeMessagePartnerLitecoinPKHOffset));
// Store partner's Litecoin PKH (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerLitecoinPKHPointer));
// 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();
/* Sleep until message arrives */
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(QortalFunctionCode.SLEEP_UNTIL_MESSAGE.value, addrLastTxnTimestamp));
// 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 LTC-QORT ACCT?", e);
}
}
codeByteBuffer.flip();
byte[] codeBytes = new byte[codeByteBuffer.limit()];
codeByteBuffer.get(codeBytes);
assert Arrays.equals(Crypto.digest(codeBytes), LitecoinACCTv2.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.LITECOIN.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 Litecoin/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 LTC 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 Litecoin PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Litecoin 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 Litecoin PKH
byte[] partnerLitecoinPKH = new byte[20];
dataByteBuffer.get(partnerLitecoinPKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerLitecoinPKH.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 = partnerLitecoinPKH;
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.partnerLitecoinPKH = 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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package org.qortal.crosschain;
import com.google.common.hash.HashCode;
import com.google.common.primitives.Bytes;
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 Litecoin & 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 Litecoin & Qortal 'trade' keys</li>
* <li>Alice funds Litecoin 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' Litecoin 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 Litecoin 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 Litecoin trade key and secret-A</li>
* <li>P2SH-A LTC funds end up at Litecoin address determined by redeem transaction output(s)</li>
* </ul>
* </li>
* </ul>
*/
public class LitecoinACCTv3 implements ACCT {
public static final String NAME = LitecoinACCTv3.class.getSimpleName();
public static final byte[] CODE_BYTES_HASH = HashCode.fromString("31588e7ddb95a908bce310bb6dc76f011ff4693d2f8a3741fab3c989d56ce7c7").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[] partnerLitecoinPKH;
public byte[] hashOfSecretA;
public long lockTimeA;
}
public static final int OFFER_MESSAGE_LENGTH = 20 /*partnerLitecoinPKH*/ + 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 Litecoin 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 LitecoinACCTv3 instance;
private LitecoinACCTv3() {
}
public static synchronized LitecoinACCTv3 getInstance() {
if (instance == null)
instance = new LitecoinACCTv3();
return instance;
}
@Override
public byte[] getCodeBytesHash() {
return CODE_BYTES_HASH;
}
@Override
public int getModeByteOffset() {
return MODE_BYTE_OFFSET;
}
@Override
public ForeignBlockchain getBlockchain() {
return Litecoin.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 litecoinPublicKeyHash 20-byte HASH160 of creator's trade Litecoin public key
* @param qortAmount how much QORT to pay trade partner if they send correct 32-byte secrets to AT
* @param litecoinAmount how much LTC the AT creator is expecting to trade
* @param tradeTimeout suggested timeout for entire trade
*/
public static byte[] buildQortalAT(String creatorTradeAddress, byte[] litecoinPublicKeyHash, long qortAmount, long litecoinAmount, int tradeTimeout) {
if (litecoinPublicKeyHash.length != 20)
throw new IllegalArgumentException("Litecoin 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 addrLitecoinPublicKeyHash = addrCounter;
addrCounter += 4;
final int addrQortAmount = addrCounter++;
final int addrLitecoinAmount = 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 addrTradeMessagePartnerLitecoinPKHOffset = addrCounter++;
final int addrPartnerLitecoinPKHPointer = 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 addrPartnerLitecoinPKH = 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));
// Litecoin public key hash
assert dataByteBuffer.position() == addrLitecoinPublicKeyHash * MachineState.VALUE_SIZE : "addrLitecoinPublicKeyHash incorrect";
dataByteBuffer.put(Bytes.ensureCapacity(litecoinPublicKeyHash, 32, 0));
// Redeem Qort amount
assert dataByteBuffer.position() == addrQortAmount * MachineState.VALUE_SIZE : "addrQortAmount incorrect";
dataByteBuffer.putLong(qortAmount);
// Expected Litecoin amount
assert dataByteBuffer.position() == addrLitecoinAmount * MachineState.VALUE_SIZE : "addrLitecoinAmount incorrect";
dataByteBuffer.putLong(litecoinAmount);
// 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 Litecoin PKH
assert dataByteBuffer.position() == addrTradeMessagePartnerLitecoinPKHOffset * MachineState.VALUE_SIZE : "addrTradeMessagePartnerLitecoinPKHOffset incorrect";
dataByteBuffer.putLong(32L);
// Index into data segment of partner's Litecoin PKH, used by GET_B_IND
assert dataByteBuffer.position() == addrPartnerLitecoinPKHPointer * MachineState.VALUE_SIZE : "addrPartnerLitecoinPKHPointer incorrect";
dataByteBuffer.putLong(addrPartnerLitecoinPKH);
// 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));
// 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 Litecoin 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, addrTradeMessagePartnerLitecoinPKHOffset));
// Store partner's Litecoin PKH (we only really use values from B1-B3)
codeByteBuffer.put(OpCode.EXT_FUN_DAT.compile(FunctionCode.GET_B_IND, addrPartnerLitecoinPKHPointer));
// 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 LTC-QORT ACCT?", e);
}
}
codeByteBuffer.flip();
byte[] codeBytes = new byte[codeByteBuffer.limit()];
codeByteBuffer.get(codeBytes);
assert Arrays.equals(Crypto.digest(codeBytes), LitecoinACCTv3.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.LITECOIN.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 Litecoin/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 LTC 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 Litecoin PKH
dataByteBuffer.position(dataByteBuffer.position() + 8);
// Skip pointer to partner's Litecoin 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 Litecoin PKH
byte[] partnerLitecoinPKH = new byte[20];
dataByteBuffer.get(partnerLitecoinPKH);
dataByteBuffer.position(dataByteBuffer.position() + 32 - partnerLitecoinPKH.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 = partnerLitecoinPKH;
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.partnerLitecoinPKH = 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;
}
}

