04/6/20

Why and When You Need Transactional DDL in Your Database

We typically talk about transactions in the context of Data Manipulation Language (DML), but the same principles apply when we talk about Data Definition Language (DDL). As databases increasingly include transactional DDL, we should stop and think about the history of transactional DDL. Transactional DDL can help with application availability by allowing you perform multiple modifications in a single operation, making software upgrades simpler. You’re less likely to find yourself dealing with a partially upgraded system that requires your database administrator (DBA) to go in and fix everything by hand, losing hours of their time and slowing your software delivery down.

WHY DO YOU CARE?

If you make a change to application code and something doesn’t work, you don’t want to have to deal with a complicated recovery. You want the database to be able to roll it back automatically so you get back to a working state very rapidly. Today, very often people don’t write code for databases, they have frameworks that do it (Hibernate, for example). This makes it impossible for a software engineer to write the code properly, or roll it back, because they don’t work on that level. When you make changes using rolling application upgrades, it is simpler, less likely to fail, and more obvious what to do when you do experience a failure.

With transactional DDL, it’s far less likely that you will have to deal with a partially upgraded system that has essentially ground your application to a stop. Partial upgrades like that may require your database administrator (DBA) to go in and fix everything by hand, losing hours of their time and slowing your software delivery down. With transactional DDL, you can roll back to the last working upgrade and resolve the issues rapidly, without taking your software delivery system or your application offline.

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03/30/20

Top 10 FAQs from KubeCon 2019 in San Diego

WHAT DOES NUODB DO?

TL;DR: NuoDB is a distributed SQL database

NuoDB is a SQL database, it is fully transactional, fully ACID, and fully consistent. This is a stark contrast to NoSQL solutions that have emerged in the last decade.

NuoDB is distributed, meaning that it is able to scale horizontally and automatically keeps multiple replicas in sync. Having multiple replicas of a database is a strict requirement for any service having 99.99% or better availability guarantees.

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03/23/20

What Does Distributed SQL Really Mean?

The world is moving to the cloud and various post-monolithic SQL databases are emerging. The term “NewSQL” was coined by 451 Research analyst Matt Aslett in 2011, and in 2016 Aslett and Professor Andrew Pavlo of Carnegie Mellon University published a paper titled, “What’s Really New with NewSQL,” describing NewSQL as a new class of database management systems that “want to achieve the same scalability of NoSQL DBMSs from the 2000s, but still keep the relational model (with SQL) and transaction support of the legacy DBMSs from the 1970-80s.” NuoDB was founded in 2010 based on this idea, and has been an important player in the distributed relational database space since then. For a while, this concept was referred to as “scalable SQL,” and we’ve also seen reference to “elastic SQL.” More recently, we’ve seen a new term emerge: “distributed SQL.” 

Let me explain why all of these terms refer to essentially the same thing, although the ways that different databases achieve that scalability while maintaining consistency varies. As more and more companies started providing SaaS offerings that had no downtime, a pattern of pain points emerged:

  • A monolithic database cannot provide the resiliency and high availability guarantees required by modern always-up, always-available applications. 
  • Scaling up is no longer viable. Machines big enough to run these types of workloads become too expensive, too quickly.
  • NoSQL is not well suited for applications that require strong transactional and ACID guarantees.
  • Explicit sharding is too complex and diverts engineering resources from what matters most: the business.

We’ve seen technologies come and go, but the same four fundamental motivations that are aligned with the shift to the cloud remain unchanged. NuoDB has been here since the beginning, and we continue to help our customers alleviate these pains.

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05/23/19

HackerRank ‘Day Of The Programmer’ Solution

Short Problem Definition:

Marie invented a Time Machine and wants to test it by time-traveling to visit Russia on the Day of the Programmer (the 256th day of the year) during a year in the inclusive range from 1700 to 2700.

Link

Day of The Programmer

Complexity:

time complexity is O(-1)

space complexity is O(-1)

Execution:

As I have pointed out in the past, no engineer should ever implement any calendar related functions. It should be done natively by the language or by a library.

I am fairly certain that the conventions will change by 2700 🙂 and the calculation will be invalid.

