<p>You are given a <strong>0-indexed</strong> integer array <code>nums</code> having length <code>n</code>.</p> <p>You are allowed to perform a special move <strong>any</strong> number of times (<strong>including zero</strong>) on <code>nums</code>. In one <strong>special</strong> <strong>move</strong> you perform the following steps <strong>in order</strong>:</p> <ul> <li>Choose an index <code>i</code> in the range <code>[0, n - 1]</code>, and a <strong>positive</strong> integer <code>x</code>.</li> <li>Add <code>|nums[i] - x|</code> to the total cost.</li> <li>Change the value of <code>nums[i]</code> to <code>x</code>.</li> </ul> <p>A <strong>palindromic number</strong> is a positive integer that remains the same when its digits are reversed. For example, <code>121</code>, <code>2552</code> and <code>65756</code> are palindromic numbers whereas <code>24</code>, <code>46</code>, <code>235</code> are not palindromic numbers.</p> <p>An array is considered <strong>equalindromic</strong> if all the elements in the array are equal to an integer <code>y</code>, where <code>y</code> is a <strong>palindromic number</strong> less than <code>10<sup>9</sup></code>.</p> <p>Return <em>an integer denoting the <strong>minimum</strong> possible total cost to make </em><code>nums</code><em> <strong>equalindromic</strong> by performing any number of special moves.</em></p> <p> </p> <p><strong class="example">Example 1:</strong></p> <pre> <strong>Input:</strong> nums = [1,2,3,4,5] <strong>Output:</strong> 6 <strong>Explanation:</strong> We can make the array equalindromic by changing all elements to 3 which is a palindromic number. The cost of changing the array to [3,3,3,3,3] using 4 special moves is given by |1 - 3| + |2 - 3| + |4 - 3| + |5 - 3| = 6. It can be shown that changing all elements to any palindromic number other than 3 cannot be achieved at a lower cost. </pre> <p><strong class="example">Example 2:</strong></p> <pre> <strong>Input:</strong> nums = [10,12,13,14,15] <strong>Output:</strong> 11 <strong>Explanation:</strong> We can make the array equalindromic by changing all elements to 11 which is a palindromic number. The cost of changing the array to [11,11,11,11,11] using 5 special moves is given by |10 - 11| + |12 - 11| + |13 - 11| + |14 - 11| + |15 - 11| = 11. It can be shown that changing all elements to any palindromic number other than 11 cannot be achieved at a lower cost. </pre> <p><strong class="example">Example 3:</strong></p> <pre> <strong>Input:</strong> nums = [22,33,22,33,22] <strong>Output:</strong> 22 <strong>Explanation:</strong> We can make the array equalindromic by changing all elements to 22 which is a palindromic number. The cost of changing the array to [22,22,22,22,22] using 2 special moves is given by |33 - 22| + |33 - 22| = 22. It can be shown that changing all elements to any palindromic number other than 22 cannot be achieved at a lower cost. </pre> <p> </p> <p><strong>Constraints:</strong></p> <ul> <li><code>1 <= n <= 10<sup>5</sup></code></li> <li><code>1 <= nums[i] <= 10<sup>9</sup></code></li> </ul>