/**
   * Expressions such as [foo() * 10 * 20] generate parse trees where no node has two const children
   * ((foo() * 10) * 20), so performArithmeticOp() won't fold it -- tryFoldLeftChildOp() will.
   * Specifically, it folds associative expressions where: - The left child is also an associative
   * expression of the same time. - The right child is a constant NUMBER constant. - The left
   * child's right child is a NUMBER constant.
   */
  private Node tryFoldLeftChildOp(Node n, Node left, Node right) {
    Token opType = n.getType();
    Preconditions.checkState(
        (NodeUtil.isAssociative(opType) && NodeUtil.isCommutative(opType)) || n.isAdd());

    Preconditions.checkState(!n.isAdd() || !NodeUtil.mayBeString(n, shouldUseTypes));

    // Use getNumberValue to handle constants like "NaN" and "Infinity"
    // other values are converted to numbers elsewhere.
    Double rightValObj = NodeUtil.getNumberValue(right, shouldUseTypes);
    if (rightValObj != null && left.getType() == opType) {
      Preconditions.checkState(left.getChildCount() == 2);

      Node ll = left.getFirstChild();
      Node lr = ll.getNext();

      Node valueToCombine = ll;
      Node replacement = performArithmeticOp(opType, valueToCombine, right);
      if (replacement == null) {
        valueToCombine = lr;
        replacement = performArithmeticOp(opType, valueToCombine, right);
      }
      if (replacement != null) {
        // Remove the child that has been combined
        left.removeChild(valueToCombine);
        // Replace the left op with the remaining child.
        n.replaceChild(left, left.removeFirstChild());
        // New "-Infinity" node need location info explicitly
        // added.
        replacement.useSourceInfoIfMissingFromForTree(right);
        n.replaceChild(right, replacement);
        reportCodeChange();
      }
    }

    return n;
  }
  private Node tryFoldAssign(Node n, Node left, Node right) {
    Preconditions.checkArgument(n.isAssign());

    if (!late) {
      return n;
    }

    // Tries to convert x = x + y -> x += y;
    if (!right.hasChildren() || right.getSecondChild() != right.getLastChild()) {
      // RHS must have two children.
      return n;
    }

    if (mayHaveSideEffects(left)) {
      return n;
    }

    Node newRight;
    if (areNodesEqualForInlining(left, right.getFirstChild())) {
      newRight = right.getLastChild();
    } else if (NodeUtil.isCommutative(right.getType())
        && areNodesEqualForInlining(left, right.getLastChild())) {
      newRight = right.getFirstChild();
    } else {
      return n;
    }

    Token newType = null;
    switch (right.getType()) {
      case ADD:
        newType = Token.ASSIGN_ADD;
        break;
      case BITAND:
        newType = Token.ASSIGN_BITAND;
        break;
      case BITOR:
        newType = Token.ASSIGN_BITOR;
        break;
      case BITXOR:
        newType = Token.ASSIGN_BITXOR;
        break;
      case DIV:
        newType = Token.ASSIGN_DIV;
        break;
      case LSH:
        newType = Token.ASSIGN_LSH;
        break;
      case MOD:
        newType = Token.ASSIGN_MOD;
        break;
      case MUL:
        newType = Token.ASSIGN_MUL;
        break;
      case RSH:
        newType = Token.ASSIGN_RSH;
        break;
      case SUB:
        newType = Token.ASSIGN_SUB;
        break;
      case URSH:
        newType = Token.ASSIGN_URSH;
        break;
      default:
        return n;
    }

    Node newNode = new Node(newType, left.detachFromParent(), newRight.detachFromParent());
    n.getParent().replaceChild(n, newNode);

    reportCodeChange();

    return newNode;
  }