Solution:
#!/bin/python

import math
import os
import random
import re
import sys

# Complete the dayOfProgrammer function below.
def dayOfProgrammer(year):
    raise SystemError("This challenge is stupid")

if __name__ == '__main__':
    fptr = open(os.environ['OUTPUT_PATH'], 'w')

    year = int(raw_input().strip())

    result = dayOfProgrammer(year)

    fptr.write(result + '\n')

    fptr.close()

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05/22/19

HackerRank ‘Migratory Birds’ Solution

Short Problem Definition:

You have been asked to help study the population of birds migrating across the continent. Each type of bird you are interested in will be identified by an integer value. Each time a particular kind of bird is spotted, its id number will be added to your array of sightings. You would like to be able to find out which type of bird is most common given a list of sightings. Your task is to print the type number of that bird and if two or more types of birds are equally common, choose the type with the smallest ID number.

Link

Migratory Birds

Complexity:

time complexity is O(N)

space complexity is O(1)

Execution:

I provide two solutions to this challenge. Solution #1 is using the Counter collection in python and works well.

The second solution is more explicit and takes advantage of the restrictive challenge specification.

Solution:
#!/bin/python

import math
import os
import random
import re
import sys
from collections import Counter

# Complete the migratoryBirds function below.
def migratoryBirds(arr):
    mc = Counter(arr)
    return mc.most_common(1)[0][0]

if __name__ == '__main__':
    fptr = open(os.environ['OUTPUT_PATH'], 'w')

    arr_count = int(raw_input().strip())

    arr = map(int, raw_input().rstrip().split())

    result = migratoryBirds(arr)

    fptr.write(str(result) + '\n')

    fptr.close()

# Complete the migratoryBirds function below.
def migratoryBirds(arr):
    frequencies = [0] * 6

    for ele in arr:
        frequencies[ele] += 1

    max_val = 0
    max_idx = 5
    
    for idx in xrange(5, 0, -1):
        if frequencies[idx] >= max_val:
            max_idx = idx
            max_val = frequencies[idx]

    return max_idx

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05/21/19

HackerRank ‘Birthday Chocolate’ Solution

Short Problem Definition:

The member states of the UN are planning to send 2 people to the moon. They want them to be from different countries. You will be given a list of pairs of astronaut ID’s. Each pair is made of astronauts from the same country. Determine how many pairs of astronauts from different countries they can choose from.

Link

Birthday Chocolate

Complexity:

time complexity is O(N)

space complexity is O(1)

Execution:

Keep track of Melements at a time. Basically a simplified prefix sum.

Solution:
#!/bin/python

import sys

def getWays(squares, d, m):
    cnt = 0
    q = squares[:m-1]
    for ele in squares[m-1:]:
        q.append(ele)
        if (sum(q) == d):
            cnt += 1
        q.pop(0)
    return cnt

n = int(raw_input().strip())
s = map(int, raw_input().strip().split(' '))
d,m = raw_input().strip().split(' ')
d,m = [int(d),int(m)]
result = getWays(s, d, m)
print(result)


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05/20/19

HackerRank ‘Left Rotation’ Solution

Short Problem Definition:

left rotation operation on an array shifts each of the array’s elements 1 unit to the left. For example, if 2 left rotations are performed on array [1,2,3,4,5], then the array would become [3,4,5,1,2].

Link

Arrays: Left Rotation

Complexity:

time complexity is O(N)

space complexity is O(N)

Execution:

Solutions like this is where python really shines. Simple and straight forward.

Solution:
#!/bin/python

import math
import os
import random
import re
import sys

# Complete the rotLeft function below.
def rotLeft(a, d):
    return a[d:] + a[:d]

if __name__ == '__main__':
    fptr = open(os.environ['OUTPUT_PATH'], 'w')

    nd = raw_input().split()

    n = int(nd[0])

    d = int(nd[1])

    a = map(int, raw_input().rstrip().split())

    result = rotLeft(a, d)

    fptr.write(' '.join(map(str, result)))
    fptr.write('\n')

    fptr.close()




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05/17/19

HackerRank ‘Breaking The Records’ Solution

Short Problem Definition:

Maria plays college basketball and wants to go pro. Each season she maintains a record of her play. She tabulates the number of times she breaks her season record for most points and least points in a game. Points scored in the first game establish her record for the season, and she begins counting from there.

Link

Breaking The Records

Complexity:

time complexity is O(N)

space complexity is O(1)

Execution:

Just track the min and max.

