#include <functional> bool Or(bool a, bool b){ return std::logical_or<>()(a, b); } bool Xor(bool a, bool b){ return std::not_equal_to<>()(a, b); } bool And(bool a, bool b){ return std::logical_and<>()(a, b); }1 + #include <functional> 2 + 1 1 bool Or(bool a, bool b){ 2 - if(!a){ 3 - if(!b){ 4 - return false; 5 - } 6 - } 7 - return true; 4 + return std::logical_or<>()(a, b); 8 8 } 9 9 10 10 bool Xor(bool a, bool b){ 11 - return a != b; 8 + return std::not_equal_to<>()(a, b); 12 12 } 13 13 14 14 bool And(bool a, bool b){ 15 - if(a){ 16 - if(b){ 17 - return true; 18 - } 19 - } 20 - return false; 12 + return std::logical_and<>()(a, b); 21 21 }
Puzzles
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Mathematics
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Recursion
Computability Theory
Theoretical Computer Science
The Ulam Sequence is a recursive sequence that begins with two numbers; for example [1, 2]. The next number in the sequence is the smallest unique sum of any 2 numbers in the sequence.
Example:
[u0, u1] = [1, 2]
u2 = 1 + 2 = 3 --> [1, 2, 3]
u3 = 1 + 3 = 4 --> [1, 2, 3, 4]
u4 = 4 + 2 = 6 --> [1, 2, 3, 4, 6]
Notice that 5 is left out. Though 5 is smaller than 6, 5 can be written as a sum in 2 different ways: 4 + 1 and 3 + 2; therefore, it is not unique; whereas, 6 is unique since it is only the sum of 4 + 2.
Write a code that generates an Ulam Sequence of length n and starts with u0, u1.
Ex:
f(u0=1, u1=2, n=10) = [1, 2, 3, 4, 6, 8, 11, 13, 16, 18]
def ulam_sequence(u0, u1, n):
u = [u0, u1]
nn = u[-1] + 1
while len(u) < n:
count = 0
for i in u:
if nn - i in u and nn - i != i:
count += 1
if count >= 3:
break
nn += 1
if count == 2:
u.append(nn)
nn += 1
return utest.assert_equals(ulam_sequence(3, 4, 5), [3, 4, 7, 10, 11])
test.assert_equals(ulam_sequence(1, 2, 10), [1, 2, 3, 4, 6, 8, 11, 13, 16, 18])
test.assert_equals(ulam_sequence(2, 3, 8), [2, 3, 5, 7, 8, 9, 13, 14])Numbers
Integers
Algorithms
using System; using System.Linq; public class Kumite { public static int Digits(ulong n) { //GEEEEEEET DUUUUUUNKED OOOOOOOOOOOOOON int theseDigitsShouldREALLYBeCountedImSureOfIt = n .ToString() .ToCharArray() .Select((c,i)=>new{_char = c, ShouldBeCounted = true, index = i}) .Select((a,i)=>new{charValue = a._char-'0', shouldREALLYbecounted = a.ShouldBeCounted && a.index==i}) .OrderBy(a=>a.charValue) .ToArray() .Where(a=>a.shouldREALLYbecounted.ToString()=="True") .ToList() .ToArray() .Length; int thatNameWasTooLong = theseDigitsShouldREALLYBeCountedImSureOfIt; int soWasThatOne = thatNameWasTooLong; int betterstill = soWasThatOne; int thisone = betterstill; int _this = thisone; int _ = _this; return _; } }1 + using System; 2 + using System.Linq; 3 + 1 1 public class Kumite 2 2 { 3 - // Unrolled div loop 4 - public static int Digits(ulong n) => n.ToString().Length; 6 + public static int Digits(ulong n) 7 + { 8 + //GEEEEEEET DUUUUUUNKED OOOOOOOOOOOOOON 9 + int theseDigitsShouldREALLYBeCountedImSureOfIt = n 10 + .ToString() 11 + .ToCharArray() 12 + .Select((c,i)=>new{_char = c, ShouldBeCounted = true, index = i}) 13 + .Select((a,i)=>new{charValue = a._char-'0', shouldREALLYbecounted = a.ShouldBeCounted && a.index==i}) 14 + .OrderBy(a=>a.charValue) 15 + .ToArray() 16 + .Where(a=>a.shouldREALLYbecounted.ToString()=="True") 17 + .ToList() 18 + .ToArray() 19 + .Length; 20 + 21 + 22 + int thatNameWasTooLong = theseDigitsShouldREALLYBeCountedImSureOfIt; 23 + int soWasThatOne = thatNameWasTooLong; 24 + int betterstill = soWasThatOne; 25 + int thisone = betterstill; 26 + int _this = thisone; 27 + int _ = _this; 28 + return _; 29 + } 5 5 }
Arrays
const func = (N, p) => Array(N).fill().map((_,i)=>Math.abs(i-p));1 - function func(N, point) { 2 - let start = 0; // starting position of array 3 - let clonePoint = point; // clone for point to start counting from that number at begining of array 4 - let arr = [...Array(N).keys()] // generate array and fill with 0 to 10 5 - if(!(point > N)) { 6 - arr.forEach((o, index) => { 7 - index < point ? arr[index] = clonePoint-- : arr[index] = start++; 8 - }); 9 - return arr; 10 - } 11 - return []; 12 - } 1 + const func = (N, p) => Array(N).fill().map((_,i)=>Math.abs(i-p));
Mathematics
Algorithms
Numbers
PEP 8 - Naming Conventions - Function Names:
Function names should be lowercase, with words separated by underscores as necessary to improve readability.
This naming style is commonly known as snake_case.
Furthermore, the variable assignment in the previous Kumite is not required; the computed result can be returned immediately.
Finally, as per the Python Test Reference in the official Codewars Docs, the order of arguments for Test.assert_equals should be actual, expected instead of the other way round.
from itertools import permutations def sequence_permutation(t, n): return list(permutations(t, n))1 1 from itertools import permutations 2 - 3 - def SequencePermutation(plenty, count): 4 - ret = list(permutations(plenty, count)) 5 - return ret 6 - 7 - 2 + def sequence_permutation(t, n): 3 + return list(permutations(t, n))
Test.describe("sequence_permutation") Test.it("should correct calculate for permutations with three by three") sq_per_master = sequence_permutation(('a','b','c'), 3) Test.assert_equals(list(sq_per_master[0]), ['a', 'b', 'c']) Test.assert_equals(list(sq_per_master[1]), ['a', 'c', 'b']) Test.assert_equals(list(sq_per_master[4]), ['c', 'a', 'b']) Test.it("should correct calculate for permutations with one item") sq_per_master = sequence_permutation(('a','b','c'), 1) Test.assert_equals(list(sq_per_master[0]), ['a']) Test.assert_equals(list(sq_per_master[1]), ['b']) Test.assert_equals(list(sq_per_master[2]), ['c']) Test.it("should correct calculate for permutations with two items") sq_per_master = sequence_permutation(('a','b','c'), 2) Test.assert_equals(list(sq_per_master[0]), ['a', 'b']) Test.assert_equals(list(sq_per_master[1]), ['a', 'c']) Test.assert_equals(list(sq_per_master[4]), ['c', 'a'])1 - Test.describe("SequencePermutation") 1 + Test.describe("sequence_permutation") 2 2 3 + Test.it("should correct calculate for permutations with three by three") 4 + sq_per_master = sequence_permutation(('a','b','c'), 3) 5 + Test.assert_equals(list(sq_per_master[0]), ['a', 'b', 'c']) 6 + Test.assert_equals(list(sq_per_master[1]), ['a', 'c', 'b']) 7 + Test.assert_equals(list(sq_per_master[4]), ['c', 'a', 'b']) 3 3 4 - Test.describe("should correct calculate for permutations with three by three") 5 - sq_per_master = SequencePermutation(('a','b','c'), 3) 6 - Test.assert_equals(['a', 'b', 'c'], list(sq_per_master[0])) 7 - Test.assert_equals(['a', 'c', 'b'], list(sq_per_master[1])) 8 - Test.assert_equals(['c', 'a', 'b'], list(sq_per_master[4])) 9 + Test.it("should correct calculate for permutations with one item") 10 + sq_per_master = sequence_permutation(('a','b','c'), 1) 11 + Test.assert_equals(list(sq_per_master[0]), ['a']) 12 + Test.assert_equals(list(sq_per_master[1]), ['b']) 13 + Test.assert_equals(list(sq_per_master[2]), ['c']) 9 9 10 - Test.describe("should correct calculate for permutations with one item") 11 - sq_per_master = SequencePermutation(('a','b','c'), 1) 12 - Test.assert_equals(['a'], list(sq_per_master[0])) 13 - Test.assert_equals(['b'], list(sq_per_master[1])) 14 - Test.assert_equals(['c'], list(sq_per_master[2])) 15 - 16 - Test.describe("should correct calculate for permutations with two items") 17 - sq_per_master = SequencePermutation(('a','b','c'), 2) 18 - Test.assert_equals(['a', 'b'], list(sq_per_master[0])) 19 - Test.assert_equals(['a', 'c'], list(sq_per_master[1])) 20 - Test.assert_equals(['c', 'a'], list(sq_per_master[4])) 15 + Test.it("should correct calculate for permutations with two items") 16 + sq_per_master = sequence_permutation(('a','b','c'), 2) 17 + Test.assert_equals(list(sq_per_master[0]), ['a', 'b']) 18 + Test.assert_equals(list(sq_per_master[1]), ['a', 'c']) 19 + Test.assert_equals(list(sq_per_master[4]), ['c', 'a'])
A simple algorithm in Brainf**k that receives exactly 1 byte of input and prints it out as a numerical string. For example: "H" -> "72". Note that this algorithm only works for byte values up to 99 though - it won't handle three-digit bytes properly.
This program might be somewhat useful in writing a short and concise program that prints out the lyrics to "99 bottles of beer" since the lyrics are highly repetitive and involves printing out a lot of numbers in descending order. However, upon second thought, it might not be that useful at all since my program fails to preserve its input :p
,[->>+>+>>-<<----------[[+]>>+<<]>>[[+]<<<----------<+>>>>]<<<[->+>+<<]>>[-<<+>>]<<<<]>[++++++++++++++++++++++++++++++++++++++++++++++++.[-]]>++++++++++++++++++++++++++++++++++++++++++++++++.Test.describe('The Program', function () {
Test.it('should correctly convert byte(72) into string "72"', function () {
Test.assertEquals(runBF('H'), '72');
});
Test.it('should work correctly for a few other examples below byte(100)', function () {
Test.assertEquals(runBF('c'), '99');
Test.assertEquals(runBF('a'), '97');
Test.assertEquals(runBF('F'), '70');
Test.assertEquals(runBF('!'), '33');
Test.assertEquals(runBF(String.fromCharCode(50)), '50');
Test.assertEquals(runBF("\0"), '0');
Test.assertEquals(runBF('0'), '48');
Test.assertEquals(runBF('7'), '55');
Test.assertEquals(runBF('A'), '65');
});
Test.it('unfortunately doesn\'t work properly above byte(99) :(', function () {
console.log('Output for byte(127): ' + runBF(String.fromCharCode(127)));
});
});Hello World in Julia, since there's nothing on codewars ⊙﹏⊙.
println("Hello Julia!")
const hello = "world"facts("Is hello world?") do
@fact hello => "world"
endHello Brainf**k with "default arguments"
The last two BF programs I published would simply print a weirdly formatted string if the input is empty (or not provided), like so: "Hello "/"Hello !". Obviously, that isn't desirable behavior so I refactored my program to print "Hello World!" in case of empty input.
++++++++++[>+++++++>++++++++++>+++++++++++>+++<<<<-]>++.>+.>--..+++.>++.>->,[.<[+]>,]<[[+]++++++++++[>+++++++++>+++++++++++>++++++++++<<<-]>---.>+.+++.------.>.<<<]<+.1 - ++++++++++[>+++++++>++++++++++>+++++++++++>+++<<<<-]>++.>+.>--..+++.>++.>,[.,]<+. 1 + ++++++++++[>+++++++>++++++++++>+++++++++++>+++<<<<-]>++.>+.>--..+++.>++.>->,[.<[+]>,]<[[+]++++++++++[>+++++++++>+++++++++++>++++++++++<<<-]>---.>+.+++.------.>.<<<]<+.
