A friend of mine just had his interview at Google and got rejected because he couldn't give a solution to this question.

I have my own interview in a couple of days and can't seem to figure out a way to solve it.

Here's the question:

You are given a pattern, such as [a b a b]. You are also given a string, example "redblueredblue". I need to write a program that tells whether the string follows the given pattern or not.

A few examples:

Pattern: [a b b a] String: catdogdogcat returns 1

Pattern: [a b a b] String: redblueredblue returns 1

Pattern: [a b b a] String: redblueredblue returns 0

I thought of a few approaches, like getting the number of unique characters in the pattern and then finding that many unique substrings of the string then comparing with the pattern using a hashmap. However, that turns out to be a problem if the substring of a is a part of b.

It'd be really great if any of you could help me out with it. :)


Added Info: There can be any number of characters in the pattern (a-z). Two characters won't represent the same substring. Also, a character can't represent an empty string.

  • Are there any restrictions on the pattern? Is it just the combinations of symbols in any order? – Alexandru Barbarosie Nov 2 '14 at 18:34
  • 1
    Can any of the strings that match a particular letter in the pattern be empty? – templatetypedef Nov 2 '14 at 18:34
  • Also, how many possible characters are in the pattern string? Is it always a and b, or can there be more characters? – templatetypedef Nov 2 '14 at 18:36
  • There can be any number of characters in the patters. Two characters won't represent the same substring. Also, a character can't represent an empty string. – SinnerShanky Nov 2 '14 at 18:40
  • 1
    There's a naive solution that works by enumerating all partitions of the string into substrings and checking that it matches the pattern string, but that might take time exponential in the length of the pattern string. I'm curious if there is a fundamentally faster approach, or if this is known to be NP-complete (or co-NP-complete?) – templatetypedef Nov 2 '14 at 20:00

14 Answers 14


Don't you just need to translate the pattern to a regexp using backreferences, i.e. something like this (Python 3 with the "re" module loaded):

>>> print(re.match('(.+)(.+)\\2\\1', 'catdogdogcat'))
<_sre.SRE_Match object; span=(0, 12), match='catdogdogcat'>

>>> print(re.match('(.+)(.+)\\1\\2', 'redblueredblue'))
<_sre.SRE_Match object; span=(0, 14), match='redblueredblue'>

>>> print(re.match('(.+)(.+)\\2\\1', 'redblueredblue'))

The regexp looks pretty trivial to generate. If you need to support more than 9 backrefs, you can use named groups - see the Python regexp docs.


The simplest solution that I can think of is to divide the given string into four parts and compare the individual parts. You don't know how long a or b is, but both as are of the same length as well as bs are. So the number of ways how to divide the given string is not very large.

Example: pattern = [a b a b], given string = redblueredblue (14 characters in total)

  1. |a| (length of a) = 1, then that makes 2 characters for as and 12 characters is left for bs, i.e. |b| = 6. Divided string = r edblue r edblue. Whoa, this matches right away!
  2. (just out of curiosity) |a| = 2, |b| = 5 -> divided string = re dblue re dblue -> match

Example 2: pattern = [a b a b], string = redbluebluered (14 characters in total)

  1. |a| = 1, |b| = 6 -> divided string = r edblue b luered -> no match
  2. |a| = 2, |b| = 5 -> divided string = re dblue bl uered -> no match
  3. |a| = 3, |b| = 4 -> divided string = red blue blu ered -> no match

The rest is not needed to be checked because if you switched a for b and vice versa, the situation is identical.

What is the pattern that has [a b c a b c] ?


Here is java backtracking solution. Source link.

public class Solution {

public boolean isMatch(String str, String pat) {
Map<Character, String> map = new HashMap<>();
return isMatch(str, 0, pat, 0, map);

boolean isMatch(String str, int i, String pat, int j, Map<Character,  String> map) {
// base case
if (i == str.length() && j == pat.length()) return true;
if (i == str.length() || j == pat.length()) return false;

// get current pattern character
char c = pat.charAt(j);

// if the pattern character exists
if (map.containsKey(c)) {
  String s = map.get(c);

  // then check if we can use it to match str[i...i+s.length()]
  if (i + s.length() > str.length() || !str.substring(i, i + s.length()).equals(s)) {
    return false;

  // if it can match, great, continue to match the rest
  return isMatch(str, i + s.length(), pat, j + 1, map);

// pattern character does not exist in the map
for (int k = i; k < str.length(); k++) {
  // create or update the map
  map.put(c, str.substring(i, k + 1));

