Exemple #1
0
 @Test
 public void testProofOfWork() throws Exception {
   // This params accepts any difficulty target.
   NetworkParameters params = UnitTestParams.get();
   Block block = params.getDefaultSerializer().makeBlock(blockBytes);
   block.setNonce(12346);
   try {
     block.verify(Block.BLOCK_HEIGHT_GENESIS, EnumSet.noneOf(Block.VerifyFlag.class));
     fail();
   } catch (VerificationException e) {
     // Expected.
   }
   // Blocks contain their own difficulty target. The BlockChain verification mechanism is what
   // stops real blocks
   // from containing artificially weak difficulties.
   block.setDifficultyTarget(Block.EASIEST_DIFFICULTY_TARGET);
   // Now it should pass.
   block.verify(Block.BLOCK_HEIGHT_GENESIS, EnumSet.noneOf(Block.VerifyFlag.class));
   // Break the nonce again at the lower difficulty level so we can try solving for it.
   block.setNonce(1);
   try {
     block.verify(Block.BLOCK_HEIGHT_GENESIS, EnumSet.noneOf(Block.VerifyFlag.class));
     fail();
   } catch (VerificationException e) {
     // Expected to fail as the nonce is no longer correct.
   }
   // Should find an acceptable nonce.
   block.solve();
   block.verify(Block.BLOCK_HEIGHT_GENESIS, EnumSet.noneOf(Block.VerifyFlag.class));
   assertEquals(block.getNonce(), 2);
 }
  public void testBlock(byte[] blockBytes, boolean isChild, boolean lazy, boolean retain)
      throws Exception {
    // reference serializer to produce comparison serialization output after changes to
    // message structure.
    BitcoinSerializer bsRef = new BitcoinSerializer(unitTestParams, false, false);
    ByteArrayOutputStream bos = new ByteArrayOutputStream();

    BitcoinSerializer bs = new BitcoinSerializer(unitTestParams, lazy, retain);
    Block b1;
    Block bRef;
    b1 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));

    // verify our reference BitcoinSerializer produces matching byte array.
    bos.reset();
    bsRef.serialize(bRef, bos);
    assertTrue(Arrays.equals(bos.toByteArray(), blockBytes));

    // check lazy and retain status survive both before and after a serialization
    assertEquals(!lazy, b1.isParsedTransactions());
    assertEquals(!lazy, b1.isParsedHeader());
    if (b1.isParsedHeader()) assertEquals(retain, b1.isHeaderBytesValid());
    if (b1.isParsedTransactions()) assertEquals(retain, b1.isTransactionBytesValid());

    serDeser(bs, b1, blockBytes, null, null);

    assertEquals(!lazy, b1.isParsedTransactions());
    assertEquals(!lazy, b1.isParsedHeader());
    if (b1.isParsedHeader()) assertEquals(retain, b1.isHeaderBytesValid());
    if (b1.isParsedTransactions()) assertEquals(retain, b1.isTransactionBytesValid());

    // compare to ref block
    bos.reset();
    bsRef.serialize(bRef, bos);
    serDeser(bs, b1, bos.toByteArray(), null, null);

    // retrieve a value from a child
    b1.getTransactions();
    assertTrue(b1.isParsedTransactions());
    if (b1.getTransactions().size() > 0) {
      assertTrue(b1.isParsedTransactions());
      Transaction tx1 = b1.getTransactions().get(0);

      // this will always be true for all children of a block once they are retrieved.
      // the tx child inputs/outputs may not be parsed however.

      // no longer forced to parse if length not provided.
      // assertEquals(true, tx1.isParsed());
      if (tx1.isParsed()) assertEquals(retain, tx1.isCached());
      else assertTrue(tx1.isCached());

      // does it still match ref block?
      serDeser(bs, b1, bos.toByteArray(), null, null);
    }

    // refresh block
    b1 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));

    // retrieve a value from header
    b1.getDifficultyTarget();
    assertTrue(b1.isParsedHeader());
    assertEquals(lazy, !b1.isParsedTransactions());

    // does it still match ref block?
    serDeser(bs, b1, bos.toByteArray(), null, null);

    // refresh block
    b1 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));

    // retrieve a value from a child and header
    b1.getDifficultyTarget();
    assertTrue(b1.isParsedHeader());
    assertEquals(lazy, !b1.isParsedTransactions());

    b1.getTransactions();
    assertTrue(b1.isParsedTransactions());
    if (b1.getTransactions().size() > 0) {
      assertTrue(b1.isParsedTransactions());
      Transaction tx1 = b1.getTransactions().get(0);