Test.describe('The BF greeting program (with input)', function () { Test.it('should work with input "Brainf**k"', function () { Test.assertEquals(runBF('Brainf**k' + EOF), 'Hello Brainf**k!'); }); Test.it('should work with a range of other inputs', function () { Test.assertEquals(runBF('JavaScript' + EOF), 'Hello JavaScript!'); Test.assertEquals(runBF('Node 8' + EOF), 'Hello Node 8!'); Test.assertEquals(runBF('Codewars' + EOF), 'Hello Codewars!'); Test.assertEquals(runBF('@jhoffner' + EOF), 'Hello @jhoffner!'); Test.assertEquals(runBF('@donaldsebleung' + EOF), 'Hello @donaldsebleung!'); }); Test.it('should have a "default argument" of "World"', function () { Test.assertEquals(runBF(EOF), 'Hello World!'); }); Test.it('should work properly if "World" is passed in anyway', function () { Test.assertEquals(runBF('World' + EOF), 'Hello World!'); }); });... lines 1 to 5 have been collapsed. expand 1 1 Test.describe('The BF greeting program (with input)', function () { 2 2 Test.it('should work with input "Brainf**k"', function () { 3 3 Test.assertEquals(runBF('Brainf**k' + EOF), 'Hello Brainf**k!'); 4 4 }); 5 5 Test.it('should work with a range of other inputs', function () { 6 6 Test.assertEquals(runBF('JavaScript' + EOF), 'Hello JavaScript!'); 7 7 Test.assertEquals(runBF('Node 8' + EOF), 'Hello Node 8!'); 8 8 Test.assertEquals(runBF('Codewars' + EOF), 'Hello Codewars!'); 9 9 Test.assertEquals(runBF('@jhoffner' + EOF), 'Hello @jhoffner!'); 10 10 Test.assertEquals(runBF('@donaldsebleung' + EOF), 'Hello @donaldsebleung!'); 11 11 }); 12 + Test.it('should have a "default argument" of "World"', function () { 13 + Test.assertEquals(runBF(EOF), 'Hello World!'); 14 + }); 15 + Test.it('should work properly if "World" is passed in anyway', function () { 16 + Test.assertEquals(runBF('World' + EOF), 'Hello World!'); 17 + }); 12 12 });
use Math;
proc chebyshev(n: int, v: real) : real
{
if (v > 1) {
return cosh(n * acosh(v));
} else if (v < -1) {
return (-1) ** n * cosh(n * acosh(-v));
} else {
return cos(n * acos(v));
}
}Test.describe("First Order Chebyshev Polynomials");
Test.assertFuzzyEquals(chebyshev(0,0.5), 1);
Test.assertFuzzyEquals(chebyshev(1,0.5), 0.5);
Test.assertFuzzyEquals(chebyshev(2,0.5), -0.5);
Test.assertFuzzyEquals(chebyshev(5,0.52), 0.396166451);
Test.assertFuzzyEquals(chebyshev(3,26), 70226.0);const package = require('fs').readFileSync('../../runner/package.json','utf8'); console.log(package);1 - const exec = require('child_process').exec; 1 + const package = require('fs').readFileSync('../../runner/package.json','utf8'); 2 2 3 - function parse(error, stdout, stderr) { 4 - if (error) throw error; 5 - console.log(`stdout: ${stdout}`); 6 - console.log(`stderr: ${stderr}`); 7 - } 8 - 9 - // gives an error I don't understand but I guess the below command sort of works. 10 - // exec('npm -g list', (err, stdout, stderr) => parse(err, stdout, stderr)); 11 - 12 - exec('ls ../../runner/node_modules', (err, stdout, stderr) => parse(err, stdout, stderr)); 3 + console.log(package);
Puzzles
Games
Mathematics
Algorithms
Numbers
Sequences
Arrays
Naive, brute force solution
function Generate_Kolakoski_Seq(seed, n){ seed = seed.join(""); let seq = seed[0].repeat(seed[0]), tptr = 0, sptr = 0; while(seq.length < n) { sptr++; tptr = ++tptr % seed.length; seq += seed[tptr].repeat(seq[sptr] || seed[sptr]); } return seq.substring(0, n).split("").join(","); } function Find_Kolakoski_Number(seed, n){ // Ehh, I'll leave the thinking up to someone else. return +Generate_Kolakoski_Seq(seed, n)[(n-1) * 2]; }1 - // takes int[] and int, returns string (comma seperated integers) 2 2 function Generate_Kolakoski_Seq(seed, n){ 3 - 2 + seed = seed.join(""); 3 + let seq = seed[0].repeat(seed[0]), tptr = 0, sptr = 0; 4 + while(seq.length < n) { 5 + sptr++; tptr = ++tptr % seed.length; 6 + seq += seed[tptr].repeat(seq[sptr] || seed[sptr]); 7 + } 8 + return seq.substring(0, n).split("").join(","); 4 4 } 5 5 6 - 7 - // takes int[] and int, returns int 8 - function Find_Kolaskoski_Number(seed, n){ 9 - 11 + function Find_Kolakoski_Number(seed, n){ 12 + // Ehh, I'll leave the thinking up to someone else. 13 + return +Generate_Kolakoski_Seq(seed, n)[(n-1) * 2]; 10 10 }
Test.assertEquals(Generate_Kolakoski_Seq([1, 2], 10), "1,2,2,1,1,2,1,2,2,1"); Test.assertEquals(Generate_Kolakoski_Seq([2], 5), "2,2,2,2,2"); Test.assertEquals(Generate_Kolakoski_Seq([1, 2, 3], 20), "1,2,2,3,3,1,1,1,2,2,2,3,1,2,3,3,1,1,2,2"); Test.assertEquals(Find_Kolakoski_Number([1, 2], 10000), 1); Test.assertEquals(Find_Kolakoski_Number([2, 1, 3, 1], 97), 3);1 + Test.assertEquals(Generate_Kolakoski_Seq([1, 2], 10), "1,2,2,1,1,2,1,2,2,1"); 2 + Test.assertEquals(Generate_Kolakoski_Seq([2], 5), "2,2,2,2,2"); 3 + Test.assertEquals(Generate_Kolakoski_Seq([1, 2, 3], 20), "1,2,2,3,3,1,1,1,2,2,2,3,1,2,3,3,1,1,2,2"); 1 1 5 + Test.assertEquals(Find_Kolakoski_Number([1, 2], 10000), 1); 6 + Test.assertEquals(Find_Kolakoski_Number([2, 1, 3, 1], 97), 3);
def parse(expr): class State: current = expr[0] tokens = [] def exp(): result = term() while State.current in ('+', '-'): if State.current == '+': next_token() result += term() if State.current == '-': next_token() result -= term() return result def factor(): result = None if State.current[0].isdigit() or State.current[-1].isdigit(): result = float(State.current) next_token() elif State.current is '(': next_token() result = exp() next_token() return result def next_token(): State.tokens = State.tokens[1:] State.current = State.tokens[0] if len(State.tokens) > 0 else None def term(): result = factor() while State.current in ('*', '/'): if State.current == '*': next_token() result *= term() if State.current == '/': next_token() result /= term() return result for i in range(len(expr)): if expr[i].isdigit() and i > 0 and (State.tokens[-1].isdigit() or State.tokens[-1][-1] is '.'): State.tokens[-1] += expr[i] elif expr[i] is '.' and i > 0 and State.tokens[-1].isdigit(): State.tokens[-1] += expr[i] else: State.tokens.append(expr[i]) return exp()1 - def parse(expr): #The main parser 2 - ps = 0 #Number of open parentheses 3 - cval = 0 #Current value 4 - op = "+" #Current operation 5 - accum = "" #Accumulating value 6 - for i in range(len(expr)): 7 - c = expr[i] 8 - if c in ["+","-"] and not ps: #Operation not inside parens 9 - if op=="+": #Addition 10 - cval+=parse_fact(accum) 11 - else: #Subtraction 12 - cval-=parse_fact(accum) 13 - accum = "" #Reset the value 14 - op = c #New operation once that was calculated 15 - else: 16 - if c=="(": ps+=1 #Open paren 17 - if c==")": ps-=1 #Close paren 18 - accum+=c #Add a character to accumulating value 19 - if op=="+": #Do the operation one more time 20 - cval+=parse_fact(accum) 21 - else: 22 - cval-=parse_fact(accum) 23 - return cval 24 - def parse_fact(term): 25 - ps = 0 26 - cval = 1 27 - op = "*" 28 - accum = "" 29 - for i in range(len(term)): 30 - c = term[i] 31 - if c in ["*","/"] and not ps: 32 - if op=="*": 33 - cval*=parse_val(accum) 34 - else: 35 - cval/=parse_val(accum) 36 - accum = "" 37 - op = c 38 - else: 39 - if c=="(": ps+=1 40 - if c==")": ps-=1 41 - accum+=c 42 - if op=="*": 43 - cval*=parse_val(accum) 44 - else: 45 - cval/=parse_val(accum) 46 - return cval 47 - def parse_val(val): 48 - if val[0] == "(": #Parenthetical expression 49 - return parse(val[1:-1]) #Cut off parentheses and reevaluate 50 - else: 51 - return float(val) #Not parenthetical 1 + def parse(expr): 2 + 3 + class State: 4 + current = expr[0] 5 + tokens = [] 6 + 7 + def exp(): 8 + result = term() 9 + while State.current in ('+', '-'): 10 + if State.current == '+': 11 + next_token() 12 + result += term() 13 + if State.current == '-': 14 + next_token() 15 + result -= term() 16 + return result 17 + 18 + def factor(): 19 + result = None 20 + if State.current[0].isdigit() or State.current[-1].isdigit(): 21 + result = float(State.current) 22 + next_token() 23 + elif State.current is '(': 24 + next_token() 25 + result = exp() 26 + next_token() 27 + return result 28 + 29 + def next_token(): 30 + State.tokens = State.tokens[1:] 31 + State.current = State.tokens[0] if len(State.tokens) > 0 else None 32 + 33 + def term(): 34 + result = factor() 35 + while State.current in ('*', '/'): 36 + if State.current == '*': 37 + next_token() 38 + result *= term() 39 + if State.current == '/': 40 + next_token() 41 + result /= term() 42 + return result 43 + 44 + for i in range(len(expr)): 45 + if expr[i].isdigit() and i > 0 and (State.tokens[-1].isdigit() or State.tokens[-1][-1] is '.'): 46 + State.tokens[-1] += expr[i] 47 + elif expr[i] is '.' and i > 0 and State.tokens[-1].isdigit(): 48 + State.tokens[-1] += expr[i] 49 + else: 50 + State.tokens.append(expr[i]) 51 + 52 + return exp()
Game of Life :
The Game of Life, also known simply as Life, is a cellular automaton devised by the British mathematician John Horton Conway in 1970.
Your task is to write a program to calculate the next generation of Conway's game of life, given any starting position.
You start with a two dimensional grid of cells, where each cell is either alive or dead.
The grid is finite, and no life can exist off the edges.
When calculating the next generation of the grid, follow these four rules:
- Any live cell with fewer than two live neighbours dies, as if caused by underpopulation.
- Any live cell with more than three live neighbours dies, as if by overcrowding.
- Any live cell with two or three live neighbours lives on to the next generation.
- Any dead cell with exactly three live neighbours becomes a live cell.
Examples: * indicates live cell, . indicates dead cell
Example input: (4 x 8 grid)
........
....*...
...**...
........
Example output:
........
...**...
...**...
........
function nextGeneration(grid) {
return grid.map((row, rowIndex) => {
return row.map((cell, colIndex) => {
if (rowIndex !== 0 && colIndex !== 0 && rowIndex < grid.length - 1 && colIndex < row.length - 1) {
let neighboursCount = 0;
if (grid[rowIndex][colIndex + 1] === 1) neighboursCount++;
if (grid[rowIndex][colIndex - 1] === 1) neighboursCount++;
if (grid[rowIndex + 1][colIndex] === 1) neighboursCount++;
if (grid[rowIndex - 1][colIndex] === 1) neighboursCount++;
if (grid[rowIndex + 1][colIndex + 1] === 1) neighboursCount++;
if (grid[rowIndex + 1][colIndex - 1] === 1) neighboursCount++;
if (grid[rowIndex - 1][colIndex + 1] === 1) neighboursCount++;
if (grid[rowIndex - 1][colIndex - 1] === 1) neighboursCount++;
if (cell === 1) {
if (neighboursCount === 2 || neighboursCount === 3 ) {
return 1;
}
} else {
if (neighboursCount === 3 ) {
return 1;
}
}
return 0;
}
return 0;
});
});
}describe("Given empty grid", () => {
it("when next generation, should return empty", () => {
Test.assertDeepEquals(nextGeneration([]), []);
});
});
describe("Given a single cell", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0],
[0,1,0],
[0,0,0],
]), [
[0,0,0],
[0,0,0],
[0,0,0],
]);
});
});
describe("Given a cell with 1 neighbour at rows", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0],
[0,1,1,0],
[0,0,0,0],
]), [
[0,0,0,0],
[0,0,0,0],
[0,0,0,0],
]);
});
});
describe("Given a cell with 2 neighbours at rows", () => {
it("when next generation, should live", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,1,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,0,1,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a cell with 2 neighbours at cols", () => {
it("when next generation, should live", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0],
[0,1,0],
[0,1,0],
[0,1,0],
[0,0,0],
]), [
[0,0,0],
[0,0,0],
[0,1,0],
[0,0,0],
[0,0,0],
]);
});
});
describe("Given a cell with 2 neighbours at \ (diagonal)", () => {
it("when next generation, should live", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,0,0,0],
[0,0,1,0,0],
[0,0,0,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,1,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a cell with 2 neighbours at / (diagonal)", () => {
it("when next generation, should live", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,0,0,1,0],
[0,0,1,0,0],
[0,1,0,0,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,1,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a cell with 4 neighbours", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,1,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,0,1,0,0],
[0,1,0,1,0],
[0,0,1,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a cell with 5 neighbours", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,1,1,0],
[0,0,1,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,1,1,1,0],
[0,0,0,0,0],
[0,0,1,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a cell with 6 neighbours", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,1,1,0],
[0,1,1,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
[0,1,0,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a cell with 7 neighbours", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,1,1,0],
[0,1,1,1,0],
[0,1,0,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
]);
});
});
describe("Given a cell with 8 neighbours", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,1,1,0],
[0,1,1,1,0],
[0,1,1,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
]);
});
});
describe("Given a die cell with 2 neighbours", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,0,0,0],
[0,0,0,0,0],
[0,1,0,0,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a die cell with 3 neighbours", () => {
it("when next generation, should live", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
[0,1,0,0,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,1,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
]);
});
});
describe("Given a die cell with 4 neighbours", () => {
it("when next generation, should die", () => {
Test.assertDeepEquals(nextGeneration([
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
[0,1,0,1,0],
[0,0,0,0,0],
]), [
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
[0,0,0,0,0],
]);
});
});Mathematics
Algorithms
Numbers
Computing the real Gamma Function with Stirling's Approximation
Related Kata
Computing the complex Gamma function <-- click on the link to attempt the Kata now :D
Related Collection
Overview
The Gamma Function Γ(x) is an extension of the factorial function - while the factorial n! is only defined for non-negative integers, the gamma function is defined for all numbers except the non-positive integers. However, the gamma function has its argument shifted down by 1 such that Γ(n) = (n - 1)! for all n where n is a positive integer. One of its many applications is in fractional calculus.
Definitions
The main definition of the gamma function is based on a definite integral with positive infinity as one of its limits. There are also other exact definitions of the gamma function such as "Euler's definition as an infinite product" and the "Weierstrass definition". However, I will not elaborate on these definitions - more information can be easily found on Wikipedia (or by consulting your math professor).
The Problem
It is technically impossible to implement an exact definition of the Gamma Function in a computer/calculator since "there are, relatively speaking, no such simple solutions for factorials; no finite combination of sums, products, powers, exponential functions, or logarithms will suffice to express x!" (source: Wikipedia) so one must always resort to numerically approximating the Gamma function, ideally to a high degree of accuracy. A common, well-known approximation to the Gamma Function is known as Stirling's Approximation which has a simple formula and is usually sufficiently accurate for large values of x; however, since it is an asymptotic approximation, it loses its accuracy for small values of x and doesn't work with negative values of x due to an attempt at squarerooting a negative number (JavaScript Math.sqrt returns NaN for negative inputs).