12
src/main/java/org/qortal/crosschain/SupportedBlockchain.java
View File

@@ -28,7 +28,9 @@ public enum SupportedBlockchain {
},
LITECOIN(Arrays.asList(
Triple.valueOf(LitecoinACCTv1.NAME, LitecoinACCTv1.CODE_BYTES_HASH, LitecoinACCTv1::getInstance)
Triple.valueOf(LitecoinACCTv1.NAME, LitecoinACCTv1.CODE_BYTES_HASH, LitecoinACCTv1::getInstance),
Triple.valueOf(LitecoinACCTv2.NAME, LitecoinACCTv2.CODE_BYTES_HASH, LitecoinACCTv2::getInstance),
Triple.valueOf(LitecoinACCTv3.NAME, LitecoinACCTv3.CODE_BYTES_HASH, LitecoinACCTv3::getInstance)
)) {
@Override
public ForeignBlockchain getInstance() {
@@ -37,12 +39,14 @@ public enum SupportedBlockchain {
@Override
public ACCT getLatestAcct() {
return LitecoinACCTv1.getInstance();
return LitecoinACCTv3.getInstance();
}
},
DOGECOIN(Arrays.asList(
Triple.valueOf(DogecoinACCTv1.NAME, DogecoinACCTv1.CODE_BYTES_HASH, DogecoinACCTv1::getInstance)
Triple.valueOf(DogecoinACCTv1.NAME, DogecoinACCTv1.CODE_BYTES_HASH, DogecoinACCTv1::getInstance),
Triple.valueOf(DogecoinACCTv2.NAME, DogecoinACCTv2.CODE_BYTES_HASH, DogecoinACCTv2::getInstance),
Triple.valueOf(DogecoinACCTv3.NAME, DogecoinACCTv3.CODE_BYTES_HASH, DogecoinACCTv3::getInstance)
)) {
@Override
public ForeignBlockchain getInstance() {
@@ -51,7 +55,7 @@ public enum SupportedBlockchain {
@Override
public ACCT getLatestAcct() {
return DogecoinACCTv1.getInstance();
return DogecoinACCTv3.getInstance();
}
};

4
src/main/java/org/qortal/data/block/BlockData.java
View File

@@ -204,6 +204,10 @@ public class BlockData implements Serializable {
return this.onlineAccountsSignatures;
}
public void setOnlineAccountsSignatures(byte[] onlineAccountsSignatures) {
this.onlineAccountsSignatures = onlineAccountsSignatures;
}
// JAXB special
@XmlElement(name = "minterAddress")

55
src/main/java/org/qortal/data/network/OnlineAccountLevel.java Normal file
View File

@@ -0,0 +1,55 @@
package org.qortal.data.network;
import javax.xml.bind.annotation.XmlAccessType;
import javax.xml.bind.annotation.XmlAccessorType;
// All properties to be converted to JSON via JAXB
@XmlAccessorType(XmlAccessType.FIELD)
public class OnlineAccountLevel {
protected int level;
protected int count;
// Constructors
// necessary for JAXB serialization
protected OnlineAccountLevel() {
}
public OnlineAccountLevel(int level, int count) {
this.level = level;
this.count = count;
}
public int getLevel() {
return this.level;
}
public int getCount() {
return this.count;
}
public void setCount(int count) {
this.count = count;
}
// Comparison
@Override
public boolean equals(Object other) {
if (other == this)
return true;
if (!(other instanceof OnlineAccountLevel))
return false;
OnlineAccountLevel otherOnlineAccountData = (OnlineAccountLevel) other;
if (otherOnlineAccountData.level != this.level)
return false;
return true;
}
}

17
src/main/java/org/qortal/list/ResourceList.java
View File

@@ -21,7 +21,7 @@ public class ResourceList {
private String category;
private String resourceName;
private List<String> list;
private List<String> list = new ArrayList<>();
/**
* ResourceList
@@ -36,7 +36,6 @@ public class ResourceList {
public ResourceList(String category, String resourceName) throws IOException {
this.category = category;
this.resourceName = resourceName;
this.list = new ArrayList<>();
this.load();
}
@@ -45,7 +44,7 @@ public class ResourceList {
private Path getFilePath() {
String pathString = String.format("%s%s%s_%s.json", Settings.getInstance().getListsPath(),
File.separator, this.resourceName, this.category);
File.separator, this.category, this.resourceName);
return Paths.get(pathString);
}
@@ -154,4 +153,16 @@ public class ResourceList {
return ResourceList.listToJSONString(this.list);
}
public String getCategory() {
return this.category;
}
public String getResourceName() {
return this.resourceName;
}
public String toString() {
return String.format("%s %s", this.category, this.resourceName);
}
}

153
src/main/java/org/qortal/list/ResourceListManager.java
View File

@@ -4,92 +4,125 @@ import org.apache.logging.log4j.LogManager;
import org.apache.logging.log4j.Logger;
import java.io.IOException;
import java.util.ArrayList;
import java.util.List;
import java.util.Objects;
public class ResourceListManager {
private static final Logger LOGGER = LogManager.getLogger(ResourceListManager.class);
private static ResourceListManager instance;
private ResourceList addressBlacklist;
private List<ResourceList> lists = new ArrayList<>();
public ResourceListManager() {
try {
this.addressBlacklist = new ResourceList("blacklist", "address");
} catch (IOException e) {
LOGGER.info("Error while loading address blacklist. Blocking is currently unavailable.");
}
}
public static synchronized ResourceListManager getInstance() {
if (instance == null) {
instance = new ResourceListManager();
}
return instance;
}
public boolean addAddressToBlacklist(String address, boolean save) {
try {
this.addressBlacklist.add(address);
if (save) {
this.addressBlacklist.save();
private ResourceList getList(String category, String resourceName) {
for (ResourceList list : this.lists) {
if (Objects.equals(list.getCategory(), category) &&
Objects.equals(list.getResourceName(), resourceName)) {
return list;
}
return true;
} catch (IllegalStateException | IOException e) {
LOGGER.info("Unable to add address to blacklist", e);
return false;
}
}
public boolean removeAddressFromBlacklist(String address, boolean save) {
// List doesn't exist in array yet, so create it
// This will load any existing data from the filesystem
try {
this.addressBlacklist.remove(address);
ResourceList list = new ResourceList(category, resourceName);
this.lists.add(list);
return list;
if (save) {
this.addressBlacklist.save();
}
return true;
} catch (IllegalStateException | IOException e) {
LOGGER.info("Unable to remove address from blacklist", e);
return false;
}
}
public boolean isAddressInBlacklist(String address) {
if (this.addressBlacklist == null) {
return false;
}
return this.addressBlacklist.contains(address);
}
public void saveBlacklist() {
if (this.addressBlacklist == null) {
return;
}
try {
this.addressBlacklist.save();
} catch (IOException e) {
LOGGER.info("Unable to save blacklist - reverting back to last saved state");
this.addressBlacklist.revert();
}
}
public void revertBlacklist() {
if (this.addressBlacklist == null) {
return;
}
this.addressBlacklist.revert();
}
public String getBlacklistJSONString() {
if (this.addressBlacklist == null) {
LOGGER.info("Unable to load or create list {} {}: {}", category, resourceName, e.getMessage());
return null;
}
return this.addressBlacklist.getJSONString();
}
public boolean addToList(String category, String resourceName, String item, boolean save) {
ResourceList list = this.getList(category, resourceName);
if (list == null) {
return false;
}
try {
list.add(item);
if (save) {
list.save();
}
return true;
} catch (IllegalStateException | IOException e) {
LOGGER.info(String.format("Unable to add item %s to list %s", item, list), e);
return false;
}
}
public boolean removeFromList(String category, String resourceName, String item, boolean save) {
ResourceList list = this.getList(category, resourceName);
if (list == null) {
return false;
}
try {
list.remove(item);
if (save) {
list.save();
}
return true;
} catch (IllegalStateException | IOException e) {
LOGGER.info(String.format("Unable to remove item %s from list %s", item, list), e);
return false;
}
}
public boolean listContains(String category, String resourceName, String address) {
ResourceList list = this.getList(category, resourceName);
if (list == null) {
return false;
}
return list.contains(address);
}
public void saveList(String category, String resourceName) {
ResourceList list = this.getList(category, resourceName);
if (list == null) {
return;
}
try {
list.save();
} catch (IOException e) {
LOGGER.info("Unable to save list {} - reverting back to last saved state", list);
list.revert();
}
}
public void revertList(String category, String resourceName) {
ResourceList list = this.getList(category, resourceName);
if (list == null) {
return;
}
list.revert();
}
public String getJSONStringForList(String category, String resourceName) {
ResourceList list = this.getList(category, resourceName);
if (list == null) {
return null;
}
return list.getJSONString();
}
}