  // continue to match the rest
  if (isMatch(str, k + 1, pat, j + 1, map)) {
    return true;

// we've tried our best but still no luck

return false;


One more brute force recursion solution:

import java.io.IOException;
import java.util.*;

public class Test {

    public static void main(String[] args) throws IOException {
        int res;
        res = wordpattern("abba", "redbluebluered");
        System.out.println("RESULT: " + res);

    static int wordpattern(String pattern, String input) {
        int patternSize = 1;
        boolean res = findPattern(pattern, input, new HashMap<Character, String>(), patternSize);
        while (!res && patternSize < input.length())
            res = findPattern(pattern, input, new HashMap<Character, String>(), patternSize);
        return res ? 1 : 0;

    private static boolean findPattern(String pattern, String input, Map<Character, String> charToValue, int patternSize) {
        StringBuilder sb = new StringBuilder();
        for (int i = 0; i < pattern.length(); i++) {
            char c = pattern.charAt(i);
            if (charToValue.containsKey(c)) {
            } else {
                // new character in pattern
                if (sb.length() + patternSize > input.length()) {
                    return false;
                } else {
                    String substring = input.substring(sb.length(), sb.length() + patternSize);
                    charToValue.put(c, substring);
                    int newPatternSize = 1;
                    boolean res = findPattern(pattern, input, new HashMap<>(charToValue), newPatternSize);
                    while (!res && newPatternSize + sb.length() + substring.length() < input.length() - 1) {
                        res = findPattern(pattern, input, new HashMap<>(charToValue), newPatternSize);
                    return res;
        return sb.toString().equals(input) && allValuesUniq(charToValue.values());

    private static boolean allValuesUniq(Collection<String> values) {
        Set<String> set = new HashSet<>();
        for (String v : values) {
            if (!set.add(v)) {
                return false;
        return true;

My Implementation on C#. Tried to look for something clean in C#, couldn't find. So I'll add it to here.

   private static bool CheckIfStringFollowOrder(string text, string subString)
        int subStringLength = subString.Length;

        if (text.Length < subStringLength) return false;

        char x, y;
        int indexX, indexY;

        for (int i=0; i < subStringLength -1; i++)
            indexX = -1;
            indexY = -1;

            x = subString[i];
            y = subString[i + 1];

            indexX = text.LastIndexOf(x);
            indexY = text.IndexOf(y);

            if (y < x || indexX == -1 || indexY == -1)
                return false;

        return true;

  • Looks like you are implementing something completely different. – apatsekin Jun 7 '18 at 16:28


I tested your DFS solution and it seems wrong, like case:

pattern = ["a", "b", "a"], s = "patrpatrr"

The problem is that when you meet a pattern that already exists in dict and find it cannot fit the following string, you delete and try to assign it a new value. However, you haven't check this pattern with the new value for the previous times it occurs.

My idea is about providing addition dict (or merge in this dict) new value to keep track of the first time it appears and another stack to keep track of the unique pattern I meet. when "not match" occurs, I will know there is some problem with the last pattern and I pop it from the stack and modify the corresponding value in the dict, also I will start to check again at that corresponding index. If cannot be modified any more. I will pop until there is none left in the stack and then return False.

(I want to add comments but don't have enough reputation as a new user.. I haven't implement it but till now I haven't find any error in my logic. I am sorry if there is something wrong with my solution== I will try to implement it later.)

  • Indeed, the version I pushed was pretty much garbage. I added Alexander Taylor's cases and yours, fixed it and cleaned it up a little. See the updated gist. I still prefer the regexp idea though: the regexp engine does the DFS for you, so less risk of wiriting bugs :-D – EricM Jan 3 '15 at 17:14

I can't think of much better than the brute force solution: try every possible partitioning of the word (this is essentially what Jan described).

The run-time complexity is O(n^(2m)) where m is the length of the pattern and n is the length of the string.

Here's what the code for that looks like (I made my code return the actual mapping instead of just 0 or 1. Modifying the code to return 0 or 1 is easy):

import java.util.Arrays;
import java.util.ArrayDeque;
import java.util.ArrayList;
import java.util.Deque;
import java.util.HashMap;
import java.util.List;
import java.util.Map;

public class StringBijection {
    public static void main(String[] args) {
        String chars = "abaac";
        String string = "johnjohnnyjohnjohncodes";
        List<String> stringBijection = getStringBijection(chars, string);


    public static List<String> getStringBijection(String chars, String string) {
        if (chars == null || string == null) {
            return null;