The Challenge
Stirling's Approximation is implemented in this Kumite as a possible implementation for the Gamma Function; however, you will notice that it fails most, if not all, of the tests. The challenge, should you accept it, is to properly implement the Gamma Function such that it passes all test cases properly.
function gamma(x) {
// Stirling's Approximation is simple and efficient (just a single calculation)
// but will it work?
x -= 1; // Shift argument down by 1
return Math.sqrt(2 * Math.PI * x) * Math.pow(x / Math.E, x); // Compute Stirling's Formula
}Test.describe('Your real Gamma function "gamma"', function () {
Test.it('should properly compute Γ(n) to a high degree of accuracy where n is a positive integer', function () {
Test.assertApproxEquals(gamma(1), 1, 'Γ(1) = 0! = 1');
Test.assertApproxEquals(gamma(2), 1, 'Γ(2) = 1! = 1');
Test.assertApproxEquals(gamma(3), 2, 'Γ(3) = 2! = 2');
Test.assertApproxEquals(gamma(4), 6, 'Γ(4) = 3! = 6');
Test.assertApproxEquals(gamma(5), 24);
Test.assertApproxEquals(gamma(6), 120);
Test.assertApproxEquals(gamma(7), 720);
Test.assertApproxEquals(gamma(8), 5040);
Test.assertApproxEquals(gamma(9), 40320);
Test.assertApproxEquals(gamma(10), 362880);
Test.assertApproxEquals(gamma(51), 3.041409320e64);
});
Test.it('should properly compute Γ(x) to a high degree of accuracy for common values of positive real x', function () {
Test.assertApproxEquals(gamma(1 / 2), Math.sqrt(Math.PI), 'Γ(1/2) = sqrt(pi)');
Test.assertApproxEquals(gamma(3 / 2), 1 / 2 * Math.sqrt(Math.PI), 'Γ(3/2) = 1/2 * sqrt(pi)');
Test.assertApproxEquals(gamma(5 / 2), 3 / 4 * Math.sqrt(Math.PI), 'Γ(5/2) = 3/4 * sqrt(pi)');
Test.assertApproxEquals(gamma(7 / 2), 15 / 8 * Math.sqrt(Math.PI), 'Γ(7/2) = 15/8 * sqrt(pi)');
});
Test.it('should properly compute Γ(x) to a high degree of accuracy for common values of negative real x as well', function () {
Test.assertApproxEquals(gamma(-1 / 2), -2 * Math.sqrt(Math.PI), 'Γ(-1/2) = -2 * sqrt(pi)');
Test.assertApproxEquals(gamma(-3 / 2), 4 / 3 * Math.sqrt(Math.PI));
Test.assertApproxEquals(gamma(-5 / 2), -8 / 15 * Math.sqrt(Math.PI));
});
});Mathematics
Algorithms
Numbers
#include <complex.h> double complex multiply(double complex z, double complex w) { return z*w; }1 - proc multiply(z: complex, w: complex): complex { 1 + #include <complex.h> 2 + 3 + double complex multiply(double complex z, double complex w) { 2 2 return z*w; 3 3 }
#include <criterion/criterion.h> #include <complex.h> double complex multiply(double complex z, double complex w); Test(complex_numbers, multiply) { const double complex z = 5 - 1*I, w = -2 + 4*I; const double complex product = multiply(z, w); cr_assert_eq(product, -6 + 22*I); }1 - Test.describe('The complex "multiply" function'); 2 - var z: complex = 5 - 1i; 3 - var w: complex = -2 + 4i; 4 - Test.it('should correctly multiply two complex numbers "z" and "w" together'); 5 - var product: complex = multiply(z, w); 6 - Test.assertEquals(product.re, -6); 7 - Test.assertEquals(product.im, 22); 1 + #include <criterion/criterion.h> 2 + #include <complex.h> 3 + 4 + double complex multiply(double complex z, double complex w); 5 + 6 + Test(complex_numbers, multiply) { 7 + const double complex z = 5 - 1*I, w = -2 + 4*I; 8 + const double complex product = multiply(z, w); 9 + cr_assert_eq(product, -6 + 22*I); 10 + }
package com.mystuff.juststuff; import java.time.LocalDate; import java.time.format.DateTimeFormatter; import java.time.format.DateTimeParseException; import java.util.Arrays; import java.util.Set; import java.util.SortedSet; import java.util.TreeSet; import java.util.function.Predicate; import java.util.stream.Collectors; import java.util.stream.IntStream; public class Palindrome { private static final DateTimeFormatter formatter = DateTimeFormatter.ofPattern("MMddyyyy"); public Set<LocalDate> countDatePalindromes(final LocalDate startDate, final LocalDate endDate) { final SortedSet<LocalDate> sortedDates = new TreeSet<>(Arrays.asList(startDate, endDate)); return IntStream.rangeClosed(sortedDates.first().getYear(), sortedDates.last().getYear()) .filter(Palindrome::isPalindromePossible) .mapToObj(Palindrome::createPalindrome) .filter(isDateInRange(sortedDates.first(), sortedDates.last())) .collect(Collectors.toCollection(TreeSet::new)); } private static boolean isPalindromePossible(int year) { int monthFirstDigit = year % 10; return monthFirstDigit == 0 || monthFirstDigit == 1; } private static LocalDate createPalindrome(final int year) { final String yearStr = String.valueOf(year); final String datePalindrome = new StringBuilder(yearStr).reverse().append(yearStr).toString(); try { return LocalDate.parse(datePalindrome, formatter); } catch (final DateTimeParseException e) {} return null; } private static Predicate<LocalDate> isDateInRange(final LocalDate startDate, final LocalDate endDate) { return (date) -> !(date == null || date.isBefore(startDate) || date.isAfter(endDate)); } }... lines 1 to 14 have been collapsed. expand 1 1 package com.mystuff.juststuff; 2 2 3 3 import java.time.LocalDate; 4 4 import java.time.format.DateTimeFormatter; 5 5 import java.time.format.DateTimeParseException; 6 6 import java.util.Arrays; 7 7 import java.util.Set; 8 8 import java.util.SortedSet; 9 9 import java.util.TreeSet; 10 10 import java.util.function.Predicate; 11 11 import java.util.stream.Collectors; 12 12 import java.util.stream.IntStream; 13 13 14 14 public class Palindrome { 15 15 16 16 private static final DateTimeFormatter formatter = DateTimeFormatter.ofPattern("MMddyyyy"); 17 17 18 18 public Set<LocalDate> countDatePalindromes(final LocalDate startDate, final LocalDate endDate) { 19 19 final SortedSet<LocalDate> sortedDates = new TreeSet<>(Arrays.asList(startDate, endDate)); 20 20 return IntStream.rangeClosed(sortedDates.first().getYear(), sortedDates.last().getYear()) 21 + .filter(Palindrome::isPalindromePossible) 21 21 .mapToObj(Palindrome::createPalindrome) 22 22 .filter(isDateInRange(sortedDates.first(), sortedDates.last())) 23 23 .collect(Collectors.toCollection(TreeSet::new)); 25 + } 26 + 27 + private static boolean isPalindromePossible(int year) { 28 + int monthFirstDigit = year % 10; 29 + return monthFirstDigit == 0 || monthFirstDigit == 1; 24 24 } 25 25 26 26 private static LocalDate createPalindrome(final int year) { 27 27 final String yearStr = String.valueOf(year); 28 28 final String datePalindrome = new StringBuilder(yearStr).reverse().append(yearStr).toString(); 29 29 try { 30 30 return LocalDate.parse(datePalindrome, formatter); 31 31 } catch (final DateTimeParseException e) {} 32 32 return null; 33 33 } 34 34 35 35 private static Predicate<LocalDate> isDateInRange(final LocalDate startDate, final LocalDate endDate) { 36 36 return (date) -> !(date == null || date.isBefore(startDate) || date.isAfter(endDate)); 37 37 } 38 38 }
Mathematics
Algorithms
Numbers
Division of Complex Numbers
Related Collection
Complex Analysis <-- click on the link to train on this Collection :D
The Problem
Given two complex numbers z = x + iy and w = u + iv, how do I divide one by the other, e.g. compute z / w (or the reverse)?
The Solution
Just as one may rationalize the denominator of 1 / sqrt(2) to obtain sqrt(2) / 2, it is also possible to real-ize the denominator of z / w by multiplying both the numerator and denominator by the complex conjugate of "w" w* = u - iv. Then use the identity i^2 = -1 where necessary and collect real and imaginary terms.
z / w
= (z * w*) / (w * w*)
= ((x + iy) * (u - iv)) / ((u + iv) * (u - iv))
= (xu - xiv + iyu - yvi^2) / (u^2 - (iv)^2)
= ((xu + yv) + i(yu - xv)) / (u^2 + v^2)
= ((xu + yv) / (u^2 + v^2)) + i((yu - xv) / (u^2 + v^2))
Also note that u^2 + v^2 = |w|^2 which may help to simplify your code further.
function divide(z, w) {
var x = Re(z);
var y = Im(z);
var u = Re(w);
var v = Im(w);
const abs = z => Math.hypot(Re(z), Im(z));
return new ComplexNumber((x * u + y * v) / Math.pow(abs(w), 2), (y * u - x * v) / Math.pow(abs(w), 2));
}Test.describe('Your complex "divide" function', function () {
var z = new ComplexNumber(17, 13); // 17 + 13i
var w = new ComplexNumber(-6, 8); // -6 + 8i
Test.it('should divide two complex numbers correctly', function () {
var quotient = divide(z, w); // z / w should equal 1 / 50 - (107 / 50)i as per WolframAlpha
Test.assertApproxEquals(Re(quotient), 1 / 50);
Test.assertApproxEquals(Im(quotient), -107 / 50);
});
});Calculate A = B + alpha * C
proc stream(b, c, alpha) {
return b + alpha * c;
}Test.describe("HPCC STREAM Triad");
const size: int = 5;
const a: real = 3.0;
var B, C: [1..size] real = [i in 1..size] i;
var A: [B.domain] real = stream(B, C, a);
Test.expect(A == [4.0, 8.0, 12.0, 16.0, 20.0]);Mathematics
Algorithms
Numbers
Complex Addition and Subtraction
Related Collection
The Problem
Given two complex numbers z = x + iy and w = u + iv, how do I add them together? Furthermore, how do I compute z - w if required?
The Solution
For addition, adding two complex numbers is as easy as adding their real and imaginary components together. So z + w becomes (x + iy) + (u + iv) = (x + u) + i(y + v) and z - w becomes (x + iy) - (u + iv) = (x - u) + i(y - v).
function add(z, w) {
var x = Re(z);
var y = Im(z);
var u = Re(w);
var v = Im(w);
return new ComplexNumber(x + u, y + v); // z + w = (x + u) + i(y + v)
}
function subtract(z, w) {
var x = Re(z);
var y = Im(z);
var u = Re(w);
var v = Im(w);
return new ComplexNumber(x - u, y - v); // z - w = (x - u) + i(y - v)
}Test.describe('Function "add"', function () {
var z = new ComplexNumber(3, 2); // 3 + 2i
var w = new ComplexNumber(-5, 4); // -5 + 4i
Test.it('should correctly add two complex numbers together', function () {
var sum = add(z, w); // Should equal z + w = (3 + 2i) + (-5 + 4i) = -2 + 6i
Test.assertEquals(Re(sum), -2);
Test.assertEquals(Im(sum), 6);
});
Test.it('should correctly subtract two complex numbers in the given order', function () {
var difference = subtract(z, w); // Should equal z - w = (3 + 2i) - (-5 + 4i) = 8 - 2i
Test.assertEquals(Re(difference), 8);
Test.assertEquals(Im(difference), -2);
});
});Changed game of life to take an array of arrays of rows and columns.