4
src/main/java/org/qortal/network/Network.java
View File

@@ -73,7 +73,9 @@ public class Network {
"node1.qortal.org", "node2.qortal.org", "node3.qortal.org", "node4.qortal.org", "node5.qortal.org",
"node6.qortal.org", "node7.qortal.org", "node8.qortal.org", "node9.qortal.org", "node10.qortal.org",
"node.qortal.ru", "node2.qortal.ru", "node3.qortal.ru", "node.qortal.uk", "node22.qortal.org",
"cinfu1.crowetic.com", "node.cwd.systems"
"cinfu1.crowetic.com", "node.cwd.systems", "bootstrap.cwd.systems", "node1.qortalnodes.live",
"node2.qortalnodes.live", "node3.qortalnodes.live", "node4.qortalnodes.live", "node5.qortalnodes.live",
"node6.qortalnodes.live", "node7.qortalnodes.live", "node8.qortalnodes.live"
};
private static final long NETWORK_EPC_KEEPALIVE = 10L; // seconds

9
src/main/java/org/qortal/repository/BlockArchiveRepository.java
View File

@@ -71,6 +71,15 @@ public interface BlockArchiveRepository {
*/
public int getHeightFromTimestamp(long timestamp) throws DataException;
/**
* Returns block timestamp for a given height.
*
* @param height
* @return timestamp, or 0 if height is out of bounds.
* @throws DataException
*/
public long getTimestampFromHeight(int height) throws DataException;
/**
* Returns block summaries for blocks signed by passed public key, or reward-share with minter with passed public key.
*/

4
src/main/java/org/qortal/repository/Bootstrap.java
View File

@@ -10,6 +10,7 @@ import org.qortal.data.account.MintingAccountData;
import org.qortal.data.block.BlockData;
import org.qortal.data.crosschain.TradeBotData;
import org.qortal.gui.SplashFrame;
import org.qortal.network.Network;
import org.qortal.repository.hsqldb.HSQLDBImportExport;
import org.qortal.repository.hsqldb.HSQLDBRepositoryFactory;
import org.qortal.settings.Settings;
@@ -241,6 +242,9 @@ public class Bootstrap {
repository.getNetworkRepository().deleteAllPeers();
repository.saveChanges();
LOGGER.info("Adding initial peers...");
Network.installInitialPeers(repository);
LOGGER.info("Creating bootstrap...");
// Timeout if the database isn't ready for backing up after 10 seconds
long timeout = 10 * 1000L;

14
src/main/java/org/qortal/repository/hsqldb/HSQLDBBlockArchiveRepository.java
View File

@@ -103,6 +103,20 @@ public class HSQLDBBlockArchiveRepository implements BlockArchiveRepository {
}
}
@Override
public long getTimestampFromHeight(int height) throws DataException {
String sql = "SELECT minted_when FROM BlockArchive WHERE height = ?";
try (ResultSet resultSet = this.repository.checkedExecute(sql, height)) {
if (resultSet == null)
return 0;
return resultSet.getLong(1);
} catch (SQLException e) {
throw new DataException("Error obtaining block timestamp by height from BlockArchive repository", e);
}
}
@Override
public List<BlockSummaryData> getBlockSummariesBySigner(byte[] signerPublicKey, Integer limit, Integer offset, Boolean reverse) throws DataException {
StringBuilder sql = new StringBuilder(512);

29
src/main/java/org/qortal/repository/hsqldb/HSQLDBImportExport.java
View File

@@ -28,9 +28,9 @@ public class HSQLDBImportExport {
private static final Logger LOGGER = LogManager.getLogger(Bootstrap.class);
public static void backupTradeBotStates(Repository repository) throws DataException {
HSQLDBImportExport.backupCurrentTradeBotStates(repository);
HSQLDBImportExport.backupArchivedTradeBotStates(repository);
public static void backupTradeBotStates(Repository repository, List<TradeBotData> additional) throws DataException {
HSQLDBImportExport.backupCurrentTradeBotStates(repository, additional);
HSQLDBImportExport.backupArchivedTradeBotStates(repository, additional);
LOGGER.info("Exported sensitive/node-local data: trade bot states");
}
@@ -47,14 +47,23 @@ public class HSQLDBImportExport {
/**
* Backs up the trade bot states currently in the repository, without combining them with past ones
* @param repository
* @param additional - any optional extra trade bot states to include in the backup
* @throws DataException
*/
private static void backupCurrentTradeBotStates(Repository repository) throws DataException {
private static void backupCurrentTradeBotStates(Repository repository, List<TradeBotData> additional) throws DataException {
try {
Path backupDirectory = HSQLDBImportExport.getExportDirectory(true);
// Load current trade bot data
List<TradeBotData> allTradeBotData = repository.getCrossChainRepository().getAllTradeBotData();
// Add any additional entries if specified
if (additional != null && !additional.isEmpty()) {
allTradeBotData.addAll(additional);
}
// Convert them to JSON objects
JSONArray currentTradeBotDataJson = new JSONArray();
for (TradeBotData tradeBotData : allTradeBotData) {
JSONObject tradeBotDataJson = tradeBotData.toJson();
@@ -82,14 +91,22 @@ public class HSQLDBImportExport {
* Backs up the trade bot states currently in the repository to a separate "archive" file,
* making sure to combine them with any unique states already present in the archive.
* @param repository
* @param additional - any optional extra trade bot states to include in the backup
* @throws DataException
*/
private static void backupArchivedTradeBotStates(Repository repository) throws DataException {
private static void backupArchivedTradeBotStates(Repository repository, List<TradeBotData> additional) throws DataException {
try {
Path backupDirectory = HSQLDBImportExport.getExportDirectory(true);
// Load current trade bot data
List<TradeBotData> allTradeBotData = repository.getCrossChainRepository().getAllTradeBotData();
// Add any additional entries if specified
if (additional != null && !additional.isEmpty()) {
allTradeBotData.addAll(additional);
}
// Convert them to JSON objects
JSONArray allTradeBotDataJson = new JSONArray();
for (TradeBotData tradeBotData : allTradeBotData) {
JSONObject tradeBotDataJson = tradeBotData.toJson();
@@ -263,7 +280,7 @@ public class HSQLDBImportExport {
* @param jsonString
* @return Triple<String, String, JSONArray> (type, dataset, data)
*/
private static Triple<String, String, JSONArray> parseJSONString(String jsonString) throws DataException {
public static Triple<String, String, JSONArray> parseJSONString(String jsonString) throws DataException {
String type = null;
String dataset = null;
JSONArray data = null;