      // no longer forced to parse if length not provided.
      // assertEquals(true, tx1.isParsed());

      if (tx1.isParsed()) assertEquals(retain, tx1.isCached());
      else assertTrue(tx1.isCached());
    }
    // does it still match ref block?
    serDeser(bs, b1, bos.toByteArray(), null, null);

    // refresh block
    b1 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));

    // change a value in header
    b1.setNonce(23);
    bRef.setNonce(23);
    assertTrue(b1.isParsedHeader());
    assertEquals(lazy, !b1.isParsedTransactions());
    assertFalse(b1.isHeaderBytesValid());
    if (b1.isParsedTransactions()) assertEquals(retain, b1.isTransactionBytesValid());
    else assertEquals(true, b1.isTransactionBytesValid());
    // does it still match ref block?
    bos.reset();
    bsRef.serialize(bRef, bos);
    serDeser(bs, b1, bos.toByteArray(), null, null);

    // refresh block
    b1 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));

    // retrieve a value from a child of a child
    b1.getTransactions();
    if (b1.getTransactions().size() > 0) {
      Transaction tx1 = b1.getTransactions().get(0);

      TransactionInput tin = tx1.getInputs().get(0);

      assertTrue(tx1.isParsed());
      assertTrue(b1.isParsedTransactions());
      assertEquals(!lazy, b1.isParsedHeader());

      assertEquals(!lazy, tin.isParsed());
      assertEquals(tin.isParsed() ? retain : true, tin.isCached());

      // does it still match ref tx?
      bos.reset();
      bsRef.serialize(bRef, bos);
      serDeser(bs, b1, bos.toByteArray(), null, null);
    }

    // refresh block
    b1 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));

    // add an input
    b1.getTransactions();
    if (b1.getTransactions().size() > 0) {
      Transaction tx1 = b1.getTransactions().get(0);

      if (tx1.getInputs().size() > 0) {
        tx1.addInput(tx1.getInputs().get(0));
        // replicate on reference tx
        bRef.getTransactions().get(0).addInput(bRef.getTransactions().get(0).getInputs().get(0));

        assertFalse(tx1.isCached());
        assertTrue(tx1.isParsed());
        assertFalse(b1.isTransactionBytesValid());
        assertTrue(b1.isParsedHeader());

        // confirm sibling cache status was unaffected
        if (tx1.getInputs().size() > 1) {
          boolean parsed = tx1.getInputs().get(1).isParsed();
          assertEquals(parsed ? retain : true, tx1.getInputs().get(1).isCached());
          assertEquals(!lazy, parsed);
        }

        // this has to be false. Altering a tx invalidates the merkle root.
        // when we have seperate merkle caching then the entire header won't need to be
        // invalidated.
        assertFalse(b1.isHeaderBytesValid());

        bos.reset();
        bsRef.serialize(bRef, bos);
        byte[] source = bos.toByteArray();
        // confirm we still match the reference tx.
        serDeser(bs, b1, source, null, null);
      }

      // does it still match ref tx?
      bos.reset();
      bsRef.serialize(bRef, bos);
      serDeser(bs, b1, bos.toByteArray(), null, null);
    }

    // refresh block
    b1 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    Block b2 = (Block) bs.deserialize(new ByteArrayInputStream(blockBytes));
    bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));
    Block bRef2 = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));

    // reparent an input
    b1.getTransactions();
    if (b1.getTransactions().size() > 0) {
      Transaction tx1 = b1.getTransactions().get(0);
      Transaction tx2 = b2.getTransactions().get(0);

      if (tx1.getInputs().size() > 0) {
        TransactionInput fromTx1 = tx1.getInputs().get(0);
        tx2.addInput(fromTx1);

        // replicate on reference tx
        TransactionInput fromTxRef = bRef.getTransactions().get(0).getInputs().get(0);
        bRef2.getTransactions().get(0).addInput(fromTxRef);

        // b1 hasn't changed but it's no longer in the parent
        // chain of fromTx1 so has to have been uncached since it won't be
        // notified of changes throught the parent chain anymore.
        assertFalse(b1.isTransactionBytesValid());

        // b2 should have it's cache invalidated because it has changed.
        assertFalse(b2.isTransactionBytesValid());

        bos.reset();
        bsRef.serialize(bRef2, bos);
        byte[] source = bos.toByteArray();
        // confirm altered block matches altered ref block.
        serDeser(bs, b2, source, null, null);
      }

      // does unaltered block still match ref block?
      bos.reset();
      bsRef.serialize(bRef, bos);
      serDeser(bs, b1, bos.toByteArray(), null, null);

      // how about if we refresh it?
      bRef = (Block) bsRef.deserialize(new ByteArrayInputStream(blockBytes));
      bos.reset();
      bsRef.serialize(bRef, bos);
      serDeser(bs, b1, bos.toByteArray(), null, null);
    }
  }