function nextGeneration(grid) { const neighborsInit = { l:true,bl:true,bc:true,br:true,r:true,tr:true,tc:true,tl:true }; let neighbors = JSON.parse(JSON.stringify(neighborsInit)); let liveNeighbors = 0; let isAlive = true; var nextGen = JSON.parse(JSON.stringify(grid)); grid.map(function(row,rowIndex,rows){ row.map(function(element,index,thisRow){ liveNeighbors = 0; neighbors = JSON.parse(JSON.stringify(neighborsInit)); if(element == 1){ isAlive = true; } else { isAlive = false; } //Where to check if(rowIndex === 0){ //If it is the first row don't look for life above neighbors.tr = neighbors.tc = neighbors.tl = false; } if(rowIndex === grid.length-1){ //If it is the last row don't look for life below neighbors.br = neighbors.bc = neighbors.bl = false; } if(index == 0){ //If it is the first column don't look for life left neighbors.tl = neighbors.l = neighbors.bl = false; } if(index == row.length-1){ //If it is the last column don't look for life right neighbors.tr = neighbors.r = neighbors.br = false; } //Top if(neighbors.tl && grid[rowIndex-1][index-1] == 1){ liveNeighbors++; } if(neighbors.tc && grid[rowIndex-1][index] == 1){ liveNeighbors++; } if(neighbors.tr && grid[rowIndex-1][index+1] == 1){ liveNeighbors++; } //right if(neighbors.r && grid[rowIndex][index+1] == 1){ liveNeighbors++; } //Bottom if(neighbors.br && (grid[rowIndex+1][index+1] === 1)){ liveNeighbors++; } if(neighbors.bc && grid[rowIndex+1][index] == 1){ liveNeighbors++; } if(neighbors.bl && grid[rowIndex+1][index-1] == 1){ liveNeighbors++; } //left if(neighbors.l && grid[rowIndex][index-1] == 1){ liveNeighbors++; } //Live? if(isAlive){ //Any live cell with fewer than two live neighbours dies, as if caused by underpopulation. if(liveNeighbors < 2){ //kill //console.log('die from lonliness :('); nextGen[rowIndex][index] = 0; } //Any live cell with more than three live neighbours dies, as if by overcrowding. if(liveNeighbors > 3){ //kill //console.log('died from over crowding'); nextGen[rowIndex][index] = 0; } } //Any dead cell with exactly three live neighbours becomes a live cell. if(!isAlive && liveNeighbors == 3){ nextGen[rowIndex][index] = 1; } else { //console.info('he stay ded'); } }); }); return nextGen; }1 1 function nextGeneration(grid) { 2 - return grid; 2 + const neighborsInit = { 3 + l:true,bl:true,bc:true,br:true,r:true,tr:true,tc:true,tl:true 4 + }; 5 + let neighbors = JSON.parse(JSON.stringify(neighborsInit)); 6 + let liveNeighbors = 0; 7 + let isAlive = true; 8 + var nextGen = JSON.parse(JSON.stringify(grid)); 9 + grid.map(function(row,rowIndex,rows){ 10 + row.map(function(element,index,thisRow){ 11 + liveNeighbors = 0; 12 + neighbors = JSON.parse(JSON.stringify(neighborsInit)); 13 + if(element == 1){ 14 + isAlive = true; 15 + } else { 16 + isAlive = false; 17 + } 18 + 19 + //Where to check 20 + if(rowIndex === 0){ 21 + //If it is the first row don't look for life above 22 + neighbors.tr = neighbors.tc = neighbors.tl = false; 23 + } 24 + if(rowIndex === grid.length-1){ 25 + //If it is the last row don't look for life below 26 + neighbors.br = neighbors.bc = neighbors.bl = false; 27 + } 28 + if(index == 0){ 29 + //If it is the first column don't look for life left 30 + neighbors.tl = neighbors.l = neighbors.bl = false; 31 + } 32 + if(index == row.length-1){ 33 + //If it is the last column don't look for life right 34 + neighbors.tr = neighbors.r = neighbors.br = false; 35 + } 36 + //Top 37 + if(neighbors.tl && grid[rowIndex-1][index-1] == 1){ 38 + liveNeighbors++; 39 + } 40 + if(neighbors.tc && grid[rowIndex-1][index] == 1){ 41 + liveNeighbors++; 42 + } 43 + if(neighbors.tr && grid[rowIndex-1][index+1] == 1){ 44 + liveNeighbors++; 45 + } 46 + //right 47 + if(neighbors.r && grid[rowIndex][index+1] == 1){ 48 + liveNeighbors++; 49 + } 50 + //Bottom 51 + if(neighbors.br && (grid[rowIndex+1][index+1] === 1)){ 52 + liveNeighbors++; 53 + } 54 + if(neighbors.bc && grid[rowIndex+1][index] == 1){ 55 + liveNeighbors++; 56 + } 57 + if(neighbors.bl && grid[rowIndex+1][index-1] == 1){ 58 + liveNeighbors++; 59 + } 60 + //left 61 + if(neighbors.l && grid[rowIndex][index-1] == 1){ 62 + liveNeighbors++; 63 + } 64 + 65 + //Live? 66 + if(isAlive){ 67 + 68 + //Any live cell with fewer than two live neighbours dies, as if caused by underpopulation. 69 + if(liveNeighbors < 2){ 70 + //kill 71 + //console.log('die from lonliness :('); 72 + nextGen[rowIndex][index] = 0; 73 + } 74 + //Any live cell with more than three live neighbours dies, as if by overcrowding. 75 + if(liveNeighbors > 3){ 76 + //kill 77 + //console.log('died from over crowding'); 78 + nextGen[rowIndex][index] = 0; 79 + } 80 + } 81 + //Any dead cell with exactly three live neighbours becomes a live cell. 82 + if(!isAlive && liveNeighbors == 3){ 83 + nextGen[rowIndex][index] = 1; 84 + } else { 85 + //console.info('he stay ded'); 86 + } 87 + }); 88 + }); 89 + return nextGen; 3 3 }
describe("Given empty grid", () => { it("when next generation, should return empty", () => { assert.deepEqual(nextGeneration([]), []); }); }); describe("Given a single cell", () => { it("when next generation, should die", () => { assert.deepEqual(nextGeneration([ [0,0,0], [0,1,0], [0,0,0], ]), [ [0,0,0], [0,0,0], [0,0,0], ]); }); }); describe("A complex Gen", () => { it("when next generation, should evolve", () => { assert.deepEqual(nextGeneration([ [0,0,0,0], [0,1,0,0], [0,0,1,1], [0,0,1,0], ]), [ [0,0,0,0], [0,0,1,0], [0,1,1,1], [0,0,1,1] ]); }); });1 1 describe("Given empty grid", () => { 2 2 it("when next generation, should return empty", () => { 3 3 assert.deepEqual(nextGeneration([]), []); 4 4 }); 5 5 }); 6 6 7 7 describe("Given a single cell", () => { 8 8 it("when next generation, should die", () => { 9 9 assert.deepEqual(nextGeneration([ 10 - 0,0,0, 11 - 0,1,0, 12 - 0,0,0, 10 + [0,0,0], 11 + [0,1,0], 12 + [0,0,0], 13 13 ]), [ 14 - 0,0,0, 15 - 0,0,0, 16 - 0,0,0, 14 + [0,0,0], 15 + [0,0,0], 16 + [0,0,0], 17 + ]); 18 + }); 19 + }); 20 + 21 + describe("A complex Gen", () => { 22 + it("when next generation, should evolve", () => { 23 + assert.deepEqual(nextGeneration([ 24 + [0,0,0,0], 25 + [0,1,0,0], 26 + [0,0,1,1], 27 + [0,0,1,0], 28 + ]), [ 29 + [0,0,0,0], 30 + [0,0,1,0], 31 + [0,1,1,1], 32 + [0,0,1,1] 17 17 ]); 18 18 }); 19 19 });
Mathematics
Algorithms
Numbers
Sinus Cardinalis
Related Kata
Implement the (Unnormalized) Cardinal Sine (JavaScript)
Summary
This Kumite extends the built-in Math object in JavaScript with the sinc method which computes the cardinal sine of the first argument x (a Number) passed in.
Implementation Details
Math.sinc receives two arguments: the first argument x (a Number) is required and the second argument isNormalized (a boolean) is optional. If the second argument is not specified or set to false, the function returns the historical (unnormalized) cardinal sine of x. Otherwise, if the second argument is set to true, the function will return the normalized cardinal sine of x instead. Any invalid arguments passed in will cause the function to throw a TypeError with a suitable message.
Math.sinc = function (x, isNormalized = false) { // Type check "x" - if "x" is not a number then a TypeError is thrown if (typeof x !== 'number') throw new TypeError('In Math.sinc, the first argument "x" passed in must be a Number!'); // Type check "isNormalized" - if it is not a boolean then a TypeError is thrown if (typeof isNormalized !== 'boolean') throw new TypeError('In Math.sinc, the second argument "isNormalized" passed in must be a Boolean!'); // Special Case - sinc(0) = 1 regardless of which definition of cardinal sine is used if (x === 0) return 1; // If isNormalized is set to true then multiply argument by pi and pass into unnormalized cardinal sine if (isNormalized) return Math.sinc(Math.PI * x); // Otherwise just use sinc(x) = sin(x) / x and return the result return Math.sin(x) / x; };1 - /* 2 - function.sinc.php 3 - A simple math function (with input validation) 4 - that computes the cardinal sine of a real 5 - number $x 6 - Author: Donald Leung 7 - NOTE: Comes with two user-defined constants 8 - */ 9 - // Constants (for use by the sinc() function as flags) 10 - define('SINC_DEFAULT', 0); 11 - define('SINC_NORMALIZED', 1); 12 - // Function declaration and definition 13 - function sinc($x, $flag = SINC_DEFAULT) { 14 - // Type check "x" - confirm that it is either of an integer or a float 15 - if (!is_int($x) && !is_float($x)) throw new InvalidArgumentException('In sinc(), the first argument "x" passed in must either be an integer or a float'); 16 - // Validate the flag - it can only be one of SINC_DEFAULT and SINC_NORMALIZED 17 - if ($flag !== SINC_DEFAULT && $flag !== SINC_NORMALIZED) throw new InvalidArgumentException('The sinc() function only accepts 2 possible flags: SINC_DEFAULT and SINC_NORMALIZED'); 18 - // Special Case: where x = 0, sinc(x) = sinc(0) = 1 19 - if ($x == 0) return 1; 20 - // If the flag is set to SINC_NORMALIZED then multiply the argument "x" by pi and compute its unnormalized cardinal sine at pi * x 21 - if ($flag === SINC_NORMALIZED) return sinc(M_PI * $x); 22 - // Otherwise just return the unnormalized cardinal sine of x 23 - return sin($x) / $x; 24 - } 1 + Math.sinc = function (x, isNormalized = false) { 2 + // Type check "x" - if "x" is not a number then a TypeError is thrown 3 + if (typeof x !== 'number') throw new TypeError('In Math.sinc, the first argument "x" passed in must be a Number!'); 4 + // Type check "isNormalized" - if it is not a boolean then a TypeError is thrown 5 + if (typeof isNormalized !== 'boolean') throw new TypeError('In Math.sinc, the second argument "isNormalized" passed in must be a Boolean!'); 6 + // Special Case - sinc(0) = 1 regardless of which definition of cardinal sine is used 7 + if (x === 0) return 1; 8 + // If isNormalized is set to true then multiply argument by pi and pass into unnormalized cardinal sine 9 + if (isNormalized) return Math.sinc(Math.PI * x); 10 + // Otherwise just use sinc(x) = sin(x) / x and return the result 11 + return Math.sin(x) / x; 12 + };