2
src/main/java/org/qortal/repository/hsqldb/HSQLDBRepository.java
View File

@@ -471,7 +471,7 @@ public class HSQLDBRepository implements Repository {
@Override
public void exportNodeLocalData() throws DataException {
HSQLDBImportExport.backupTradeBotStates(this);
HSQLDBImportExport.backupTradeBotStates(this, null);
HSQLDBImportExport.backupMintingAccounts(this);
}

13
src/main/java/org/qortal/settings/Settings.java
View File

@@ -91,9 +91,9 @@ public class Settings {
/** Whether to show a notification when we backup repository. */
private boolean showBackupNotification = false;
/** Minimum time between repository maintenance attempts (ms) */
private long repositoryMaintenanceMinInterval = 7 * 24 * 60 * 60 * 1000L; // 7 days (ms) default
private long repositoryMaintenanceMinInterval = 3 * 24 * 60 * 60 * 1000L; // 3 days (ms) default
/** Maximum time between repository maintenance attempts (ms) (0 if disabled). */
private long repositoryMaintenanceMaxInterval = 30 * 24 * 60 * 60 * 1000L; // 30 days (ms) default
private long repositoryMaintenanceMaxInterval = 14 * 24 * 60 * 60 * 1000L; // 14 days (ms) default
/** Whether to show a notification when we run scheduled maintenance. */
private boolean showMaintenanceNotification = false;
/** How long between repository checkpoints (ms). */
@@ -149,6 +149,10 @@ public class Settings {
private boolean bootstrap = true;
/** Registered names integrity check */
private boolean namesIntegrityCheckEnabled = false;
// Peer-to-peer related
private boolean isTestNet = false;
/** Port number for inbound peer-to-peer connections. */
@@ -205,6 +209,7 @@ public class Settings {
// Bootstrap sources
private String[] bootstrapHosts = new String[] {
"http://bootstrap.qortal.org",
"http://bootstrap2.qortal.org",
"http://cinfu1.crowetic.com"
};
@@ -638,6 +643,10 @@ public class Settings {
return this.blockPruneBatchSize;
}
public boolean isNamesIntegrityCheckEnabled() {
return this.namesIntegrityCheckEnabled;
}
public boolean isArchiveEnabled() {
if (this.topOnly) {

2
src/main/java/org/qortal/transaction/ChatTransaction.java
View File

@@ -146,7 +146,7 @@ public class ChatTransaction extends Transaction {
// Check for blacklisted author by address
ResourceListManager listManager = ResourceListManager.getInstance();
if (listManager.isAddressInBlacklist(this.chatTransactionData.getSender())) {
if (listManager.listContains("blacklist", "address", this.chatTransactionData.getSender())) {
return ValidationResult.ADDRESS_IN_BLACKLIST;
}

49
src/main/resources/i18n/ApiError_de.properties
View File

@@ -4,68 +4,68 @@
# "localeLang": "de",
### Common ###
JSON = JSON nachricht konnte nicht geparsed werden
JSON = JSON Nachricht konnte nicht geparst werden
INSUFFICIENT_BALANCE = insufficient balance
UNAUTHORIZED = API call unauthorized
UNAUTHORIZED = API-Aufruf nicht autorisiert
REPOSITORY_ISSUE = repository error
REPOSITORY_ISSUE = Repository-Fehler
NON_PRODUCTION = this API call is not permitted for production systems
BLOCKCHAIN_NEEDS_SYNC = blockchain needs to synchronize first
NO_TIME_SYNC = no clock synchronization yet
NO_TIME_SYNC = noch keine Uhrensynchronisation
### Validation ###
INVALID_SIGNATURE = ungültige signatur
INVALID_SIGNATURE = ungültige Signatur
INVALID_ADDRESS = ungültige adresse
INVALID_ADDRESS = ungültige Adresse
INVALID_PUBLIC_KEY = ungültiger public key
INVALID_DATA = ungültige daten
INVALID_DATA = ungültige Daten
INVALID_NETWORK_ADDRESS = invalid network address
INVALID_NETWORK_ADDRESS = ungültige Netzwerk Adresse
ADDRESS_UNKNOWN = account address unknown
ADDRESS_UNKNOWN = Account Adresse unbekannt
INVALID_CRITERIA = invalid search criteria
INVALID_CRITERIA = ungültige Suchkriterien
INVALID_REFERENCE = invalid reference
INVALID_REFERENCE = ungültige Referenz
TRANSFORMATION_ERROR = could not transform JSON into transaction
TRANSFORMATION_ERROR = konnte JSON nicht in eine Transaktion umwandeln
INVALID_PRIVATE_KEY = invalid private key
INVALID_PRIVATE_KEY = ungültiger private key
INVALID_HEIGHT = invalid block height
INVALID_HEIGHT = ungültige block height
CANNOT_MINT = account cannot mint
CANNOT_MINT = Account kann nicht minten
### Blocks ###
BLOCK_UNKNOWN = block unknown
BLOCK_UNKNOWN = block unbekannt
### Transactions ###
TRANSACTION_UNKNOWN = transaction unknown
TRANSACTION_UNKNOWN = Transaktion unbekannt
PUBLIC_KEY_NOT_FOUND = public key wurde nicht gefunden
# this one is special in that caller expected to pass two additional strings, hence the two %s
TRANSACTION_INVALID = transaction invalid: %s (%s)
TRANSACTION_INVALID = Transaktion ungültig: %s (%s)
### Naming ###
NAME_UNKNOWN = name unknown
NAME_UNKNOWN = Name unbekannt
### Asset ###
INVALID_ASSET_ID = ungültige asset ID
INVALID_ORDER_ID = invalid asset order ID
INVALID_ORDER_ID = ungültige asset order ID
ORDER_UNKNOWN = unknown asset order ID
ORDER_UNKNOWN = unbekannte asset order ID
### Groups ###
GROUP_UNKNOWN = group unknown
GROUP_UNKNOWN = Gruppe unbekannt
### Foreign Blockchain ###
FOREIGN_BLOCKCHAIN_NETWORK_ISSUE = foreign blokchain or ElectrumX network issue
@@ -78,6 +78,7 @@ FOREIGN_BLOCKCHAIN_TOO_SOON = too soon to broadcast foreign blockchain transacti
ORDER_SIZE_TOO_SMALL = order amount too low
### Data ###
FILE_NOT_FOUND = file not found
FILE_NOT_FOUND = Datei nicht gefunden
NO_REPLY = peer did not reply with data
NO_REPLY = peer did not reply with data