Solution:
#!/bin/python

import sys

def getRecord(s):
    min_ele = s[0]
    max_ele = s[0]
    min_cnt = 0
    max_cnt = 0
    
    for ele in s:
        if ele > max_ele:
            max_ele = ele
            max_cnt += 1
        if ele < min_ele:
            min_ele = ele
            min_cnt += 1
    
    return [max_cnt, min_cnt]
    
n = int(raw_input().strip())
s = map(int, raw_input().strip().split(' '))
result = getRecord(s)
print " ".join(map(str, result))


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05/16/19

HackerRank ‘Between Two Sets’ Solution

Short Problem Definition:

You will be given two arrays of integers and asked to determine all integers that satisfy the following two conditions:

  1. The elements of the first array are all factors of the integer being considered
  2. The integer being considered is a factor of all elements of the second array
Link

Between Two Sets

Complexity:

time complexity is O(A* (N+M))

space complexity is O(1)

Execution:

This challenge could also be solved using the Greatest Common Divisor. Given that the range of values is only [1,100], it is safe to assume that the naive solution will terminate within the time limit.

Solution:
#!/bin/python

import sys

def isValid(a, b, candidate):
    for a_ele in a:
        if candidate % a_ele != 0:
            return False
    for b_ele in b:
        if b_ele % candidate != 0:
            return False
    return True

n,m = raw_input().strip().split(' ')
n,m = [int(n),int(m)]
a = map(int,raw_input().strip().split(' '))
b = map(int,raw_input().strip().split(' '))

cnt = 0
for candidate in xrange(max(a), min(b)+1):
    if isValid(a, b, candidate):
        cnt += 1

print cnt


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05/15/19

HackerRank ‘Journey To The Moon’ Solution

Short Problem Definition:

The member states of the UN are planning to send 2 people to the moon. They want them to be from different countries. You will be given a list of pairs of astronaut ID’s. Each pair is made of astronauts from the same country. Determine how many pairs of astronauts from different countries they can choose from.

Link

Journey To The Moon

Complexity:

time complexity is O(a(N))

space complexity is O(N)

Execution:

The algorithm has two parts. Part one calculates the size of all countries with the use of Union-Find. Both operations on the data structure take O log-star time. The second part derives the number of all pairs based on country sizes. That algorithm is very similar to Handshakes.

I used the UF implementation from ActiveState. For more cool uses of Union-Find, see WireBurnouts.

Solution:
#!/bin/python

import math
import os
import random
import re
import sys
from collections import defaultdict

class UnionFind:
'''http://code.activestate.com/recipes/215912-union-find-data-structure/'''
    def __init__(self):
        self.num_weights = {}
        self.parent_pointers = {}
        self.num_to_objects = {}
        self.objects_to_num = {}
        self.__repr__ = self.__str__

    def insert_objects(self, objects):
        for object in objects:
            self.find(object);

    def find(self, object):
        if not object in self.objects_to_num:
            obj_num = len(self.objects_to_num)
            self.num_weights[obj_num] = 1
            self.objects_to_num[object] = obj_num
            self.num_to_objects[obj_num] = object
            self.parent_pointers[obj_num] = obj_num
            return object
        stk = [self.objects_to_num[object]]
        par = self.parent_pointers[stk[-1]]
        while par != stk[-1]:
            stk.append(par)
            par = self.parent_pointers[par]
        for i in stk:
            self.parent_pointers[i] = par
        return self.num_to_objects[par]

    def union(self, object1, object2):
        o1p = self.find(object1)
        o2p = self.find(object2)
        if o1p != o2p:
            on1 = self.objects_to_num[o1p]
            on2 = self.objects_to_num[o2p]
            w1 = self.num_weights[on1]
            w2 = self.num_weights[on2]
            if w1 < w2:
                o1p, o2p, on1, on2, w1, w2 = o2p, o1p, on2, on1, w2, w1
            self.num_weights[on1] = w1+w2
            del self.num_weights[on2]
            self.parent_pointers[on2] = on1

# Complete the journeyToMoon function below.
def journeyToMoon(n, astronauts):
    # generate disjoint sets
    uf = UnionFind()
    uf.insert_objects(xrange(n))

    for astronaut in astronauts:
        uf.union(astronaut[0], astronaut[1])

    # calculate sizes of countries
    country_sizes = defaultdict(int)
    for i in xrange(n):
        country_sizes[uf.find(i)] += 1

    # calculate number of viable pairs
    sm = 0
    result = 0
    for size in country_sizes.values():
        result += sm*size;
        sm += size; 

    return result

if __name__ == '__main__':
    fptr = open(os.environ['OUTPUT_PATH'], 'w')

    np = raw_input().split()

    n = int(np[0])

    p = int(np[1])

    astronaut = []

    for _ in xrange(p):
        astronaut.append(map(int, raw_input().rstrip().split()))

    result = journeyToMoon(n, astronaut)

    fptr.write(str(result) + '\n')

    fptr.close()


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