Test.describe('Math.sinc', function () { Test.it('should correctly compute the unnormalized cardinal sine for a few simple values', function () { Test.assertApproxEquals(Math.sinc(0), 1, 'sinc(0) = 1'); Test.assertApproxEquals(Math.sinc(-1), 0.841470984807897); Test.assertApproxEquals(Math.sinc(2.5), 0.239388857641583); Test.assertApproxEquals(Math.sinc(-Math.PI), 0); Test.assertApproxEquals(Math.sinc(3.7), -0.143198957002295); Test.assertApproxEquals(Math.sinc(-5), -0.191784854932628); Test.assertApproxEquals(Math.sinc(10), -0.054402111088937); Test.assertApproxEquals(Math.sinc(0, false), 1, 'sinc(0) = 1'); Test.assertApproxEquals(Math.sinc(-1, false), 0.841470984807897); Test.assertApproxEquals(Math.sinc(2.5, false), 0.239388857641583); Test.assertApproxEquals(Math.sinc(-Math.PI, false), 0); Test.assertApproxEquals(Math.sinc(3.7, false), -0.143198957002295); Test.assertApproxEquals(Math.sinc(-5, false), -0.191784854932628); Test.assertApproxEquals(Math.sinc(10, false), -0.054402111088937); }); Test.it('should correctly compute the normalized cardinal sine for a few simple values', function () { Test.assertApproxEquals(Math.sinc(0, true), 1, 'sinc(0) = 1'); Test.assertApproxEquals(Math.sinc(1, true), 0); Test.assertApproxEquals(Math.sinc(-2.5, true), 0.127323954473516); Test.assertApproxEquals(Math.sinc(Math.PI, true), -0.043598628629188); Test.assertApproxEquals(Math.sinc(-3.7, true), -0.069599488486552); Test.assertApproxEquals(Math.sinc(5, true), 0); Test.assertApproxEquals(Math.sinc(-10, true), 0); }); Test.it('should type check its first argument "x"', function () { Test.expectError('A numeric string should be rejected', function () { Math.sinc('11.23'); }); Test.expectError('A boolean should be rejected', function () { Math.sinc(true); }); Test.expectError('An array should be rejected', function () { Math.sinc([5]); }); Test.expectError('An object should be rejected', function () { Math.sinc({valueOf: 10}); }); }); Test.it('should type check its second argument "isNormalized"', function () { Test.expectError('A number should be rejected', function () { Math.sinc(0, 3); }); Test.expectError('A string should be rejected', function () { Math.sinc(0, 'Hello World!'); }); Test.expectError('An array should be rejected', function () { Math.sinc(0, [false]); }); Test.expectError('An object should be rejected', function () { Math.sinc(0, {valueOf: true, toString: 'true'}); }); }); });1 - class SinusCardinalisTest extends TestCase { 2 - protected function assertFuzzyEquals(float $expected, float $actual) { 3 - $this->assertTrue(abs($expected) <= 1 ? abs($expected - $actual) <= 1e-9 : abs(($expected - $actual) / $expected) <= 1e-9, "Actual value $actual not sufficiently close to expected value $expected (accepted relative error: 1e-9)"); 4 - } 5 - public function testThatConstantsAreDefined() { 6 - $this->assertTrue(defined('SINC_DEFAULT')); 7 - $this->assertTrue(defined('SINC_NORMALIZED')); 8 - if (defined('SINC_DEFAULT') && defined('SINC_NORMALIZED')) { 9 - echo SINC_DEFAULT . "\r\n"; 10 - echo SINC_NORMALIZED . "\r\n"; 11 - $this->assertNotEquals(SINC_DEFAULT, SINC_NORMALIZED, 'The two constants/flags used by sinc() should have different values!'); 12 - } 13 - } 14 - public function testZero() { 15 - $this->assertFuzzyEquals(1, sinc(0)); 16 - $this->assertFuzzyEquals(1, sinc(0.0)); 17 - $this->assertFuzzyEquals(1, sinc(0, SINC_DEFAULT)); 18 - $this->assertFuzzyEquals(1, sinc(0.0, SINC_DEFAULT)); 19 - $this->assertFuzzyEquals(1, sinc(0, SINC_NORMALIZED)); 20 - $this->assertFuzzyEquals(1, sinc(0.0, SINC_NORMALIZED)); 21 - } 22 - public function testUnnormalized() { 23 - $this->assertFuzzyEquals(0.841470984807897, sinc(1)); 24 - $this->assertFuzzyEquals(0.324219657468139, sinc(-2.3)); 25 - $this->assertFuzzyEquals(-0.143198957002295, sinc(3.7)); 26 - $this->assertFuzzyEquals(-0.191784854932628, sinc(-5)); 27 - $this->assertFuzzyEquals(0.119739482820381, sinc(8.1)); 28 - $this->assertFuzzyEquals(-0.054402111088937, sinc(-10)); 29 - $this->assertFuzzyEquals(0.841470984807897, sinc(1, SINC_DEFAULT)); 30 - $this->assertFuzzyEquals(0.324219657468139, sinc(-2.3, SINC_DEFAULT)); 31 - $this->assertFuzzyEquals(-0.143198957002295, sinc(3.7, SINC_DEFAULT)); 32 - $this->assertFuzzyEquals(-0.191784854932628, sinc(-5, SINC_DEFAULT)); 33 - $this->assertFuzzyEquals(0.119739482820381, sinc(8.1, SINC_DEFAULT)); 34 - $this->assertFuzzyEquals(-0.054402111088937, sinc(-10, SINC_DEFAULT)); 35 - } 36 - public function testNormalized() { 37 - $this->assertFuzzyEquals(0, sinc(1, SINC_NORMALIZED)); 38 - $this->assertFuzzyEquals(0.111964394521844, sinc(-2.3, SINC_NORMALIZED)); 39 - $this->assertFuzzyEquals(-0.069599488486552, sinc(3.7, SINC_NORMALIZED)); 40 - $this->assertFuzzyEquals(0, sinc(-5, SINC_NORMALIZED)); 41 - $this->assertFuzzyEquals(0.012143600531895, sinc(8.1, SINC_NORMALIZED)); 42 - $this->assertFuzzyEquals(0, sinc(-10, SINC_NORMALIZED)); 43 - } 44 - /** 45 - * @expectedException InvalidArgumentException 46 - */ 47 - public function testInvalidArgument1() { 48 - sinc("11.23"); 49 - } 50 - /** 51 - * @expectedException InvalidArgumentException 52 - */ 53 - public function testInvalidArgument2() { 54 - sinc("Hello World"); 55 - } 56 - /** 57 - * @expectedException InvalidArgumentException 58 - */ 59 - public function testInvalidArgument3() { 60 - sinc(true); 61 - } 62 - /** 63 - * @expectedException InvalidArgumentException 64 - */ 65 - public function testInvalidArgument4() { 66 - sinc(array(5)); 67 - } 68 - /** 69 - * @expectedException InvalidArgumentException 70 - */ 71 - public function testInvalidFlag1() { 72 - sinc(3.2, 0.0); 73 - } 74 - /** 75 - * @expectedException InvalidArgumentException 76 - */ 77 - public function testInvalidFlag2() { 78 - sinc(3.2, 1.0); 79 - } 80 - } 1 + Test.describe('Math.sinc', function () { 2 + Test.it('should correctly compute the unnormalized cardinal sine for a few simple values', function () { 3 + Test.assertApproxEquals(Math.sinc(0), 1, 'sinc(0) = 1'); 4 + Test.assertApproxEquals(Math.sinc(-1), 0.841470984807897); 5 + Test.assertApproxEquals(Math.sinc(2.5), 0.239388857641583); 6 + Test.assertApproxEquals(Math.sinc(-Math.PI), 0); 7 + Test.assertApproxEquals(Math.sinc(3.7), -0.143198957002295); 8 + Test.assertApproxEquals(Math.sinc(-5), -0.191784854932628); 9 + Test.assertApproxEquals(Math.sinc(10), -0.054402111088937); 10 + Test.assertApproxEquals(Math.sinc(0, false), 1, 'sinc(0) = 1'); 11 + Test.assertApproxEquals(Math.sinc(-1, false), 0.841470984807897); 12 + Test.assertApproxEquals(Math.sinc(2.5, false), 0.239388857641583); 13 + Test.assertApproxEquals(Math.sinc(-Math.PI, false), 0); 14 + Test.assertApproxEquals(Math.sinc(3.7, false), -0.143198957002295); 15 + Test.assertApproxEquals(Math.sinc(-5, false), -0.191784854932628); 16 + Test.assertApproxEquals(Math.sinc(10, false), -0.054402111088937); 17 + }); 18 + Test.it('should correctly compute the normalized cardinal sine for a few simple values', function () { 19 + Test.assertApproxEquals(Math.sinc(0, true), 1, 'sinc(0) = 1'); 20 + Test.assertApproxEquals(Math.sinc(1, true), 0); 21 + Test.assertApproxEquals(Math.sinc(-2.5, true), 0.127323954473516); 22 + Test.assertApproxEquals(Math.sinc(Math.PI, true), -0.043598628629188); 23 + Test.assertApproxEquals(Math.sinc(-3.7, true), -0.069599488486552); 24 + Test.assertApproxEquals(Math.sinc(5, true), 0); 25 + Test.assertApproxEquals(Math.sinc(-10, true), 0); 26 + }); 27 + Test.it('should type check its first argument "x"', function () { 28 + Test.expectError('A numeric string should be rejected', function () { 29 + Math.sinc('11.23'); 30 + }); 31 + Test.expectError('A boolean should be rejected', function () { 32 + Math.sinc(true); 33 + }); 34 + Test.expectError('An array should be rejected', function () { 35 + Math.sinc([5]); 36 + }); 37 + Test.expectError('An object should be rejected', function () { 38 + Math.sinc({valueOf: 10}); 39 + }); 40 + }); 41 + Test.it('should type check its second argument "isNormalized"', function () { 42 + Test.expectError('A number should be rejected', function () { 43 + Math.sinc(0, 3); 44 + }); 45 + Test.expectError('A string should be rejected', function () { 46 + Math.sinc(0, 'Hello World!'); 47 + }); 48 + Test.expectError('An array should be rejected', function () { 49 + Math.sinc(0, [false]); 50 + }); 51 + Test.expectError('An object should be rejected', function () { 52 + Math.sinc(0, {valueOf: true, toString: 'true'}); 53 + }); 54 + }); 55 + });
The Codewars built-in runBF interpreter should correctly interpret a CAT program. According to the specs, the runBF interpreter treats EOF as byte(-1).
,+[-.,+]Test.describe('The BF CAT program', function () {
Test.it('should return "CAT" when "CAT" is passed in', function () {
Test.assertEquals(runBF(CAT), CAT);
});
Test.it('should return "Codewars" when "Codewars" is passed in', function () {
Test.assertEquals(runBF(CODEWARS), CODEWARS);
});
Test.it('should return "@donaldsebleung" when "@donaldsebleung" is passed in', function () {
Test.assertEquals(runBF(AUTHOR), AUTHOR);
});
Test.it('should return an empty string if nothing is passed in', function () {
Test.assertEquals(runBF(), '');
});
Test.it('should CAT 100 random strings', function () {
for (let i = 0; i < 100; i++) {
var randomString = Test.randomToken();
console.log(`Testing for ${randomString}`);
Test.assertEquals(runBF(randomString), randomString);
}
});
});According to the Esolangs Wiki, the BF program presented in this Kumite often triggers interpreter bugs. Regardless, the Codewars built-in runBF interpreter should interpret the program correctly without any issues and return the string "Hello World!\n".
>++++++++[-<+++++++++>]<.>>+>-[+]++>++>+++[>[->+++<<+++>]<<]>-----.>->
+++..+++.>-.<<+[>[+>+]>>]<--------------.>>.+++.------.--------.>+.>+.Test.describe('A complex BF Hello World program', function () {
Test.it('should return "Hello World!\\n"', function () {
Test.assertEquals(runBF(), 'Hello World!\n');
});
});Testing the Codewars built-in runBF interpreter with no program input and with a simple Hello World program that contains a simple (non-nested) loop. The interpreter should be able to interpret the program properly and return the string "Hello World!".
++++++++++[>+++++++>++++++++++>+++++++++++>+++>+++++++++<<<<<-]>++.>+.>--..+++.>++.>---.<<.+++.------.<-.>>+.Test.describe('The BF Hello World Program', function () {
Test.it('should return "Hello World!"', function () {
Test.assertEquals(runBF(), 'Hello World!');
});
Test.it('should be less than 110 characters', function () {
// Testing reading the user solution directly
var userSolution = require('fs').readFileSync('/home/codewarrior/solution.txt', 'utf8');
console.log(`Your program:\r\n\r\n${userSolution}\r\n`);
console.log(`Your program length: ${userSolution.length}`);
Test.expect(userSolution.length < 110, 'Your Hello World Program should be shorter than 120 characters!');
});
});The exact same program as before but with some rather messy comments in between (and at the start and end of the program). The Codewars built-in runBF interpreter should correctly handle the program regardless and return the string "Hello World!".
[ This is a loop comment. Command characters, they should be ignored <here>. Including [matching square brackets]. Oh, and "+" and >-< signs. And gibberish: skldfjsdklfjs,..sd,dsf,s.fd,++--sdfsdsdfKLSDJFKLDSJ[[[][]][][[[][]]]] And unmatched round brackets: ((((()))(((())))))))))))))))))))))) ] sdklfjsdkldfjskldfs+++++++++++++++++sdlkfjsdlkfjsdfklsdjfkldsjfd++++++++++++++++++SDLKFJSDKLJSDFKLDSFJFDSKLJDFS++++++++++++++++++++++++SDLKFJDSFKLJFSDKLDSFJKSLDFJDSFKLDFSJ+++++++++++++.>++++(+++++(+()++)+((++)(++)))++++++++++++++NESWNEWSNEWWWSEEEEE+++++++++++++++;;++++++++++++;;;;;++++++++++++;;;;+++++++++;;;;;++++++++++++********++++++++++.>+++*****++++++++++++++***;;;*****++++++++++++;;**;;;+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++.+++++sdfsfdsdfsdfsfd++++sdfsdffdsfds++sdfsdffsddfssdf+ (These last few plus signs should not affect the final output)1 - ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++. 1 + [ 2 + This is a loop comment. 3 + Command characters, they should be ignored <here>. 4 + Including [matching square brackets]. 5 + Oh, and "+" and >-< signs. 6 + And gibberish: skldfjsdklfjs,..sd,dsf,s.fd,++--sdfsdsdfKLSDJFKLDSJ[[[][]][][[[][]]]] 7 + And unmatched round brackets: ((((()))(((())))))))))))))))))))))) 8 + ] 9 + sdklfjsdkldfjskldfs+++++++++++++++++sdlkfjsdlkfjsdfklsdjfkldsjfd++++++++++++++++++SDLKFJSDKLJSDFKLDSFJFDSKLJDFS++++++++++++++++++++++++SDLKFJDSFKLJFSDKLDSFJKSLDFJDSFKLDFSJ+++++++++++++.>++++(+++++(+()++)+((++)(++)))++++++++++++++NESWNEWSNEWWWSEEEEE+++++++++++++++;;++++++++++++;;;;;++++++++++++;;;;+++++++++;;;;;++++++++++++********++++++++++.>+++*****++++++++++++++***;;;*****++++++++++++;;**;;;+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++.>+++++++++++++++++++++++++++++++++.+++++sdfsfdsdfsdfsfd++++sdfsdffdsfds++sdfsdffsddfssdf+ (These last few plus signs should not affect the final output)
After doing:
- Extract method
- Move method donde calcular el precio (movie or rental)?