        Map<Character, String> bijection = new HashMap<Character, String>();
        Deque<String> assignments = new ArrayDeque<String>();
        List<String> results = new ArrayList<String>();
        boolean hasBijection = getStringBijection(chars, string, 0, 0, bijection, assignments);

        if (!hasBijection) {
            return null;

        for (String result : assignments) {

        return results;

    private static boolean getStringBijection(String chars, String string, int charIndex, int stringIndex, Map<Character, String> bijection, Deque<String> assignments) {
        int charsLen = chars.length();
        int stringLen = string.length();

        if (charIndex == charsLen && stringIndex == stringLen) {
            return true;
        } else if (charIndex == charsLen || stringIndex == stringLen) {
            return false;

        char currentChar = chars.charAt(charIndex);
        List<String> possibleWords = new ArrayList<String>();
        boolean charAlreadyAssigned = bijection.containsKey(currentChar);

        if (charAlreadyAssigned) {
            String word = bijection.get(currentChar);
        } else {
            StringBuilder word = new StringBuilder();

            for (int i = stringIndex; i < stringLen; ++i) {

        for (String word : possibleWords) {
            int wordLen = word.length();
            int endIndex = stringIndex + wordLen;

            if (endIndex <= stringLen && string.substring(stringIndex, endIndex).equals(word)) {
                if (!charAlreadyAssigned) {
                    bijection.put(currentChar, word);


                boolean done = getStringBijection(chars, string, charIndex + 1, stringIndex + wordLen, bijection, assignments);

                if (done) {
                    return true;


                if (!charAlreadyAssigned) {

        return false;

If you are looking for a solution in C++, here is a brute force solution: https://linzhongzl.wordpress.com/2014/11/04/repeating-pattern-match/


Plain Brute Force, not sure if any optimization is possible here ..

import java.util.HashMap;
import java.util.Map;
import org.junit.*;

public class Pattern {
   private Map<Character, String> map;
   private boolean matchInt(String pattern, String str) {
      if (pattern.length() == 0) {
         return str.length() == 0;
      char pch = pattern.charAt(0);
      for (int i = 0; i < str.length(); ++i) {
         if (!map.containsKey(pch)) {
            String val = str.substring(0, i + 1);
            map.put(pch, val);
            if (matchInt(pattern.substring(1), str.substring(val.length()))) {
               return true;
            } else {
         } else {
            String val = map.get(pch);
            if (!str.startsWith(val)) {
               return false;
            return matchInt(pattern.substring(1), str.substring(val.length()));
      return false;
   public boolean match(String pattern, String str) {
      map = new HashMap<Character, String>();
      return matchInt(pattern, str);
   public void test1() {
      Assert.assertTrue(match("aabb", "ABABCDCD"));
      Assert.assertTrue(match("abba", "redbluebluered"));
      Assert.assertTrue(match("abba", "asdasdasdasd"));
      Assert.assertFalse(match("aabb", "xyzabcxzyabc"));
      Assert.assertTrue(match("abba", "catdogdogcat"));
      Assert.assertTrue(match("abab", "ryry"));
      Assert.assertFalse(match("abba", " redblueredblue"));
class StringPattern{
  int n, pn;
  string str;
  unordered_map<string, pair<string, int>> um;
  vector<string> p;
  bool match(string pat, string str_) {
    istringstream istr(pat);
    string x;
    while(istr>>x) p.push_back(x);
    return dfs(0, 0);

  bool dfs(int i, int c) {
    if(i>=n) {
          return 1;
    if(c>=pn) return 0;
    for(int len=1; i+len-1<n; len++) {
      string sub=str.substr(i, len);

      if(um.count(p[c]) && um[p[c]].fi!=sub
         || um.count(sub) && um[sub].fi!=p[c]
      //cout<<p[c]<<" "<<sub<<endl;
      if(dfs(i+len, c+1)) return 1;
      if(!um[p[c]].se) um.erase(p[c]);
      if(!um[sub].se) um.erase(sub);
    return 0;

My solution, as two side hashmap is needed, and also need to count the hash map counts


My java script solution:

function isMatch(pattern, str){

  var map = {}; //store the pairs of pattern and strings

  function checkMatch(pattern, str) {

    if (pattern.length == 0 && str.length == 0){
      return true;
    //if the pattern or the string is empty
    if (pattern.length == 0 || str.length == 0){
      return false;

    //store the next pattern
    var currentPattern = pattern.charAt(0);

    if (currentPattern in map){
        //the pattern has alredy seen, check if there is a match with the string
        if (str.length >= map[currentPattern].length  && str.startsWith(map[currentPattern])){
          //there is a match, try all other posibilities
          return checkMatch(pattern.substring(1), str.substring(map[currentPattern].length));
        } else {
          //no match, return false
          return false;

