Wednesday, October 06, 2010
csharptrie project on Google Code
Added project csharptrie - a C# implementation of trie data structure to Google Code.
Monday, August 23, 2010
building tree view from given child-parent pairs in hashmap
Ex: The child-parent pairs are in a hashmap 'childParentMap' as shown below. The root node is with value 0.
1 -> 0
2 -> 1
3 -> 2
4 -> 2
5 -> 0
The tree node data structure has an int value and list of children tree nodes.
The code first traverses through the childParentMap hashmap to build the value->TreeNode hashmap 'valueNodeMap'. It traverses through it again to get child and parent values, their equivalent nodes and adds the child node to the parent node. The root node with value 0 is created separately (root of the tree).
Time is O(n).
There is a recursive solution too but it takes O(n^2) time.
The code is similar to building a graph from an adjacency list.
[H/T ai, as, sc, jf, se]
1 -> 0
2 -> 1
3 -> 2
4 -> 2
5 -> 0
The tree node data structure has an int value and list of children tree nodes.
class TreeNode:
int value
IList children
//constructor
TreeNode(int value):
this.value = value
children = new List()
The code first traverses through the childParentMap hashmap to build the value->TreeNode hashmap 'valueNodeMap'. It traverses through it again to get child and parent values, their equivalent nodes and adds the child node to the parent node. The root node with value 0 is created separately (root of the tree).
TreeNode createTreeView(Hashmap childParentMap):
// build value->TreeNode map
Hashmap valueNodeMap = new Hashmap()
foreach (KeyValuePair kvPair in childParentMap):
int value = kvPair.Key
TreeNode node = new TreeNode(value)
if !valueNodeMap.ContainsKey(value):
valueNodeMap.Add(value, node)
// add root value 0 and root node to valueNodeMap
int rootValue = 0;
TreeNode rootNode = new TreeNode(rootValue);
valueNodeMap.Add(rootValue, rootNode);
// for child and parent values, find equivalent nodes and
// add child node as child to parent node
foreach (KeyValuePair kvPair in childParentMap):
int childValue = kvPair.Key
int parentValue = kvPair.Value
TreeNode childNode = valueNodeMap[childValue]
TreeNode parentNode = valueNodeMap[parentValue]
parentNode.children.Add(childNode)
// return root
return rootNode
Time is O(n).
There is a recursive solution too but it takes O(n^2) time.
The code is similar to building a graph from an adjacency list.
[H/T ai, as, sc, jf, se]
Friday, August 06, 2010
bracket matching
Check for brackets matching - curly, square, round, {}[]() - and return boolean.
ex: return true for
{}
{[()]}
{()[]}
return false for
{
}
[Hat tip to BR]
ex: return true for
{}
{[()]}
{()[]}
return false for
{
}
bool bracketMatching(char[] str):
bool result = true
Stack stack = new Stack()
//close-open bracket map
Hashmap bracketMap = new Hashmap()
bracketMap.Add('}', '{')
bracketMap.Add(')', '(')
bracketMap.Add(']', '[')
foreach (char c in str):
if (c == '{' || c == '[' || c == '('):
stack.Push(c)
if (c == '}' || c == ']' || c == ')'):
if (stack.isEmpty result = false
break
//tos should be open bracket and c close bracket
char tos = stack.Pop()
if (tos != bracketMap[c]):
result = false
break
if (!stack.isEmpty()):
result = false
return result
[Hat tip to BR]
Friday, May 21, 2010
codejam 2010 qualifications
qualifications problems
A Snapper Chain
The snappers are same as incrementing binary bits. The overflow is discarded. ANDing K with 111...N bits gives the state of the snappers after K snaps. The count of 1 bits of that number if same as N means the state is ON else OFF.
B Fair Warning
I used this IntX code for 64+ bits data structure. The trick is to subtract the min of the array and find their gcd - which gives Tmax. ymin is calculated then. One way is to sort the array and find the gcd from index 1...N. Another way is to find the min and put checks for 0 in gcd function.
C Theme Park
Limits
1 <= T <= 50
gi <= k
Small dataset
1 <= R <= 1000
1 <= k <= 100
1 <= N <= 10
1 <= gi <= 10
Large dataset
1 <= R <= 10^8
1 <= k <= 10^9
1 <= N <= 1000
1 <= gi <= 10^7
My first solution was of O(R*N) time i.e. 10^8 * 10^3 which does not work for large dataset. The trick is to first calculate and cache the sums and save the next group position which takes O(N*N) time i.e. 10^6 and then add the sums in O(R) time i.e. 10^8 - the sum is calculated for each position i of N in cache[] and the next group index in nextCacheIndex[].