55
src/main/resources/i18n/ApiError_fr.properties Normal file
View File

@@ -0,0 +1,55 @@
### Commun ###
JSON = échec de l'analyse du message JSON
INSUFFICIENT_BALANCE = balance insuffisante
UNAUTHORIZED = appel de lAPI non autorisé
REPOSITORY_ISSUE = erreur de dépôt
NON_PRODUCTION = cet appel API n'est pas autorisé pour les systèmes en production
BLOCKCHAIN_NEEDS_SYNC = la blockchain doit d'abord être synchronisée
NO_TIME_SYNC = heure pas encore synchronisée
### Validation ###
INVALID_SIGNATURE = signature invalide
INVALID_ADDRESS = adresse invalide
INVALID_PUBLIC_KEY = clé publique invalide
INVALID_DATA = données invalides
INVALID_NETWORK_ADDRESS = adresse réseau invalide
ADDRESS_UNKNOWN = adresse de compte inconnue
INVALID_CRITERIA = critère de recherche invalide
INVALID_REFERENCE = référence invalide
TRANSFORMATION_ERROR = ne peut pas transformer JSON en transaction
INVALID_PRIVATE_KEY = clé privée invalide
INVALID_HEIGHT = hauteur de bloc invalide
CANNOT_MINT = le compte ne peut pas mint
### Blocks ###
BLOCK_UNKNOWN = bloc inconnu
### Transactions ###
TRANSACTION_UNKNOWN = opération inconnue
PUBLIC_KEY_NOT_FOUND = clé publique introuvable
# celui-ci est spécial dans le sens où l'appelant doit passer deux chaînes supplémentaires, d'où les deux %s
TRANSACTION_INVALID = transaction invalide: %s (%s)
### Nommage ###
NAME_UNKNOWN = nom inconnu
### Asset ###
INVALID_ASSET_ID = identifiant d'actif invalide
INVALID_ORDER_ID = identifiant de commande d'actif non valide
ORDER_UNKNOWN = identifiant d'ordre d'actif inconnu
### Groupes ###
GROUP_UNKNOWN = groupe inconnu
### Blockchain étrangère ###
FOREIGN_BLOCKCHAIN_NETWORK_ISSUE = Problème blokchain étrangère ou de réseau ElectrumX
FOREIGN_BLOCKCHAIN_BALANCE_ISSUE = solde insuffisant sur la blockchain étrangère
FOREIGN_BLOCKCHAIN_TOO_SOON = trop tôt pour diffuser la transaction sur la blockchain étrangère (temps de verrouillage/temps de bloc médian)
### Portail de trading ###
ORDER_SIZE_TOO_SMALL = montant de commande trop bas
### Données ###
FILE_NOT_FOUND = fichier introuvable
NO_REPLY = le pair n'a pas renvoyé de données

40
src/main/resources/i18n/SysTray_de.properties Normal file
View File

@@ -0,0 +1,40 @@
#Generated by ResourceBundle Editor (http://essiembre.github.io/eclipse-rbe/)
# SysTray pop-up menu
AUTO_UPDATE = Automatisches Update
APPLYING_UPDATE_AND_RESTARTING = Automatisches Update anwenden und neu starten …
BLOCK_HEIGHT = height
BUILD_VERSION = Build-Version
CHECK_TIME_ACCURACY = Prüfe Zeitgenauigkeit
CONNECTING = Verbindung wird hergestellt
CONNECTION = Verbindung
CONNECTIONS = Verbindungen
CREATING_BACKUP_OF_DB_FILES = Erstellen Backup von Datenbank Dateien …
DB_BACKUP = Datenbank Backup
DB_CHECKPOINT = Datenbank Kontrollpunkt
EXIT = Verlassen
MINTING_DISABLED = NOT minting
MINTING_ENABLED = \u2714 Minting
OPEN_UI = Öffne UI
PERFORMING_DB_CHECKPOINT = Speichern nicht übergebener Datenbank Änderungen …
SYNCHRONIZE_CLOCK = Synchronisiere Uhr
SYNCHRONIZING_BLOCKCHAIN = Synchronisierung
SYNCHRONIZING_CLOCK = Synchronisierung Uhr

41
src/main/resources/i18n/SysTray_fr.properties Normal file
View File

@@ -0,0 +1,41 @@
AUTO_UPDATE = Mise à jour automatique
APPLYING_UPDATE_AND_RESTARTING = Application de la mise à jour automatique et redémarrage...
BLOCK_HEIGHT = hauteur
BUILD_VERSION = Numéro de version
CHECK_TIME_ACCURACY = Vérifier l'heure
CONNECTING = Connexion en cours
CONNECTION = connexion
CONNECTIONS = connexions
CREATING_BACKUP_OF_DB_FILES = Création d'une sauvegarde des fichiers de la base de données...
DB_BACKUP = Sauvegarde de la base de données
DB_MAINTENANCE = Maintenance de la base de données
DB_CHECKPOINT = Point de contrôle de la base de données
EXIT = Quitter
MINTING_DISABLED = NE mint PAS
MINTING_ENABLED = \u2714 Minting
OPEN_UI = Ouvrir l'interface
PERFORMING_DB_CHECKPOINT = Enregistrement des modifications de base de données non validées...
PERFORMING_DB_MAINTENANCE = Entrain d'effectuer la maintenance programmée...
SYNCHRONIZE_CLOCK = Mettre l'heure à jour
SYNCHRONIZING_BLOCKCHAIN = Synchronisation
SYNCHRONIZING_CLOCK = Synchronisation de l'heure

