Пример #1
0
  void andOrList(SqlWriter writer, SqlKind sepKind) {
    SqlBinaryOperator sepOp =
        sepKind == SqlKind.AND ? SqlStdOperatorTable.AND : SqlStdOperatorTable.OR;
    for (int i = 0; i < list.size(); i++) {
      SqlNode node = list.get(i);
      writer.sep(sepKind.name(), false);

      // The precedence pulling on the LHS of a node is the
      // right-precedence of the separator operator, except at the start
      // of the list; similarly for the RHS of a node. If the operator
      // has left precedence 4 and right precedence 5, the precedences
      // in a 3-node list will look as follows:
      //   0 <- node1 -> 4  5 <- node2 -> 4  5 <- node3 -> 0
      int lprec = (i == 0) ? 0 : sepOp.getRightPrec();
      int rprec = (i == (list.size() - 1)) ? 0 : sepOp.getLeftPrec();
      node.unparse(writer, lprec, rprec);
    }
  }
Пример #2
0
 public boolean equalsDeep(SqlNode node, boolean fail) {
   if (!(node instanceof SqlNodeList)) {
     assert !fail : this + "!=" + node;
     return false;
   }
   SqlNodeList that = (SqlNodeList) node;
   if (this.size() != that.size()) {
     assert !fail : this + "!=" + node;
     return false;
   }
   for (int i = 0; i < list.size(); i++) {
     SqlNode thisChild = list.get(i);
     final SqlNode thatChild = that.list.get(i);
     if (!thisChild.equalsDeep(thatChild, fail)) {
       return false;
     }
   }
   return true;
 }
Пример #3
0
 public int size() {
   return list.size();
 }
Пример #4
0
 public SqlNode[] toArray() {
   return list.toArray(new SqlNode[list.size()]);
 }
  public int reduceExpr(int opOrdinal, List<Object> list) {
    final SqlParserUtil.ToTreeListItem betweenNode =
        (SqlParserUtil.ToTreeListItem) list.get(opOrdinal);
    SqlOperator op = betweenNode.getOperator();
    assert op == this;

    // Break the expression up into expressions. For example, a simple
    // expression breaks down as follows:
    //
    //            opOrdinal   endExp1
    //            |           |
    //     a + b BETWEEN c + d AND e + f
    //    |_____|       |_____|   |_____|
    //     exp0          exp1      exp2
    // Create the expression between 'BETWEEN' and 'AND'.
    final SqlParserPos pos = ((SqlNode) list.get(opOrdinal + 1)).getParserPosition();
    SqlNode exp1 = SqlParserUtil.toTreeEx(list, opOrdinal + 1, 0, SqlKind.AND);
    if ((opOrdinal + 2) >= list.size()) {
      SqlParserPos lastPos = ((SqlNode) list.get(list.size() - 1)).getParserPosition();
      final int line = lastPos.getEndLineNum();
      final int col = lastPos.getEndColumnNum() + 1;
      SqlParserPos errPos = new SqlParserPos(line, col, line, col);
      throw SqlUtil.newContextException(
          errPos, EigenbaseResource.instance().BetweenWithoutAnd.ex());
    }
    final Object o = list.get(opOrdinal + 2);
    if (!(o instanceof SqlParserUtil.ToTreeListItem)) {
      SqlParserPos errPos = ((SqlNode) o).getParserPosition();
      throw SqlUtil.newContextException(
          errPos, EigenbaseResource.instance().BetweenWithoutAnd.ex());
    }
    if (((SqlParserUtil.ToTreeListItem) o).getOperator().getKind() != SqlKind.AND) {
      SqlParserPos errPos = ((SqlParserUtil.ToTreeListItem) o).getPos();
      throw SqlUtil.newContextException(
          errPos, EigenbaseResource.instance().BetweenWithoutAnd.ex());
    }

    // Create the expression after 'AND', but stopping if we encounter an
    // operator of lower precedence.
    //
    // For example,
    //   a BETWEEN b AND c + d OR e
    // becomes
    //   (a BETWEEN b AND c + d) OR e
    // because OR has lower precedence than BETWEEN.
    SqlNode exp2 = SqlParserUtil.toTreeEx(list, opOrdinal + 3, getRightPrec(), SqlKind.OTHER);

    // Create the call.
    SqlNode exp0 = (SqlNode) list.get(opOrdinal - 1);
    SqlCall newExp =
        createCall(
            betweenNode.getPos(),
            exp0,
            exp1,
            exp2,
            SqlLiteral.createSymbol(flag, SqlParserPos.ZERO));

    // Replace all of the matched nodes with the single reduced node.
    SqlParserUtil.replaceSublist(list, opOrdinal - 1, opOrdinal + 4, newExp);

    // Return the ordinal of the new current node.
    return opOrdinal - 1;
  }