[codejam]
A Snapper Chain
The snappers are same as incrementing binary bits. The overflow is discarded. ANDing K with 111...N bits gives the state of the snappers after K snaps. The count of 1 bits of that number if same as N means the state is ON else OFF.
string snapperChain(int n, int k)
int nbit = (int) Math.Pow(2, n) - 1;
int result = nbit & k;
int count1 = count1bits(result);
if (count1 == n)
return "ON";
else
return "OFF";
int count1bits(int num)
int n = num;
int count = 0;
while (n != 0)
n = n & (n - 1);
count++;
return count;
B Fair Warning
I used this IntX code for 64+ bits data structure. The trick is to subtract the min of the array and find their gcd - which gives Tmax. ymin is calculated then. One way is to sort the array and find the gcd from index 1...N. Another way is to find the min and put checks for 0 in gcd function.
string fairWarning(IntX[] input)
IntX Tmax = -1;
IntX ymin = -1;
//Array.Sort(input);
IntX min = minf(input);
for (int i = 0; i < input.Length; i++)
input[i] = input[i] - min;
Tmax = gcdf(input);
if (Tmax == 0 || (min % Tmax) == 0)
ymin = 0;
else
ymin = Tmax - (min % Tmax);
return ymin.ToString()
//min of array
IntX minf(IntX[] input)
IntX min = input[0];
for (int i = 0; i < input.Length; i++)
if (input[i] < min)
min = input[i];
return min;
//gcd of array
IntX gcdf(IntX[] input)
IntX a = input[0];
for (int i = 1; i < input.Length; i++)
IntX b = input[i];
if (i < input.Length-1 && a == 0)
i++;
a = input[i];
if (i < input.Length-1 && b == 0)
i++;
b = input[i];
a = gcdf(a, b);
return a;
//gcd of a, b
IntX gcdf(IntX a, IntX b)
if (a == 0 && b == 0)
throw new ArgumentException();
while (b != 0)
IntX t = a % b;
a = b;
b = t;
return a;
C Theme Park
Limits
1 <= T <= 50
gi <= k
Small dataset
1 <= R <= 1000
1 <= k <= 100
1 <= N <= 10
1 <= gi <= 10
Large dataset
1 <= R <= 10^8
1 <= k <= 10^9
1 <= N <= 1000
1 <= gi <= 10^7
My first solution was of O(R*N) time i.e. 10^8 * 10^3 which does not work for large dataset. The trick is to first calculate and cache the sums and save the next group position which takes O(N*N) time i.e. 10^6 and then add the sums in O(R) time i.e. 10^8 - the sum is calculated for each position i of N in cache[] and the next group index in nextCacheIndex[].
Int64 themePark(Int64 R, Int64 k, Int64[] q)
Int64 totalMoney = 0;
Int64 groups = q.Length;
Int64[] cache = new Int64[q.Length];
Int64[] nextCacheIndex = new Int64[q.Length];
for (Int64 i = 0; i < groups; i++)
Int64 sum = 0;
Int64 nextIndex = i;
Int64 groupCount = 0;
//while sum <= k and not at the end of the *current* queue
while ((sum + q[nextIndex] <= k) && (groupCount < groups))
sum += q[nextIndex];
nextIndex = (nextIndex + 1) % groups;
groupCount++;
cache[i] = sum;
nextCacheIndex[i] = nextIndex;
Int64 index = 0;
for (Int64 r = 0; r < R; r++)
totalMoney += cache[index];
index = nextCacheIndex[index];
return totalMoney;
[codejam]
Friday, May 14, 2010
permutations and combinations of string - derivative
This is a derivative of permutations of a string. For digits [1, 2, 3], we want [1, 12, 21, 123, 132, 213, 231, 312, 321]. The permute_wrapper loops through the input array to permute the sub-array with limit marking its end.
For combinations of digits, instead of using a string buffer for output, an int array is used. index is used to keep track of where to insert the digit. The number is between index and 0 of output array.
def permute_wrapper(digits):
input = [i for i in range(1, digits+1)]
print(input)
output = [0 for x in range(len(input))]
flags = [False for x in range(len(input))]
depth = 0
for i in range(len(input)):
permute_(input, i+1, output, flags, depth, nums)
return nums
def permute_(input, limit, output, flags, depth, nums):
if depth == limit:
num = 0
factor = 1
for i in range(limit, 0, -1):
num = num + output[i - 1] * factor
factor *= 10
nums.append(num)
return None
for i in range(limit):
if flags[i] == True:
continue
flags[i] = True
output[depth] = input[i]
permute_(input, limit, output, flags, depth + 1, nums)
flags[i] = False
For combinations of digits, instead of using a string buffer for output, an int array is used. index is used to keep track of where to insert the digit. The number is between index and 0 of output array.