151
src/main/resources/i18n/TransactionValidity_fr.properties Normal file
View File

@@ -0,0 +1,151 @@
OK = OK
INVALID_ADDRESS = adresse invalide
NEGATIVE_AMOUNT = montant invalide/négatif
NEGATIVE_FEE = frais invalides/négatifs
NO_BALANCE = solde insuffisant
INVALID_REFERENCE = référence invalide
INVALID_NAME_LENGTH = longueur de nom invalide
INVALID_VALUE_LENGTH = longueur de 'valeur' invalide
NAME_ALREADY_REGISTERED = le nom est déjà enregistré
NAME_DOES_NOT_EXIST = le nom n'existe pas
INVALID_NAME_OWNER = le nom du propriétaire est invalide
NAME_ALREADY_FOR_SALE = le nom est déjà en vente
NAME_NOT_FOR_SALE = le nom n'est pas à vendre
BUYER_ALREADY_OWNER = l'acheteur est déjà le propriétaire
INVALID_AMOUNT = montant invalide
INVALID_SELLER = vendeur invalide
NAME_NOT_NORMALIZED = le nom n'est pas sous la forme 'normalisée' Unicode
INVALID_DESCRIPTION_LENGTH = longueur de description invalide
INVALID_OPTIONS_COUNT = nombre d'options invalides
INVALID_OPTION_LENGTH = longueur des options invalide
DUPLICATE_OPTION = option dupliquée
POLL_ALREADY_EXISTS = le scrutin existe déjà
POLL_DOES_NOT_EXIST = le scrutin n'existe pas
POLL_OPTION_DOES_NOT_EXIST = Ce choix de scrutin n'existe pas
ALREADY_VOTED_FOR_THAT_OPTION = Vous avez déjà voté pour ce choix
INVALID_DATA_LENGTH = longueur de données invalide
INVALID_QUANTITY = quantité invalide
ASSET_DOES_NOT_EXIST = l'actif n'existe pas
INVALID_RETURN = retour invalide
HAVE_EQUALS_WANT = l'actif désiré est le même que l'actif possédé
ORDER_DOES_NOT_EXIST = l'ordre d'échange d'actifs n'existe pas
INVALID_ORDER_CREATOR = créateur d'ordre invalide
INVALID_PAYMENTS_COUNT = nombre de paiements invalides
NEGATIVE_PRICE = prix invalide/négatif
INVALID_CREATION_BYTES = octets de création invalides
INVALID_TAGS_LENGTH = longueur de 'tags' invalide
INVALID_AT_TYPE_LENGTH = longueur 'type' AT invalide
INVALID_AT_TRANSACTION = transaction AT invalide
INSUFFICIENT_FEE = frais insuffisant
ASSET_DOES_NOT_MATCH_AT = l'actif ne correspond pas à l'actif d'AT
ASSET_ALREADY_EXISTS = l'actif existe déjà
MISSING_CREATOR = créateur manquant
TIMESTAMP_TOO_OLD = horodatage trop ancien
TIMESTAMP_TOO_NEW = horodatage trop récent
TOO_MANY_UNCONFIRMED = le compte a trop de transactions non confirmées en attente
GROUP_ALREADY_EXISTS = le groupe existe déjà
GROUP_DOES_NOT_EXIST = le groupe n'existe pas
INVALID_GROUP_OWNER = propriétaire de groupe invalide
ALREADY_GROUP_MEMBER = vous êtes déjà un(e) membre du groupe
GROUP_OWNER_CANNOT_LEAVE = le propriétaire du groupe ne peut pas quitter le groupe
NOT_GROUP_MEMBER = le compte n'est pas membre du groupe
ALREADY_GROUP_ADMIN = vous êtes déjà l'administrateur(trice) du groupe
NOT_GROUP_ADMIN = le compte n'est pas un administrateur du groupe
INVALID_LIFETIME = durée de vie invalide
INVITE_UNKNOWN = invitation de groupe inconnue
BAN_EXISTS = déjà banni
BAN_UNKNOWN = bannissement inconnu
BANNED_FROM_GROUP = banned from group
JOIN_REQUEST_EXISTS = la demande d'adhésion au groupe existe déjà
INVALID_GROUP_APPROVAL_THRESHOLD = seuil d'approbation de groupe non valide
GROUP_ID_MISMATCH = identifiant de groupe non-concorde
INVALID_GROUP_ID = identifiant de groupe invalide
TRANSACTION_UNKNOWN = transaction inconnue
TRANSACTION_ALREADY_CONFIRMED = la transaction a déjà été confirmée
INVALID_TX_GROUP_ID = identifiant du groupe de transactions invalide
TX_GROUP_ID_MISMATCH = l'identifiant du groupe de transaction ne correspond pas
MULTIPLE_NAMES_FORBIDDEN = l'enregistrement de plusieurs noms par compte est interdit
INVALID_ASSET_OWNER = propriétaire de l'actif invalide
AT_IS_FINISHED = l'AT est fini
NO_FLAG_PERMISSION = le compte n'a pas cette autorisation
NOT_MINTING_ACCOUNT = le compte ne peut pas mint
REWARD_SHARE_UNKNOWN = partage de récompense inconnu
INVALID_REWARD_SHARE_PERCENT = pourcentage du partage de récompense invalide
PUBLIC_KEY_UNKNOWN = clé publique inconnue
INVALID_PUBLIC_KEY = clé publique invalide
AT_UNKNOWN = AT inconnu
AT_ALREADY_EXISTS = AT déjà existante
GROUP_APPROVAL_NOT_REQUIRED = approbation de groupe non requise
GROUP_APPROVAL_DECIDED = approbation de groupe déjà décidée
MAXIMUM_REWARD_SHARES = déjà au nombre maximum de récompense pour ce compte
TRANSACTION_ALREADY_EXISTS = la transaction existe déjà
NO_BLOCKCHAIN_LOCK = nœud de la blockchain actuellement occupé
ORDER_ALREADY_CLOSED = l'ordre d'échange d'actifs est déjà fermé
CLOCK_NOT_SYNCED = horloge non synchronisée
ASSET_NOT_SPENDABLE = l'actif n'est pas dépensable
ACCOUNT_CANNOT_REWARD_SHARE = le compte ne peut pas récompenser
SELF_SHARE_EXISTS = l'auto-partage (récompense) existe déjà
ACCOUNT_ALREADY_EXISTS = Le compte existe déjà
INVALID_GROUP_BLOCK_DELAY = délai de blocage d'approbation de groupe invalide
INCORRECT_NONCE = PoW nonce incorrect
INVALID_TIMESTAMP_SIGNATURE = signature d'horodatage invalide
ADDRESS_IN_BLACKLIST = cette adresse est dans votre liste noire
ADDRESS_ABOVE_RATE_LIMIT = l'adresse a atteint la limite de débit spécifiée
DUPLICATE_MESSAGE = l'adresse a envoyé un message en double
INVALID_BUT_OK = invalide mais OK
NOT_YET_RELEASED = fonctionnalité pas encore publiée

