private void appendScanRow(StringBuilder buf, Bound bound) { ScanRanges scanRanges = context.getScanRanges(); KeyRange minMaxRange = context.getMinMaxRange(); Iterator<byte[]> minMaxIterator = Iterators.emptyIterator(); if (minMaxRange != null) { RowKeySchema schema = tableRef.getTable().getRowKeySchema(); if (!minMaxRange.isUnbound(bound)) { minMaxIterator = new RowKeyValueIterator(schema, minMaxRange.getRange(bound)); } } int nRanges = scanRanges.getRanges().size(); for (int i = 0, minPos = 0; minPos < nRanges || minMaxIterator.hasNext(); i++) { List<KeyRange> ranges = minPos >= nRanges ? EVERYTHING : scanRanges.getRanges().get(minPos++); KeyRange range = bound == Bound.LOWER ? ranges.get(0) : ranges.get(ranges.size() - 1); byte[] b = range.getRange(bound); Boolean isNull = KeyRange.IS_NULL_RANGE == range ? Boolean.TRUE : KeyRange.IS_NOT_NULL_RANGE == range ? Boolean.FALSE : null; if (minMaxIterator.hasNext()) { byte[] bMinMax = minMaxIterator.next(); int cmp = Bytes.compareTo(bMinMax, b) * (bound == Bound.LOWER ? 1 : -1); if (cmp > 0) { minPos = nRanges; b = bMinMax; isNull = null; } else if (cmp < 0) { minMaxIterator = Iterators.emptyIterator(); } } appendPKColumnValue(buf, b, isNull, i); buf.append(','); } }
private static byte[] getKey( RowKeySchema schema, List<List<KeyRange>> slots, int[] slotSpan, Bound bound) { if (slots.isEmpty()) { return KeyRange.UNBOUND; } int[] position = new int[slots.size()]; int maxLength = 0; for (int i = 0; i < position.length; i++) { position[i] = bound == Bound.LOWER ? 0 : slots.get(i).size() - 1; KeyRange range = slots.get(i).get(position[i]); Field field = schema.getField(i + slotSpan[i]); int keyLength = range.getRange(bound).length; if (!field.getDataType().isFixedWidth()) { keyLength++; if (range.isUnbound(bound) && !range.isInclusive(bound) && field.getSortOrder() == SortOrder.DESC) { keyLength++; } } maxLength += keyLength; } byte[] key = new byte[maxLength]; int length = setKey(schema, slots, slotSpan, position, bound, key, 0, 0, position.length); if (length == 0) { return KeyRange.UNBOUND; } if (length == maxLength) { return key; } byte[] keyCopy = new byte[length]; System.arraycopy(key, 0, keyCopy, 0, length); return keyCopy; }
public static int setKey( RowKeySchema schema, List<List<KeyRange>> slots, int[] slotSpan, int[] position, Bound bound, byte[] key, int byteOffset, int slotStartIndex, int slotEndIndex, int schemaStartIndex) { int offset = byteOffset; boolean lastInclusiveUpperSingleKey = false; boolean anyInclusiveUpperRangeKey = false; // The index used for slots should be incremented by 1, // but the index for the field it represents in the schema // should be incremented by 1 + value in the current slotSpan index // slotSpan stores the number of columns beyond one that the range spans Field field = null; int i = slotStartIndex, fieldIndex = ScanUtil.getRowKeyPosition(slotSpan, slotStartIndex); for (i = slotStartIndex; i < slotEndIndex; i++) { // Build up the key by appending the bound of each key range // from the current position of each slot. KeyRange range = slots.get(i).get(position[i]); // Use last slot in a multi-span column to determine if fixed width field = schema.getField(fieldIndex + slotSpan[i]); boolean isFixedWidth = field.getDataType().isFixedWidth(); fieldIndex += slotSpan[i] + 1; /* * If the current slot is unbound then stop if: * 1) setting the upper bound. There's no value in * continuing because nothing will be filtered. * 2) setting the lower bound when the type is fixed length * for the same reason. However, if the type is variable width * continue building the key because null values will be filtered * since our separator byte will be appended and incremented. */ if (range.isUnbound(bound) && (bound == Bound.UPPER || isFixedWidth)) { break; } byte[] bytes = range.getRange(bound); System.arraycopy(bytes, 0, key, offset, bytes.length); offset += bytes.length; /* * We must add a terminator to a variable length key even for the last PK column if * the lower key is non inclusive or the upper key is inclusive. Otherwise, we'd be * incrementing the key value itself, and thus bumping it up too much. */ boolean inclusiveUpper = range.isInclusive(bound) && bound == Bound.UPPER; boolean exclusiveLower = !range.isInclusive(bound) && bound == Bound.LOWER; // If we are setting the upper bound of using inclusive single key, we remember // to increment the key if we exit the loop after this iteration. // // We remember to increment the last slot if we are setting the upper bound with an // inclusive range key. // // We cannot combine the two flags together in case for single-inclusive key followed // by the range-exclusive key. In that case, we do not need to increment the end at the // end. But if we combine the two flag, the single inclusive key in the middle of the // key slots would cause the flag to become true. lastInclusiveUpperSingleKey = range.isSingleKey() && inclusiveUpper; anyInclusiveUpperRangeKey |= !range.isSingleKey() && inclusiveUpper; // A null or empty byte array is always represented as a zero byte byte sepByte = SchemaUtil.getSeparatorByte(schema.rowKeyOrderOptimizable(), bytes.length == 0, field); if (!isFixedWidth && (fieldIndex < schema.getMaxFields() || inclusiveUpper || exclusiveLower || sepByte == QueryConstants.DESC_SEPARATOR_BYTE)) { key[offset++] = sepByte; // Set lastInclusiveUpperSingleKey back to false if this is the last pk column // as we don't want to increment the null byte in this case lastInclusiveUpperSingleKey &= i < schema.getMaxFields() - 1; } // If we are setting the lower bound with an exclusive range key, we need to bump the // slot up for each key part. For an upper bound, we bump up an inclusive key, but // only after the last key part. if (exclusiveLower) { if (!ByteUtil.nextKey(key, offset)) { // Special case for not being able to increment. // In this case we return a negative byteOffset to // remove this part from the key being formed. Since the // key has overflowed, this means that we should not // have an end key specified. return -byteOffset; } // We're filtering on values being non null here, but we still need the 0xFF // terminator, since DESC keys ignore the last byte as it's expected to be // the terminator. Without this, we'd ignore the separator byte that was // just added and incremented. if (!isFixedWidth && bytes.length == 0 && SchemaUtil.getSeparatorByte(schema.rowKeyOrderOptimizable(), false, field) == QueryConstants.DESC_SEPARATOR_BYTE) { key[offset++] = QueryConstants.DESC_SEPARATOR_BYTE; } } } if (lastInclusiveUpperSingleKey || anyInclusiveUpperRangeKey) { if (!ByteUtil.nextKey(key, offset)) { // Special case for not being able to increment. // In this case we return a negative byteOffset to // remove this part from the key being formed. Since the // key has overflowed, this means that we should not // have an end key specified. return -byteOffset; } } // Remove trailing separator bytes, since the columns may have been added // after the table has data, in which case there won't be a separator // byte. if (bound == Bound.LOWER) { while (--i >= schemaStartIndex && offset > byteOffset && !(field = schema.getField(--fieldIndex)).getDataType().isFixedWidth() && field.getSortOrder() == SortOrder.ASC && key[offset - 1] == QueryConstants.SEPARATOR_BYTE) { offset--; fieldIndex -= slotSpan[i]; } } return offset - byteOffset; }