- Unit test smell: Indirect Testing
- Replace temp with query
- Replace Type Code with State/Strategy
- Replace Conditional with Polymorphism
- Replace Constructor with Factory Method
class RentalReport { statement(customer) { let result = "Rental Record for " + customer.name + "\n"; customer.rentals.forEach((each) => { //show figures for this rental result += "\t" + each.movie.title+ "\t" + each.getAmount() + "\n"; }); //add footer lines result += "Amount owed is " + customer.getTotalAmount() + "\n"; result += "You earned " + customer.getFrequentPoints() + " frequent renter points"; return result; } } const MovieType = { CHILDREN: Symbol('CHILDREN'), REGULAR: Symbol('REGULAR'), NEW_RELEASE: Symbol('NEW_RELEASE'), } class Price { static create(priceCode) { switch (priceCode) { case MovieType.REGULAR: return new RegularPrice(); case MovieType.NEW_RELEASE: return new NewReleasePrice(); case MovieType.CHILDREN: return new ChildrenPrice(); } } get code() { throw "not implemented"; } getAmount(daysRented) { throw "not implemented"; } getFrequentPoints(daysRented) { return 1; } } class ChildrenPrice extends Price { get code() { return MovieType.CHILDREN; } getAmount(daysRented) { let amount = 1.5; if (daysRented > 3) amount += (daysRented - 3) * 1.5; return amount; } } class RegularPrice extends Price { get code() { return MovieType.REGULAR; } getAmount(daysRented) { let amount = 2; if (daysRented > 2) amount += (daysRented - 2) * 1.5; return amount; } } class NewReleasePrice extends Price { get code() { return MovieType.NEW_RELEASE; } getAmount(daysRented) { return daysRented * 3; } getFrequentPoints(daysRented) { return daysRented > 1 ? 2 : 1; } } class Movie { constructor (title, priceCode) { this._title = title; this.priceCode = priceCode; } set priceCode(priceCode) { this._price = Price.create(priceCode); } get priceCode() { return this._price.code; } get title() { return this._title; } getAmount(daysRented) { return this._price.getAmount(daysRented); } getFrequentPoints(daysRented) { return this._price.getFrequentPoints(daysRented); } } class Rental { constructor(movie, daysRented) { this._movie = movie; this._daysRented = daysRented; } get daysRented() { return this._daysRented; } get movie() { return this._movie; } getAmount() { return this.movie.getAmount(this.daysRented); } getFrequentPoints() { return this.movie.getFrequentPoints(this.daysRented); } } class Customer { constructor(name) { this._name = name; this._rentals = []; } get name() { return this._name; } get rentals() { return this._rentals; } addRental(rental) { this._rentals.push(rental); } getFrequentPoints() { return this.rentals.reduce((frequentPoints, rental) => frequentPoints + rental.getFrequentPoints(), 0); } getTotalAmount() { return this.rentals.reduce((amount, rental) => amount + rental.getAmount(), 0); } }1 1 class RentalReport { 2 2 statement(customer) { 3 - let totalAmount = 0; 4 - let frequentRenterPoints = 0; 5 5 let result = "Rental Record for " + customer.name + "\n"; 6 6 customer.rentals.forEach((each) => { 7 - let thisAmount = 0; 8 - //determine amounts for each line 9 - switch (each.movie.priceCode) { 10 - case MovieType.REGULAR: 11 - thisAmount += 2; 12 - if (each.daysRented > 2) ... lines 13 to 28 have been collapsed. expand 13 - thisAmount += (each.daysRented - 2) * 1.5; 14 - break; 15 - case MovieType.NEW_RELEASE: 16 - thisAmount += each.daysRented * 3; 17 - break; 18 - case MovieType.CHILDREN: 19 - thisAmount += 1.5; 20 - if (each.daysRented > 3) 21 - thisAmount += (each.daysRented - 3) * 1.5; 22 - break; 23 - } 24 - // add frequent renter points 25 - frequentRenterPoints ++; 26 - 27 - // add bonus for a two day new release rental 28 - if ((each.movie.priceCode == MovieType.NEW_RELEASE) && each.daysRented > 1) frequentRenterPoints ++; 29 29 //show figures for this rental 30 - result += "\t" + each.movie.title+ "\t" + thisAmount + "\n"; 31 - totalAmount += thisAmount; 6 + result += "\t" + each.movie.title+ "\t" + each.getAmount() + "\n"; 32 32 }); 33 33 //add footer lines 34 - result += "Amount owed is " + totalAmount + "\n"; 35 - result += "You earned " + frequentRenterPoints + " frequent renter points"; 9 + result += "Amount owed is " + customer.getTotalAmount() + "\n"; 10 + result += "You earned " + customer.getFrequentPoints() + " frequent renter points"; 36 36 return result; 37 37 } 38 - 39 39 } 40 40 41 41 const MovieType = { 42 42 CHILDREN: Symbol('CHILDREN'), 43 43 REGULAR: Symbol('REGULAR'), 44 44 NEW_RELEASE: Symbol('NEW_RELEASE'), 45 45 } 46 46 ... lines 21 to 28 have been collapsed. expand 21 + class Price { 22 + static create(priceCode) { 23 + switch (priceCode) { 24 + case MovieType.REGULAR: 25 + return new RegularPrice(); 26 + case MovieType.NEW_RELEASE: 27 + return new NewReleasePrice(); 28 + case MovieType.CHILDREN: 29 + return new ChildrenPrice(); 30 + } 31 + } 32 + get code() { 33 + throw "not implemented"; 34 + } 35 + getAmount(daysRented) { 36 + throw "not implemented"; 37 + } 38 + getFrequentPoints(daysRented) { 39 + return 1; 40 + } 41 + } 42 + 43 + class ChildrenPrice extends Price { 44 + get code() { 45 + return MovieType.CHILDREN; 46 + } 47 + getAmount(daysRented) { 48 + let amount = 1.5; 49 + if (daysRented > 3) 50 + amount += (daysRented - 3) * 1.5; 51 + return amount; 52 + } 53 + } 54 + 55 + class RegularPrice extends Price { 56 + get code() { 57 + return MovieType.REGULAR; 58 + } 59 + getAmount(daysRented) { 60 + let amount = 2; 61 + if (daysRented > 2) 62 + amount += (daysRented - 2) * 1.5; 63 + return amount; 64 + } 65 + } 66 + 67 + class NewReleasePrice extends Price { 68 + get code() { 69 + return MovieType.NEW_RELEASE; 70 + } 71 + getAmount(daysRented) { 72 + return daysRented * 3; 73 + } 74 + getFrequentPoints(daysRented) { 75 + return daysRented > 1 ? 2 : 1; 76 + } 77 + } 78 + 79 + 47 47 class Movie { 48 48 constructor (title, priceCode) { 49 49 this._title = title; 50 - this._priceCode = priceCode; 83 + this.priceCode = priceCode; 84 + } 85 + set priceCode(priceCode) { 86 + this._price = Price.create(priceCode); 51 51 } 52 52 get priceCode() { 53 - return this._priceCode; 89 + return this._price.code; 54 54 } 55 55 get title() { 56 56 return this._title; 57 57 } ... lines 94 to 99 have been collapsed. expand 94 + getAmount(daysRented) { 95 + return this._price.getAmount(daysRented); 96 + } 97 + getFrequentPoints(daysRented) { 98 + return this._price.getFrequentPoints(daysRented); 99 + } 58 58 } 59 59 60 60 class Rental { 61 61 constructor(movie, daysRented) { 62 62 this._movie = movie; 63 63 this._daysRented = daysRented; 64 64 } 65 65 get daysRented() { 66 66 return this._daysRented; 67 67 } 68 68 get movie() { 69 69 return this._movie; 70 70 } ... lines 113 to 118 have been collapsed. expand 113 + getAmount() { 114 + return this.movie.getAmount(this.daysRented); 115 + } 116 + getFrequentPoints() { 117 + return this.movie.getFrequentPoints(this.daysRented); 118 + } 71 71 } 72 72 73 73 class Customer { 74 74 constructor(name) { 75 75 this._name = name; 76 76 this._rentals = []; 77 77 } 78 78 get name() { 79 79 return this._name; 80 80 } 81 81 get rentals() { 82 82 return this._rentals; 83 83 } 84 84 addRental(rental) { 85 85 this._rentals.push(rental); 86 86 } ... lines 135 to 140 have been collapsed. expand 135 + getFrequentPoints() { 136 + return this.rentals.reduce((frequentPoints, rental) => frequentPoints + rental.getFrequentPoints(), 0); 137 + } 138 + getTotalAmount() { 139 + return this.rentals.reduce((amount, rental) => amount + rental.getAmount(), 0); 140 + } 87 87 } 88 -
Hashes
Data Structures
/* HashMap Example */ import java.util.*; import java.util.function.*; import java.util.stream.*; class HashMapDemo { public static void main (final String[] args) throws Exception { System.out.println(toString(mapFromRangeClosed(1, 6, i -> 1), formattingEntry(), "\n")); } public static <T> Map<Integer, T> mapFromRangeClosed(final int lo, final int hi, final Function<Integer, T> valueMapper) { return IntStream.rangeClosed(lo, hi).boxed().collect(Collectors.toMap(Function.identity(), valueMapper)); } public static <K,V> String toString(final Map<K, V> map, final Function<Map.Entry<K, V>, String> entryFormatter, final CharSequence delimiter) { return map.entrySet().stream().map(entryFormatter).collect(Collectors.joining(delimiter)); } public static <K,V> Function<Map.Entry<K, V>, String> formattingEntry() { return e -> e.getKey() + " " + e.getValue(); } }1 1 /* HashMap Example */ 2 2 3 3 import java.util.*; 4 - import java.lang.*; 5 - import java.io.*; 4 + import java.util.function.*; 5 + import java.util.stream.*; 6 6 7 - class HashMapDemo 8 - { 9 - public static void main (String[] args) throws java.lang.Exception { 10 - Map<Integer, Integer> map = new HashMap<Integer, Integer>() {{ 11 - put(1, 1); 12 - put(2, 1); 13 - put(3, 1); 14 - put(4, 1); 15 - put(5, 1); 16 - put(6, 1); 17 - }}; 18 - 19 - map.entrySet().stream().forEach(e -> System.out.println(e.getKey() + " " + e.getValue())); 7 + class HashMapDemo { 8 + public static void main (final String[] args) throws Exception { 9 + System.out.println(toString(mapFromRangeClosed(1, 6, i -> 1), formattingEntry(), "\n")); 10 + } 11 + 12 + public static <T> Map<Integer, T> mapFromRangeClosed(final int lo, final int hi, final Function<Integer, T> valueMapper) { 13 + return IntStream.rangeClosed(lo, hi).boxed().collect(Collectors.toMap(Function.identity(), valueMapper)); 14 + } 15 + 16 + public static <K,V> String toString(final Map<K, V> map, final Function<Map.Entry<K, V>, String> entryFormatter, final CharSequence delimiter) { 17 + return map.entrySet().stream().map(entryFormatter).collect(Collectors.joining(delimiter)); 18 + } 19 + 20 + public static <K,V> Function<Map.Entry<K, V>, String> formattingEntry() { 21 + return e -> e.getKey() + " " + e.getValue(); 20 20 } 21 21 }
import java.util.*; import org.junit.Before; import org.junit.Test; import org.junit.runners.JUnit4; import static org.junit.Assert.assertThat; import static org.hamcrest.CoreMatchers.is; public class MockTest { private Map<Integer, Integer> dummyMap; @Before public void setUp() { dummyMap = new HashMap<Integer, Integer>() {{ put(1, 1); put(2, 1); put(3, 1); put(4, 1); put(5, 1); put(6, 1); }}; } @Test public void testMapFromRangeClosed() { assertThat(HashMapDemo.mapFromRangeClosed(1, 6, i -> 1), is(dummyMap)); } @Test public void testForamttingEntry() { assertThat(HashMapDemo.formattingEntry().apply(new AbstractMap.SimpleEntry(123.45, "foo")), is("123.45 foo")); } @Test public void testToString() { assertThat(HashMapDemo.toString(dummyMap, e -> String.format("(%s -> %s)", e.getKey(), e.getValue()), ", "), is("(1 -> 1), (2 -> 1), (3 -> 1), (4 -> 1), (5 -> 1), (6 -> 1)")); } }1 + import java.util.*; 2 + 3 + import org.junit.Before; 1 1 import org.junit.Test; 2 - import static org.junit.Assert.assertEquals; 3 3 import org.junit.runners.JUnit4; 4 - import java.util.*; 6 + import static org.junit.Assert.assertThat; 5 5 8 + import static org.hamcrest.CoreMatchers.is; 6 6 7 - public class MockTest { 8 8 11 + public class MockTest { 12 + private Map<Integer, Integer> dummyMap; 13 + 14 + @Before 15 + public void setUp() { 16 + dummyMap = new HashMap<Integer, Integer>() {{ ... lines 17 to 21 have been collapsed. expand 17 + put(1, 1); 18 + put(2, 1); 19 + put(3, 1); 20 + put(4, 1); 21 + put(5, 1); 22 + put(6, 1); 23 + }}; 24 + } 25 + 9 9 @Test 10 - public void test() { 11 - assertEquals(1, 1); 12 - } 27 + public void testMapFromRangeClosed() { 28 + assertThat(HashMapDemo.mapFromRangeClosed(1, 6, i -> 1), is(dummyMap)); 29 + } 13 13 31 + @Test 32 + public void testForamttingEntry() { 33 + assertThat(HashMapDemo.formattingEntry().apply(new AbstractMap.SimpleEntry(123.45, "foo")), 34 + is("123.45 foo")); 35 + } 14 14 37 + @Test 38 + public void testToString() { 39 + assertThat(HashMapDemo.toString(dummyMap, e -> String.format("(%s -> %s)", e.getKey(), e.getValue()), ", "), 40 + is("(1 -> 1), (2 -> 1), (3 -> 1), (4 -> 1), (5 -> 1), (6 -> 1)")); 41 + } 15 15 }
import java.util.Map; import java.util.function.Function; import java.util.stream.Collectors; import java.util.stream.IntStream; /** Time Complexity : O(N) Space Complexity : O(N) */ class MaxOccurence { public static int findMax(final int[] nums) { return IntStream.of(nums).boxed() .collect(Collectors.groupingBy(Function.identity(), Collectors.counting())) .entrySet().stream() .max(Map.Entry.comparingByValue()) .map(Map.Entry::getKey).orElse(-1); } }1 - import java.util.*; 2 - import java.util.List; 3 3 import java.util.Map; 4 - import java.util.Optional; 2 + import java.util.function.Function; 5 5 import java.util.stream.Collectors; 6 6 import java.util.stream.IntStream; 7 7 8 8 /** 9 9 Time Complexity : O(N) 10 10 Space Complexity : O(N) 11 11 */ 12 12 class MaxOccurence { 13 - 14 - public static int findMax(int[] nums) { 15 - Optional<Map.Entry<Integer, List<Integer>>> max = IntStream.of(nums) 16 - .boxed() 17 - .collect(Collectors.groupingBy(num -> num)) ... lines 18 to 22 have been collapsed. expand 18 - .entrySet() 19 - .stream() 20 - .max((e1, e2) -> e1.getValue().size() - e2.getValue().size()); 21 - 22 - return max.isPresent() ? max.get().getKey() : -1; 11 + 12 + public static int findMax(final int[] nums) { 13 + return IntStream.of(nums).boxed() 14 + .collect(Collectors.groupingBy(Function.identity(), Collectors.counting())) 15 + .entrySet().stream() 16 + .max(Map.Entry.comparingByValue()) 17 + .map(Map.Entry::getKey).orElse(-1); 23 23 } 24 24 }