7
src/test/java/org/qortal/test/BootstrapTests.java
View File

@@ -208,8 +208,11 @@ public class BootstrapTests extends Common {
private void deleteBootstraps() throws IOException {
try {
Path path = Paths.get(String.format("%s%s", Settings.getInstance().getBootstrapFilenamePrefix(), "bootstrap-archive.7z"));
Files.delete(path);
Path archivePath = Paths.get(String.format("%s%s", Settings.getInstance().getBootstrapFilenamePrefix(), "bootstrap-archive.7z"));
Files.delete(archivePath);
Path sha256Path = Paths.get(String.format("%s%s", Settings.getInstance().getBootstrapFilenamePrefix(), "bootstrap-archive.7z.sha256"));
Files.delete(sha256Path);
} catch (NoSuchFileException e) {
// Nothing to delete

74
src/test/java/org/qortal/test/ImportExportTests.java
View File

@@ -25,12 +25,15 @@ import org.qortal.repository.hsqldb.HSQLDBImportExport;
import org.qortal.settings.Settings;
import org.qortal.test.common.Common;
import org.qortal.utils.NTP;
import org.qortal.utils.Triple;
import java.io.FileWriter;
import java.io.IOException;
import java.nio.file.Files;
import java.nio.file.Path;
import java.nio.file.Paths;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
import static org.junit.Assert.*;
@@ -68,7 +71,7 @@ public class ImportExportTests extends Common {
assertEquals(10, repository.getCrossChainRepository().getAllTradeBotData().size());
// Export them
HSQLDBImportExport.backupTradeBotStates(repository);
HSQLDBImportExport.backupTradeBotStates(repository, null);
// Delete them from the repository
for (TradeBotData tradeBotData : tradeBots) {
@@ -117,7 +120,7 @@ public class ImportExportTests extends Common {
assertEquals(10, repository.getCrossChainRepository().getAllTradeBotData().size());
// Export them
HSQLDBImportExport.backupTradeBotStates(repository);
HSQLDBImportExport.backupTradeBotStates(repository, null);
// Delete them from the repository
for (TradeBotData tradeBotData : tradeBots) {
@@ -136,7 +139,7 @@ public class ImportExportTests extends Common {
}
// Export again
HSQLDBImportExport.backupTradeBotStates(repository);
HSQLDBImportExport.backupTradeBotStates(repository, null);
// Import current states only
Path exportPath = HSQLDBImportExport.getExportDirectory(false);
@@ -184,7 +187,7 @@ public class ImportExportTests extends Common {
assertEquals(10, repository.getCrossChainRepository().getAllTradeBotData().size());
// Export them
HSQLDBImportExport.backupTradeBotStates(repository);
HSQLDBImportExport.backupTradeBotStates(repository, null);
// Delete them from the repository
for (TradeBotData tradeBotData : tradeBots) {
@@ -203,7 +206,7 @@ public class ImportExportTests extends Common {
}
// Export again
HSQLDBImportExport.backupTradeBotStates(repository);
HSQLDBImportExport.backupTradeBotStates(repository, null);
// Import all states from the archive
Path exportPath = HSQLDBImportExport.getExportDirectory(false);
@@ -263,6 +266,67 @@ public class ImportExportTests extends Common {
}
}
@Test
public void testArchiveTradeBotStateOnTradeFailure() throws DataException, IOException {
try (final Repository repository = RepositoryManager.getRepository()) {
// Create a trade bot and save it in the repository
TradeBotData tradeBotData = this.createTradeBotData(repository);
// Ensure it doesn't exist in the repository
assertTrue(repository.getCrossChainRepository().getAllTradeBotData().isEmpty());
// Export trade bot states, passing in the newly created trade bot as an additional parameter
// This is needed because it hasn't been saved to the db yet
HSQLDBImportExport.backupTradeBotStates(repository, Arrays.asList(tradeBotData));
// Ensure it is still not present in the repository
assertTrue(repository.getCrossChainRepository().getAllTradeBotData().isEmpty());
// Export all local node data again, but this time without including the trade bot data
// This simulates the behaviour of a node shutdown
repository.exportNodeLocalData();
// The TradeBotStates.json file should contain no entries
Path backupDirectory = HSQLDBImportExport.getExportDirectory(false);
Path tradeBotStatesBackup = Paths.get(backupDirectory.toString(), "TradeBotStates.json");
assertTrue(Files.exists(tradeBotStatesBackup));
String jsonString = new String(Files.readAllBytes(tradeBotStatesBackup));
Triple<String, String, JSONArray> parsedJSON = HSQLDBImportExport.parseJSONString(jsonString);
JSONArray tradeBotDataJson = parsedJSON.getC();
assertTrue(tradeBotDataJson.isEmpty());
// .. but the TradeBotStatesArchive.json should contain the trade bot data
Path tradeBotStatesArchiveBackup = Paths.get(backupDirectory.toString(), "TradeBotStatesArchive.json");
assertTrue(Files.exists(tradeBotStatesArchiveBackup));
jsonString = new String(Files.readAllBytes(tradeBotStatesArchiveBackup));
parsedJSON = HSQLDBImportExport.parseJSONString(jsonString);
JSONObject tradeBotDataJsonObject = (JSONObject) parsedJSON.getC().get(0);
assertEquals(tradeBotData.toJson().toString(), tradeBotDataJsonObject.toString());
// Now try importing local data (to simulate a node startup)
String exportPath = Settings.getInstance().getExportPath();
Path importPath = Paths.get(exportPath, "TradeBotStates.json");
repository.importDataFromFile(importPath.toString());
// The trade should be missing since it's not present in TradeBotStates.json
assertTrue(repository.getCrossChainRepository().getAllTradeBotData().isEmpty());
// The user now imports TradeBotStatesArchive.json
Path archiveImportPath = Paths.get(exportPath, "TradeBotStatesArchive.json");
repository.importDataFromFile(archiveImportPath.toString());
// The trade should be present in the database
assertEquals(1, repository.getCrossChainRepository().getAllTradeBotData().size());
// The trade bot data in the repository should match the one that was originally created
byte[] tradePrivateKey = tradeBotData.getTradePrivateKey();
TradeBotData repositoryTradeBotData = repository.getCrossChainRepository().getTradeBotData(tradePrivateKey);
assertNotNull(repositoryTradeBotData);
assertEquals(tradeBotData.toJson().toString(), repositoryTradeBotData.toJson().toString());
}
}
@Test
public void testExportAndImportMintingAccountData() throws DataException, IOException {
try (final Repository repository = RepositoryManager.getRepository()) {