    //the current pattern is new, try all the posibilities of current string
    for (var i=1; i <= str.length; i++){
        var stringToCheck = str.substring(0, i);

        //store in the map
        map[currentPattern] = stringToCheck;
        //try the rest
        var match = checkMatch(pattern.substring(1), str.substring(i));
        if (match){
            //there is a match
             return true;
        } else {
           //if there is no match, delete the pair from the map
           delete map[currentPattern];
    return false;

  return checkMatch(pattern, str);



I solved this as a language production problem using regexen.

def  wordpattern( pattern,  string):
        input: pattern 'abba'
        string  'redbluebluered'
        output: 1 for match, 2 for no match

    # assemble regex into something like this for 'abba':
    # '^(?P<A>.+)(?P<B>.+)(?P=B)(?P=A)$'
    p = pattern
    for c in pattern:
        C = c.upper()
        p = p.replace(c,"(?P<{0}>.+)".format(C),1)
        p = p.replace(c,"(?P={0})".format(C),len(pattern))
    p = '^' + p + '$'

    # check for a preliminary match
    if re.search(p,string):
        rem = re.match(p,string)
        seen = {}
        # check to ensure that no points in the pattern share the same match
        for c in pattern:
            s = rem.group(c.upper())
            # has match been seen? yes, fail, no continue
            if s in seen and seen[s] != c:
                return 0
            seen[s] = c
        # success
            return  1
    # did not hit the search, fail
    return 0

pattern - "abba"; input - "redbluebluered"

  1. Find counts for every unique char in pattern, assign to list pattern_count. Ex.: [2,2] for a and b.
  2. Assign pattern_lengths for each unique char. Ex.: [1,1].
  3. Iterate values of pattern_lengths right-to-left maintaining equation: pattern_count * (pattern_lengths)^T = length(input) (dot product of vectors). Use step to jump directly to next equation root.
  4. When equation holds, check if string follows patterns with current pattern_lenghts (check_combination())

Python implementation:

def check(pattern, input):
    def _unique(pattern):
        hmap = {}
        for i in pattern:
            if i not in hmap:
                hmap[i] = 1
                hmap[i] += 1
        return hmap.keys(), hmap.values()
    def check_combination(pattern, string, pattern_unique, pattern_lengths):
        pos = 0
        hmap = {}
        _set = set()
        for code in pattern:
            string_value = string[pos:pos + pattern_lengths[pattern_unique.index(code)]]
            if code in hmap:
                if hmap[code] != string_value:
                    return False
                if string_value in _set:
                    return False
                hmap[code] = string_value
            pos += len(string_value)
        return False if pos < len(string) else True

    pattern = list(pattern)
    pattern_unique, pattern_count = _unique(pattern)
    pattern_lengths = [1] * len(pattern_unique)
    x_len =  len(pattern_unique)
    i = x_len - 1
    while i>0:
        diff_sum_pattern = len(input) - sum([x * y for x, y in zip(pattern_lengths, pattern_count)])
        if diff_sum_pattern >= 0:
            if diff_sum_pattern == 0 and \
               check_combination(pattern, input, pattern_unique, pattern_lengths):
                    return 1
            pattern_lengths[i] += max(1, diff_sum_pattern // pattern_count[i])
            pattern_lengths[i:x_len] = [1] * (x_len - i)
            pattern_lengths[i - 1] += 1
            sum_pattern = sum([x * y for x, y in zip(pattern_lengths, pattern_count)])
            if sum_pattern <= len(input):
                i = x_len - 1
                i -= 1
    return 0

task = ("abcdddcbaaabcdddcbaa","redbluegreenyellowyellowyellowgreenblueredredredbluegreenyellowyellowyellowgreenblueredred")

On the sample pattern from this code (20 chars, 4 unique) works 50000 times faster than plain bruteforce (DFS) with recursion (implementation by @EricM) ; 30 times faster than regular expression (implementation by @IknoweD).


Depending on what patterns are given, you can answer a 'different' question (that really is the same question).

For patterns like [a b b a] determine whether or not the string is a palindrome.

For patterns like [a b a b] determine if the second half of the string equals the first half of the string.

Longer patterns like [a b c b c a], but you still break it up into smaller problems to solve. For this one, you know that the last n characters of the string should be the reverse of the first n characters. Once they stop being equal, you simply have another [b c b c] problem to check for.

Although possible, in an interview, I doubt they'd give you anything more complex than maybe 3-4 different substrings.

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