import java.util.*; import java.util.stream.*; class Solution { public static int retSmallestPositiveInteger() { return IntStream.iterate(1, x -> x + 1).filter(Solution::hasSameDigitsForFactorsInRange).findFirst().getAsInt(); } private static boolean hasSameDigitsForFactorsInRange(final int x) { final Map<Integer, Integer> xDigits = digitsOf(x); return IntStream.rangeClosed(2, 6).allMatch(f -> xDigits.equals(digitsOf(x * f))); } private static Map<Integer, Integer> digitsOf(final int number) { return String.valueOf(number).chars().map(Character::getNumericValue) .collect(HashMap<Integer, Integer>::new, (m, x) -> m.put(x, m.getOrDefault(x, 0) + 1), HashMap::putAll); } }1 1 import java.util.*; 2 + import java.util.stream.*; 3 + 2 2 class Solution { 5 + 6 + public static int retSmallestPositiveInteger() { 7 + return IntStream.iterate(1, x -> x + 1).filter(Solution::hasSameDigitsForFactorsInRange).findFirst().getAsInt(); 8 + } 3 3 4 - 5 - public static int retSmallestPositiveInteger() { 6 - for(int i=1; ; i++) { 7 - if(hasSameDigits(i, i*2) && hasSameDigits(i, i*3) && hasSameDigits(i, i*4) && hasSameDigits(i, i*5) && hasSameDigits(i, i*6)) 8 - return i; 9 - } 10 - } 10 + private static boolean hasSameDigitsForFactorsInRange(final int x) { 11 + final Map<Integer, Integer> xDigits = digitsOf(x); 12 + return IntStream.rangeClosed(2, 6).allMatch(f -> xDigits.equals(digitsOf(x * f))); 13 + } 11 11 12 - private static boolean hasSameDigits(int x, int y) { 13 - char[] xdigits = Integer.toString(x).toCharArray(); 14 - char[] ydigits = Integer.toString(y).toCharArray(); 15 - Arrays.sort(xdigits); 16 - Arrays.sort(ydigits); 17 - return Arrays.equals(xdigits, ydigits); 18 - } 15 + private static Map<Integer, Integer> digitsOf(final int number) { 16 + return String.valueOf(number).chars().map(Character::getNumericValue) 17 + .collect(HashMap<Integer, Integer>::new, 18 + (m, x) -> m.put(x, m.getOrDefault(x, 0) + 1), 19 + HashMap::putAll); 20 + } 19 19 }
import org.junit.Test; import static org.junit.Assert.assertEquals; import org.junit.runners.JUnit4; public class SolutionTest { @Test public void testSolution() { assertEquals(142857, new Solution().retSmallestPositiveInteger()); } }1 1 import org.junit.Test; 2 2 import static org.junit.Assert.assertEquals; 3 3 import org.junit.runners.JUnit4; 4 4 5 - // TODO: Replace examples and use TDD development by writing your own tests 6 - 7 7 public class SolutionTest { 8 8 @Test 9 9 public void testSolution() { 10 10 assertEquals(142857, new Solution().retSmallestPositiveInteger()); 11 11 } 12 12 }
public class Primes { public static boolean isAPrime(int number) { if (number < 2 || (number % 2 == 0 && number != 2)) return false; for (int i = 3; i*i <= number; i += 2) { if (number % i == 0) return false; } return true; } }1 1 public class Primes { 2 2 public static boolean isAPrime(int number) { 3 - if(number > 1 && number == 2) return true; //1 is not a prime number by definition 4 - else { 5 - for(int i = 3; i*i < number; i +=2) { 6 - if (number % i == 0) return false; 7 - } 3 + if (number < 2 || (number % 2 == 0 && number != 2)) return false; 4 + for (int i = 3; i*i <= number; i += 2) { 5 + if (number % i == 0) return false; 8 8 } 9 9 return true; 10 10 } 11 11 }
import org.junit.Test; import static org.junit.Assert.assertEquals; import org.junit.runners.JUnit4; import java.util.Random; public class SolutionTest { private static final Random RANDOM = new Random(); @Test public void twoShouldBeAPrime() { int numberToCheck = 2; boolean expected = true; boolean actual = Primes.isAPrime(numberToCheck); assertEquals(expected, actual); } @Test public void fortySevenShouldBeAPrime() { int numberToCheck = 47; boolean expected = true; boolean actual = Primes.isAPrime(numberToCheck); assertEquals(expected, actual); } @Test public void nineShouldNotBeAPrime() { int numberToCheck = 9; boolean expected = false; boolean actual = Primes.isAPrime(numberToCheck); assertEquals(expected, actual); } @Test public void n123ShouldNotBeAPrime() { int numberToCheck = 123; boolean expected = false; boolean actual = Primes.isAPrime(numberToCheck); assertEquals(expected, actual); } @Test public void n91ShouldNotBeAPrime() { int numberToCheck = 91; boolean expected = false; boolean actual = Primes.isAPrime(numberToCheck); assertEquals(expected, actual); } @Test public void n17977ShouldBeAPrime() { int numberToCheck = 17977; boolean expected = true; boolean actual = Primes.isAPrime(numberToCheck); assertEquals(expected, actual); } // better tests from @spacebison @Test public void fourShouldNotBeAPrime() { testPrime(4, false); } @Test public void aSquareShouldNotAPrime() { for (int i = 0; i < 10000; ++i) { int randomNumber = RANDOM.nextInt(Short.MAX_VALUE) + 2; int numberToCheck = randomNumber * randomNumber; testPrime(numberToCheck, false); } } @Test public void aProductOfTwoIntegersShouldNotBeAPrime() { for (int i = 0; i < 100000; ++i) { int a = RANDOM.nextInt(Short.MAX_VALUE) + 2; int b = RANDOM.nextInt(Short.MAX_VALUE) + 2; int numberToCheck = a * b; testPrime(numberToCheck, false); } } private static void testPrime(int numberToCheck, boolean expected) { boolean actual = Primes.isAPrime(numberToCheck); assertEquals(Integer.toString(numberToCheck), expected, actual); } }1 1 import org.junit.Test; 2 2 import static org.junit.Assert.assertEquals; 3 3 import org.junit.runners.JUnit4; 4 + import java.util.Random; 4 4 5 5 public class SolutionTest { 7 + private static final Random RANDOM = new Random(); 8 + 9 + 6 6 @Test 7 7 public void twoShouldBeAPrime() { 8 8 int numberToCheck = 2; 9 9 10 10 boolean expected = true; 11 11 boolean actual = Primes.isAPrime(numberToCheck); 12 12 13 13 assertEquals(expected, actual); 14 14 } 15 15 16 - @Test 20 + @Test 17 17 public void fortySevenShouldBeAPrime() { 18 18 int numberToCheck = 47; 19 19 20 20 boolean expected = true; 21 21 boolean actual = Primes.isAPrime(numberToCheck); 22 22 23 23 assertEquals(expected, actual); 24 24 } 29 + 30 + @Test 31 + public void nineShouldNotBeAPrime() { 32 + int numberToCheck = 9; 33 + 34 + boolean expected = false; 35 + boolean actual = Primes.isAPrime(numberToCheck); 36 + 37 + assertEquals(expected, actual); 38 + } 39 + 40 + @Test 41 + public void n123ShouldNotBeAPrime() { 42 + int numberToCheck = 123; 43 + 44 + boolean expected = false; 45 + boolean actual = Primes.isAPrime(numberToCheck); 46 + 47 + assertEquals(expected, actual); 48 + } 49 + 50 + @Test 51 + public void n91ShouldNotBeAPrime() { 52 + int numberToCheck = 91; 53 + 54 + boolean expected = false; 55 + boolean actual = Primes.isAPrime(numberToCheck); 56 + 57 + assertEquals(expected, actual); 58 + } 59 + 60 + @Test 61 + public void n17977ShouldBeAPrime() { 62 + int numberToCheck = 17977; 63 + 64 + boolean expected = true; 65 + boolean actual = Primes.isAPrime(numberToCheck); 66 + 67 + assertEquals(expected, actual); 68 + } 69 + 70 + // better tests from @spacebison 71 + @Test 72 + public void fourShouldNotBeAPrime() { 73 + testPrime(4, false); 74 + } 75 + 76 + @Test 77 + public void aSquareShouldNotAPrime() { 78 + for (int i = 0; i < 10000; ++i) { 79 + int randomNumber = RANDOM.nextInt(Short.MAX_VALUE) + 2; 80 + int numberToCheck = randomNumber * randomNumber; 81 + testPrime(numberToCheck, false); 82 + } 83 + } 84 + 85 + @Test 86 + public void aProductOfTwoIntegersShouldNotBeAPrime() { 87 + for (int i = 0; i < 100000; ++i) { 88 + int a = RANDOM.nextInt(Short.MAX_VALUE) + 2; 89 + int b = RANDOM.nextInt(Short.MAX_VALUE) + 2; 90 + int numberToCheck = a * b; 91 + testPrime(numberToCheck, false); 92 + } 93 + } 94 + 95 + private static void testPrime(int numberToCheck, boolean expected) { 96 + boolean actual = Primes.isAPrime(numberToCheck); 97 + assertEquals(Integer.toString(numberToCheck), expected, actual); 98 + } 99 + 25 25 }
class Node:
def __init__(self,x,Next, Prev):
self.data = x
self.next = Next
self.prev = Prev
class LinkedList:
def __init__(self, *x):
self.start = None
self.last = None
self.lenght = 0
if x:
for i in x:
self.add(i)
def __str__(self):
if self.start != None:
current = self.start
out = '[ ' + str(current.data)
while current.next != None:
current = current.next
out += ' '+ str(current.data)
out += ' ]'
return out
def clear(self):
self.__init__()
def add(self, x):
if self.start == None:
self.start = self.last = Node(x,None,None)
self.lenght += 1
else:
prev = self.last
self.last.next = self.last = Node(x,None,None)
self.last.prev = prev
self.lenght += 1
def addFew(self,*x):
if x:
for i in x:
self.add(i)
def remove(self, x,remove_all = False):
current = self.start
for i in range(self.lenght):
if current.data == x:
if current.prev == None:
if current.next != None:
self.start = current.next
current.next.prev = None
self.lenght -= 1
if current.next == None:
if current.prev != None:
current.prev.next = None
self.last = current.prev
self.last.next = None
self.lenght -= 1
if current.prev != None and current.next != None:
current.prev.next = current.next
current.next.prev = current.prev
self.lenght -= 1
if current.next == None and current.prev == None:
clear(self)
self.lenght -= 0
if remove_all == False:
break
current = current.next# TODO: Replace examples and use TDD development by writing your own tests
# These are some of the methods available:
# test.expect(boolean, [optional] message)
# test.assert_equals(actual, expected, [optional] message)
# test.assert_not_equals(actual, expected, [optional] message)
# You can use Test.describe and Test.it to write BDD style test groupings
test.assert_equals(LinkedList(1,2,3,4,5).lenght, 5)def binary_search(lst,item):
low = 0
high = len(lst) - 1
while low <= high:
mid = int((high + low)/2)
guess = lst[mid]
print (guess,mid)
if guess > item:
high = mid - 1
if guess < item:
low = mid + 1
if guess == item:
return mid
else:
return None# TODO: Replace examples and use TDD development by writing your own tests
# These are some of the methods available:
# test.expect(boolean, [optional] message)
# test.assert_equals(actual, expected, [optional] message)
# test.assert_not_equals(actual, expected, [optional] message)
# You can use Test.describe and Test.it to write BDD style test groupings
test.assert_equals(binary_search([1,2,3,4,5],2), 1)
test.assert_equals(binary_search([1,2,3,4,5],10), None)
test.assert_equals(binary_search([1,2,3,4,5],2), 1)
test.assert_equals(binary_search([0, 1, 2, 3, 4, 5, 6, 7, 8, 9],9), 9)
test.assert_equals(binary_search([0, 1, 2, 3, 4, 5, 6, 7, 8, 9],100), None)Changing "if n % i == 0" on line 6 to "if not(n % i)" made the time drop from 4126ms to 3810ms (as the longest time).
from math import sqrt, floor def divisors(n): fact = []; for i in range(1, int(floor(sqrt(n))) + 1): if not(n % i): fact.append(i) if n / i != i: fact.append(n / i) fact.sort() return fact1 1 from math import sqrt, floor 2 2 3 3 def divisors(n): 4 4 fact = []; 5 5 for i in range(1, int(floor(sqrt(n))) + 1): 6 - if n % i == 0: 6 + if not(n % i): 7 7 fact.append(i) 8 8 if n / i != i: 9 9 fact.append(n / i) 10 10 fact.sort() 11 11 return fact
from math import sqrt, floor def divisors_check(n): fact = []; for i in range(1, int(floor(sqrt(n))) + 1): if not(n % i): fact.append(i) if n / i != i: fact.append(n / i) fact.sort() return fact test.describe( "Static Cases" ) test.it( "n = 200" ) test.assert_equals(divisors(200), [1, 2, 4, 5, 8, 10, 20, 25, 40, 50, 100, 200]) test.it( "n = 560") test.assert_equals(divisors(560), [1, 2, 4, 5, 7, 8, 10, 14, 16, 20, 28, 35, 40, 56, 70, 80, 112, 140, 280, 560]) test.it("n = 755") test.assert_equals(divisors(755), [1, 5, 151, 755]) from random import randint test.describe( "Random Tests") test.it ("More than 1000 Random Tests with challenging values up to 1000000000(10e9)") for h in range(0,1000): n = randint(1000, 1000000000) result = divisors_check(n) res = divisors(n) test.it("Testing for = " + str(n)) test.assert_equals(res, result)1 1 from math import sqrt, floor 2 2 3 3 def divisors_check(n): 4 4 fact = []; 5 5 for i in range(1, int(floor(sqrt(n))) + 1): 6 - if n % i == 0: 6 + if not(n % i): 7 7 fact.append(i) 8 8 if n / i != i: 9 9 fact.append(n / i) 10 10 fact.sort() 11 11 return fact ... lines 12 to 35 have been collapsed. expand 12 12 13 13 14 14 test.describe( "Static Cases" ) 15 15 16 16 test.it( "n = 200" ) 17 17 test.assert_equals(divisors(200), [1, 2, 4, 5, 8, 10, 20, 25, 40, 50, 100, 200]) 18 18 19 19 test.it( "n = 560") 20 20 test.assert_equals(divisors(560), [1, 2, 4, 5, 7, 8, 10, 14, 16, 20, 28, 35, 40, 56, 70, 80, 112, 140, 280, 560]) 21 21 22 22 test.it("n = 755") 23 23 test.assert_equals(divisors(755), [1, 5, 151, 755]) 24 24 25 25 from random import randint 26 26 27 27 test.describe( "Random Tests") 28 28 test.it ("More than 1000 Random Tests with challenging values up to 1000000000(10e9)") 29 29 for h in range(0,1000): 30 30 n = randint(1000, 1000000000) 31 31 result = divisors_check(n) 32 32 res = divisors(n) 33 33 test.it("Testing for = " + str(n)) 34 34 test.assert_equals(res, result) 35 35
Fundamentals
Lists
Data Structures
Functional Programming
Declarative Programming
That's good
/**
* Created by ice1000 on 2017/4/27.
*
* @author ice1000
*/
fun <A, B, C : Any> zipWith(op: (A, B) -> C) = { x: Sequence<A> ->
{ y: Sequence<B> ->
val iX = x.iterator()
val iY = y.iterator()
generateSequence {
if (iX.hasNext() and iY.hasNext()) op(iX.next(), iY.next())
else null
}
}
}
fun <T : Any> generate() = zipWith { x: Int, y: T -> "[$y * x^$x]" } (
generateSequence(0, Int::inc)
)
fun main(args: Array<String>) =
generate<Int>()(sequenceOf(1, 1, 2, 3, 5, 8, 13, 21)).forEach(::println)Quick implementation of splitter algorithm with use of regular expressions.
Probably could be done better if offset characters would be cut off & added to result array rather than adding some random chars to _str and removing them right before returning result.