def combine_wrapper(digits):
input = [i for i in range(1, digits+1)]
print(input)
output = [0 for x in range(len(input))]
start = 0
index = 0
combine_(input, output, start, index, nums)
return nums
def combine_(input, output, start, index, nums):
if start == len(input):
return None
for i in range(start, len(input), 1):
output[index] = input[i]
num = 0
factor = 1
for x in range(index, -1, -1):
num = num + output[x] * factor
factor *= 10
nums.append(num)
index+=1
combine_(input, output, i + 1, index, nums)
index-=1
Wednesday, May 12, 2010
nine-digit polydivisible number with 1 to 9 exactly once: 381654729
Arrange the digits 1 to 9 in order so that the first two digits form a multiple of 2, the first three digits form a multiple of 3, the first four digits form a multiple of 4 etc. and finally the entire number is a multiple of 9. It contains the digits 1 to 9 exactly once each. [Polydivisible number]
There are 9^9 9-digit numbers; 9^9 = 387420489. There are only 9! numbers with 1-9 appearing only once; 9! = 362880 (1000 times smaller set). So, the trick is to find those 9! first (using permutations or otherwise) and then check for polydivisiblity. 381654729 is the only number.
[Hat tip to JF]
There are 9^9 9-digit numbers; 9^9 = 387420489. There are only 9! numbers with 1-9 appearing only once; 9! = 362880 (1000 times smaller set). So, the trick is to find those 9! first (using permutations or otherwise) and then check for polydivisiblity. 381654729 is the only number.
#checks if a number is polydivisible
#polydivCheck(381654729)
def polydivCheck(n, digts):
for i in range(digts, 0, -1):
if (n % i != 0):
return False
n = int(n / 10)
return True
#finds permutation for array 'input' and puts the numbers in list 'nums'
def permute(digits, input, output, flags, depth, nums):
if depth == len(input):
num = 0
factor = 1
for i in range(digits, 0, -1):
num = num + output[i - 1] * factor
factor *= 10
nums.append(num)
for i in range(len(input)):
if flags[i] == True:
continue
flags[i] = True
output[depth] = input[i]
permute(digits, input, output, flags, depth + 1, nums)
flags[i] = False
#wrapper function to call the recursive 'permute' function
def permute_wrapper(digits):
input = [i for i in range(1, digits+1)]
output = [0 for x in range(len(input))]
flags = [False for x in range(len(input))]
depth = 0
nums = []
permute(digits, input, output, flags, depth, nums);
return nums
#calls 'permute_wrapper' and for each number checks for polydivisibility
def getPolydivNums(digits):
nums = permute_wrapper(digits)
numbers=[]
for num in nums:
if polydivCheck(num, digits):
numbers.append(num)
return numbers
#start(9)
def start(digits):
nums = getPolydivNums(digits)
for n in nums:
print(n)
[Hat tip to JF]
Sunday, September 27, 2009
print all word combinations from phone number
Print all words combinations from phone number.
ex: 111-1111 -> AAA-AAAA, AAA-AAAB ... CCC-CCCC
char charkeyMap(int digit, int position)
ex:
charkeyMap(1, 0) = 'A'
charkeyMap(1, 1) = 'B'
charkeyMap(1, 2) = 'C'
ex: 111-1111 -> AAA-AAAA, AAA-AAAB ... CCC-CCCC
char charkeyMap(int digit, int position)
ex:
charkeyMap(1, 0) = 'A'
charkeyMap(1, 1) = 'B'
charkeyMap(1, 2) = 'C'
void printCombinations(int[] in):
char[] out = new char[in.length]
//first combination ex: 111-1111 -> AAA-AAAA
for(int i = in.length -1; i >= 0; i--):
out[i] = charkeyMap(in[i], 0)
int i
while (true):
out.print()
i = in.length - 1;
while (true):
//if A then B
if out[i] == charkeyMap(in[i], 0):
out[i] = charkeyMap(in[i], 1)
break
//if B then C
if out[i] == charkeyMap(in[i], 1):
out[i] = charkeyMap(in[i], 2)
break
//if C then A and let it loop for the adjacent digit
if out[i] == charkeyMap(in[i], 2):
out[i] = charkeyMap(in[i], 0)
//let it loop
i--
if i < 0 break
if i < 0 break
Saturday, September 26, 2009
fix duplicates in sorted array
12233344445 -> 12345
[Hat tip to MG]
//using 3 pointers
fixDuplicatesInSortedArray(Integer[] a):
start = 0
end = 0
destination = 0
while(start < a.length):
while(end < a.length && a[end] == a[start]):
end++
end--
//copy the distinct element
a[destination] = a[start]
destination++
start = end + 1
end = start
//null out the rest
while destination < a.length:
a[destination] = null
return
//using 2 pointers
fixDuplicatesInSortedArray(Integer[] a):
prev = 0
curr = 1
while curr < a.length():
while curr < a.length && a[curr] == c[prev]:
curr++
if curr == a.length() break
prev++
a[prev] = a[curr]
curr++
//null out the rest
prev++
while prev < a.length:
a[prev] = null
return
[Hat tip to MG]
Wednesday, September 16, 2009
Sunday, July 26, 2009
induction too
My lame attempt at this.
[Hats off to xkcd - images from Fetishes, No Pun Intended, Voynich Manuscript, Designated Drivers]
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