4
src/test/java/org/qortal/test/api/BlockApiTests.java
View File

@@ -40,7 +40,7 @@ public class BlockApiTests extends ApiCommon {
byte[] signatureBytes = GenesisBlock.getInstance(repository).getSignature();
String signature = Base58.encode(signatureBytes);
assertNotNull(this.blocksResource.getBlock(signature));
assertNotNull(this.blocksResource.getBlock(signature, true));
}
}
@@ -72,7 +72,7 @@ public class BlockApiTests extends ApiCommon {
@Test
public void testGetBlockByHeight() {
assertNotNull(this.blocksResource.getByHeight(1));
assertNotNull(this.blocksResource.getByHeight(1, true));
}
@Test

769
src/test/java/org/qortal/test/crosschain/dogecoinv3/DogecoinACCTv3Tests.java Normal file
View File

@@ -0,0 +1,769 @@
package org.qortal.test.crosschain.dogecoinv3;
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.DogecoinACCTv3;
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 DogecoinACCTv3Tests 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[] dogecoinPublicKeyHash = 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 dogecoinAmount = 864200L; // 0.00864200 DOGE
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 = DogecoinACCTv3.buildQortalAT(tradeAccount.getAddress(), dogecoinPublicKeyHash, redeemAmount, dogecoinAmount, 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 = DogecoinACCTv3.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 = DogecoinACCTv3.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 = DogecoinACCTv3.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 = DogecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DogecoinACCTv3.buildTradeMessage(partner.getAddress(), dogecoinPublicKeyHash, 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 = DogecoinACCTv3.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 dogecoin PKH was extracted correctly
assertTrue(Arrays.equals(dogecoinPublicKeyHash, 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 = DogecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT BUT NOT FROM AT CREATOR
byte[] messageData = DogecoinACCTv3.buildTradeMessage(partner.getAddress(), dogecoinPublicKeyHash, 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 = DogecoinACCTv3.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 = DogecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DogecoinACCTv3.buildTradeMessage(partner.getAddress(), dogecoinPublicKeyHash, 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 = DogecoinACCTv3.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 = DogecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DogecoinACCTv3.buildTradeMessage(partner.getAddress(), dogecoinPublicKeyHash, 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 = DogecoinACCTv3.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 = DogecoinACCTv3.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 = DogecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DogecoinACCTv3.buildTradeMessage(partner.getAddress(), dogecoinPublicKeyHash, 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 = DogecoinACCTv3.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 = DogecoinACCTv3.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 = DogecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DogecoinACCTv3.buildTradeMessage(partner.getAddress(), dogecoinPublicKeyHash, 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 = DogecoinACCTv3.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 = DogecoinACCTv3.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 = DogecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = DogecoinACCTv3.buildTradeMessage(partner.getAddress(), dogecoinPublicKeyHash, 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 = DogecoinACCTv3.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, DogecoinACCTv3.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 = DogecoinACCTv3.buildQortalAT(tradeAddress, dogecoinPublicKeyHash, redeemAmount, dogecoinAmount, 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-DOGE cross-chain trade";
String description = String.format("Qortal-Dogecoin cross-chain trade");
String atType = "ACCT";
String tags = "QORT-DOGE 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 = DogecoinACCTv3.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 dogecoin: %s DOGE,\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"
+ "\tDogecoin 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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src/test/java/org/qortal/test/crosschain/litecoinv3/LitecoinACCTv3Tests.java Normal file
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package org.qortal.test.crosschain.litecoinv3;
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.LitecoinACCTv3;
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 LitecoinACCTv3Tests 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[] litecoinPublicKeyHash = 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 litecoinAmount = 864200L; // 0.00864200 LTC
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 = LitecoinACCTv3.buildQortalAT(tradeAccount.getAddress(), litecoinPublicKeyHash, redeemAmount, litecoinAmount, 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 = LitecoinACCTv3.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 = LitecoinACCTv3.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 = LitecoinACCTv3.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 = LitecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = LitecoinACCTv3.buildTradeMessage(partner.getAddress(), litecoinPublicKeyHash, 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 = LitecoinACCTv3.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 Litecoin PKH was extracted correctly
assertTrue(Arrays.equals(litecoinPublicKeyHash, 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 = LitecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT BUT NOT FROM AT CREATOR
byte[] messageData = LitecoinACCTv3.buildTradeMessage(partner.getAddress(), litecoinPublicKeyHash, 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 = LitecoinACCTv3.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 = LitecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = LitecoinACCTv3.buildTradeMessage(partner.getAddress(), litecoinPublicKeyHash, 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 = LitecoinACCTv3.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 = LitecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = LitecoinACCTv3.buildTradeMessage(partner.getAddress(), litecoinPublicKeyHash, 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 = LitecoinACCTv3.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 = LitecoinACCTv3.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 = LitecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = LitecoinACCTv3.buildTradeMessage(partner.getAddress(), litecoinPublicKeyHash, 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 = LitecoinACCTv3.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 = LitecoinACCTv3.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 = LitecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = LitecoinACCTv3.buildTradeMessage(partner.getAddress(), litecoinPublicKeyHash, 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 = LitecoinACCTv3.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 = LitecoinACCTv3.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 = LitecoinACCTv3.calcRefundTimeout(partnersOfferMessageTransactionTimestamp, lockTimeA);
// Send trade info to AT
byte[] messageData = LitecoinACCTv3.buildTradeMessage(partner.getAddress(), litecoinPublicKeyHash, 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 = LitecoinACCTv3.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, LitecoinACCTv3.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 = LitecoinACCTv3.buildQortalAT(tradeAddress, litecoinPublicKeyHash, redeemAmount, litecoinAmount, 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-LTC cross-chain trade";
String description = String.format("Qortal-Litecoin cross-chain trade");
String atType = "ACCT";
String tags = "QORT-LTC 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 = LitecoinACCTv3.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 Litecoin: %s LTC,\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"
+ "\tLitecoin 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");
}
}