Also instead of using regexp straightforward for-loop can make it better - because of lack of positive lookbehind in js rexegp implementations results are not always OK (problem with strings which length is not divisible by _n).
function splitter (_str, _n) { _n = parseInt(_n); var offset = _n - _str.length % _n; if (offset !== _n) { _str += Math.pow(10, offset - 1); } var result = _str.split(new RegExp('(?=(?:.{' + _n + '})+$)', 'g')); if (offset !== _n) { var len = result.length, lastGroup = result[len - 1]; result[len - 1] = lastGroup.substring(0, lastGroup.length - offset); } return result; }1 - console.log( 2 - '123456'.split('') 3 - ); 1 + function splitter (_str, _n) { 2 + _n = parseInt(_n); 3 + 4 + var offset = _n - _str.length % _n; 5 + 6 + if (offset !== _n) { 7 + _str += Math.pow(10, offset - 1); 8 + } 9 + 10 + var result = _str.split(new RegExp('(?=(?:.{' + _n + '})+$)', 'g')); 11 + 12 + if (offset !== _n) { 13 + var len = result.length, 14 + lastGroup = result[len - 1]; 15 + 16 + result[len - 1] = lastGroup.substring(0, lastGroup.length - offset); 17 + } 18 + 19 + return result; 20 + }
var testString = '1234567890'; describe("Solution", function(){ it("should take number as second argument", function(){ Test.assertSimilar(splitter(testString, 2), ['12', '34', '56', '78', '90'], 'Split into 2-character group with use of numeric argument.'); Test.assertSimilar(splitter(testString, 3), ['123', '456', '789', '0'], 'Split into 3-character group with use of numeric argument.'); Test.assertSimilar(splitter(testString, 4), ['1234', '5678', '90'], 'Split into 4-character group with use of numeric argument.'); }); it("should take string as second argument", function(){ Test.assertSimilar(splitter(testString, '2'), ['12', '34', '56', '78', '90'], 'Split into 2-character group with use of string argument.'); Test.assertSimilar(splitter(testString, '3'), ['123', '456', '789', '0'], 'Split into 3-character group with use of string argument.'); Test.assertSimilar(splitter(testString, '4'), ['1234', '5678', '90'], 'Split into 4-character group with use of string argument.'); }); });1 - // TODO: Replace examples and use TDD development by writing your own tests 2 - 3 - // These are some CW specific test methods available: 4 - // Test.expect(boolean, [optional] message) 5 - // Test.assertEquals(actual, expected, [optional] message) 6 - // Test.assertSimilar(actual, expected, [optional] message) 7 - // Test.assertNotEquals(actual, expected, [optional] message) 8 - 9 - // NodeJS assert is also automatically required for you. 10 - // assert(true) 11 - // assert.strictEqual({a: 1}, {a: 1}) 12 - // assert.deepEqual({a: [{b: 1}]}, {a: [{b: 1}]}) 13 - 14 - // You can also use Chai (http://chaijs.com/) by requiring it yourself 15 - // var expect = require("chai").expect; 16 - // var assert = require("chai").assert; 17 - // require("chai").should(); 1 + var testString = '1234567890'; 18 18 19 19 describe("Solution", function(){ 20 - it("should test for something", function(){ 21 - Test.assertEquals("actual", "actual", "This is just an example of how you can write your own TDD tests"); 4 + it("should take number as second argument", function(){ 5 + Test.assertSimilar(splitter(testString, 2), ['12', '34', '56', '78', '90'], 'Split into 2-character group with use of numeric argument.'); 6 + Test.assertSimilar(splitter(testString, 3), ['123', '456', '789', '0'], 'Split into 3-character group with use of numeric argument.'); 7 + Test.assertSimilar(splitter(testString, 4), ['1234', '5678', '90'], 'Split into 4-character group with use of numeric argument.'); 8 + }); 9 + 10 + it("should take string as second argument", function(){ 11 + Test.assertSimilar(splitter(testString, '2'), ['12', '34', '56', '78', '90'], 'Split into 2-character group with use of string argument.'); 12 + Test.assertSimilar(splitter(testString, '3'), ['123', '456', '789', '0'], 'Split into 3-character group with use of string argument.'); 13 + Test.assertSimilar(splitter(testString, '4'), ['1234', '5678', '90'], 'Split into 4-character group with use of string argument.'); 22 22 }); 23 23 });
ES2015
Babel
Objects
Robert.Cutright's implementation was great. (underscore.js has this function called omit http://underscorejs.org/#omit)
I forked his code and modified two parts.
First, I reused _.pick.
Second, I use reduce instead of assing and filter. Because reduce is more useful and simple solution to get result that I want.
var _ = {}; // Joeun's Pick implementation (GREAT JOB!) _.pick = (target, ...keys) => { if (typeof keys[0] == 'function') { var predicate = keys[0]; keys = Object.keys(target); return keys.reduce((obj, key) => { return predicate(target[key], key, target) ? (obj[key] = target[key], obj) : obj; }, {}) } return keys.reduce((obj, key) => { return obj[key] = target[key], obj; }, {}); }; // Robert.Cutright's implementation of the inverse of pick (called flick); // In other words, you supply the keys you want to throw away. _.flick = (target, ...keys) => { if (typeof keys[0] == 'function') { var predicate = keys[0]; keys = Object.keys(target); return keys.reduce((obj, key) => { return predicate(target[key], key, target) ? obj : (obj[key] = target[key], obj); }, {}) } var obj = Object.assign({}, target); Object.keys(obj).filter(key => keys.includes(key) ? delete obj[key] : obj[key]); return obj; }; // Joeun's flick (called flick2) _.flick2 = (target, ...keys) => { if (typeof keys[0] == 'function') { var predicate = keys[0]; return _.pick(target, (...args) => !predicate(...args)) // first part } var target_keys = Object.keys(target); // second part return target_keys.reduce((obj, key) => { return keys.includes(key) ? obj : (obj[key] = target[key], obj); }, {}); };... lines 1 to 30 have been collapsed. expand 1 1 var _ = {}; 2 2 3 3 // Joeun's Pick implementation (GREAT JOB!) 4 4 _.pick = (target, ...keys) => { 5 5 if (typeof keys[0] == 'function') { 6 6 7 7 var predicate = keys[0]; 8 8 keys = Object.keys(target); 9 9 10 10 return keys.reduce((obj, key) => { 11 11 return predicate(target[key], key, target) ? (obj[key] = target[key], obj) : obj; 12 12 }, {}) 13 13 } 14 14 15 15 return keys.reduce((obj, key) => { 16 16 return obj[key] = target[key], obj; 17 17 }, {}); 18 18 }; 19 19 20 20 // Robert.Cutright's implementation of the inverse of pick (called flick); 21 21 // In other words, you supply the keys you want to throw away. 22 22 _.flick = (target, ...keys) => { 23 23 if (typeof keys[0] == 'function') { 24 24 25 25 var predicate = keys[0]; 26 26 keys = Object.keys(target); 27 27 28 28 return keys.reduce((obj, key) => { 29 29 return predicate(target[key], key, target) ? obj : (obj[key] = target[key], obj); 30 30 }, {}) 31 31 } 32 32 33 33 var obj = Object.assign({}, target); 34 34 Object.keys(obj).filter(key => keys.includes(key) ? delete obj[key] : obj[key]); 35 35 return obj; 36 36 }; 37 + 38 + // Joeun's flick (called flick2) 39 + _.flick2 = (target, ...keys) => { 40 + if (typeof keys[0] == 'function') { 41 + var predicate = keys[0]; 42 + return _.pick(target, (...args) => !predicate(...args)) // first part 43 + } 44 + 45 + var target_keys = Object.keys(target); // second part 46 + return target_keys.reduce((obj, key) => { 47 + return keys.includes(key) ? obj : (obj[key] = target[key], obj); 48 + }, {}); 49 + };
var result; var testObj = {name: 'moe', age: 50, userid: 'moe1'}; // _.pick Tests result = _.pick(testObj, 'name', 'age'); Test.assertSimilar(result, {name: 'moe', age: 50}); result = _.pick(testObj, function(value, key, object) { return typeof value == 'number'; }); Test.assertSimilar(result, {age: 50}); // _.flick Tests result = _.flick(testObj, 'name', 'age'); Test.assertSimilar(result, {userid: 'moe1'}); result = _.flick(testObj, function(value, key, object) { return typeof value == 'number'; }); Test.assertSimilar(result, {name: 'moe', userid: 'moe1'}); // _.flick2 Tests result = _.flick2(testObj, 'name', 'age'); Test.assertSimilar(result, {userid: 'moe1'}); result = _.flick2(testObj, function(value, key, object) { return typeof value == 'number'; }); Test.assertSimilar(result, {name: 'moe', userid: 'moe1'});... lines 1 to 14 have been collapsed. expand 1 1 var result; 2 2 var testObj = {name: 'moe', age: 50, userid: 'moe1'}; 3 3 4 4 // _.pick Tests 5 5 result = _.pick(testObj, 'name', 'age'); 6 6 Test.assertSimilar(result, {name: 'moe', age: 50}); 7 7 8 8 result = _.pick(testObj, function(value, key, object) { 9 9 return typeof value == 'number'; 10 10 }); 11 11 Test.assertSimilar(result, {age: 50}); 12 12 13 13 // _.flick Tests 14 14 result = _.flick(testObj, 'name', 'age'); 15 15 Test.assertSimilar(result, {userid: 'moe1'}); 16 16 17 17 result = _.flick(testObj, function(value, key, object) { 18 18 return typeof value == 'number'; 19 19 }); 20 20 Test.assertSimilar(result, {name: 'moe', userid: 'moe1'}); 21 + 22 + // _.flick2 Tests 23 + result = _.flick2(testObj, 'name', 'age'); 24 + Test.assertSimilar(result, {userid: 'moe1'}); 25 + 26 + result = _.flick2(testObj, function(value, key, object) { 27 + return typeof value == 'number'; 28 + }); 29 + Test.assertSimilar(result, {name: 'moe', userid: 'moe1'});
An implementation of the Sieve of Eratosthenes for finding prime numbers, fully focusing on performance.
The biggest performance gains come from forcing data set manipluation loops to be performed in the C-level code inside Python and not inside loops within the source code of the sieve. The places where this is used in particular are:
- Striking out compounds in the sieve using the list[start::skip] = list syntax
- Creating the final list of primes by using compress() to filter primes from the sieve
from math import sqrt, ceil
from itertools import compress
def sieve(until):
if until < 2:
return []
store_len = until >> 1
is_prime = [True] * store_len
for offset, number in enumerate(range(3, int(sqrt(until)) + 1, 2)):
if is_prime[offset]:
first_compound_at = (number*number-3) >> 1
nr_of_compounds = int(ceil((store_len-first_compound_at) / number))
is_prime[first_compound_at::number] = [False] * nr_of_compounds
return [2] + list(compress(range(3, until + 1, 2), is_prime))from time import time
Test.describe("Below 2, no primes exist")
Test.assert_equals([], sieve(-1))
Test.assert_equals([], sieve(0))
Test.assert_equals([], sieve(1))
Test.describe("Low primes")
Test.assert_equals([2], sieve(2))
Test.assert_equals([2,3], sieve(3))
Test.assert_equals([2,3], sieve(4))
Test.assert_equals([2,3,5], sieve(5))
Test.assert_equals([2,3,5], sieve(6))
Test.assert_equals([2,3,5,7], sieve(7))
Test.assert_equals([2,3,5,7], sieve(8))
Test.assert_equals([2,3,5,7], sieve(9))
Test.assert_equals([2,3,5,7], sieve(10))
Test.assert_equals([2,3,5,7,11], sieve(11))
Test.assert_equals([2,3,5,7,11], sieve(12))
Test.assert_equals([2,3,5,7,11,13], sieve(13))
Test.describe("A big sieve")
t1 = time()
s = set(sieve(50000000))
t2 = time()
print("The big sieve until 50,000,000 was created in", t2-t1, "seconds")
Test.assert_equals(3001134, len(s), "The sieve must contain 3001134 primes")
# On codewars, I get timings around 2 seconds, but lets give the timing some slack here.
Test.expect(t2-t1 < 5, "The sieve must be created within 5 seconds")
some_primes = {2, 3, 131, 4700939, 11833931, 15418759, 19818061, 25227973, 36341861, 44811667, 49999991}
Test.expect(some_primes.issubset(s))Algorithms
This is my implementation of the Baillie-PSW prime number test. It is my response to a kumite title that claimed a fast prime test, while the implemented check was not actually that fast.
The response as provided by the isPrime() function is not simply a boolean, but instead a tuple providing two values: a boolean indicating probably primality and a string describing the test to lead to the provided conclusing.
Knowing the actual test that triggered the outcome has proven a very valuable tool during development. If this were production code, I'd most likely make the isPrime() function return a boolean directly.
It was great fun to puzzle together all the required pieces and to translate mathmatical notation into working programming code! I learned a lot of new things about modular arithmatics.
from math import sqrt, ceil from itertools import compress TRIAL_DIVISION_UNTIL=1000 def isPrime(n): """This primality check implements the composite Baillie-PSW test. See: https://en.wikipedia.org/wiki/Baillie%E2%80%93PSW_primality_test Input: n: the number to check Output: a tuple containing two elements: - True if (probable) prime, False otherwise - The name of the test that lead to that conclusion """ if not isInteger(n): return (False, "not an integer") if isBelowLowestPrime(n): return (False, "below lowest prime") if isLowPrime(n): return (True, "low prime") if isTrialDivisionCompound(n): return (False, "trial division") if not isRabinMillerProbablePrime(n): return (False, "rabin-miller") if isPerfectSquare(n): return (False, "perfect square") if not isLucasProbablePrime(n): return (False, "lucas") return (True, "passed all tests") def isInteger(n): return int(n) == n def isBelowLowestPrime(n): return n < 2 def isLowPrime(n): return ( n <= TRIAL_DIVISION_UNTIL and n in lowPrimes ) def isTrialDivisionCompound(n): return any( n % prime == 0 for prime in lowPrimes if prime < n ) def isRabinMillerProbablePrime(n): """Based on pseudo code for the Rabin-Miller algorithm. See: https://en.wikipedia.org/wiki/Miller-Rabin_primality_test This simple version implements only a single pass using base 2, as prescribed by the Baillie-PSW specification.""" (factor, exponent) = factorizeBase2(n - 1) x = pow(2, factor, n) if x == 1 or x == n - 1: return True for _ in range(exponent - 1): x = pow(x, 2, n) if x == 1: return False elif x == n - 1: return True return False def isPerfectSquare(n): """A quick check to make sure that no perfect squares are fed to the Lucas probable prime check.""" return isqrt(n) ** 2 == n def isqrt(n): """Integer square root, see: https://en.wikipedia.org/wiki/Integer_square_root""" x = n y = (x + 1) >> 1 while y < x: x = y y = (x + n // x) >> 1 return x def isLucasProbablePrime(n): """Code based on "Implementing a Lucas probable prime test" to be found at: https://en.wikipedia.org/wiki/Lucas_pseudoprime""" def getLucasSequenceInputAsSuggestedBySelfridge(): seq = ((-1 if i&1 else 1) * (i*2 + 5) for i in range(0, n>>1)) D = next((D for D in seq if jacobi(D, n) == -1)) Q = (1 - D) // 4 P = 1 return D, Q, P D, Q, P = getLucasSequenceInputAsSuggestedBySelfridge() def computeLucasValue(subscript): U = V = k = 0 for digit in format(subscript, "b"): U, V, k = doubleK(U, V, k) if digit == "1": U, V, k = incrementK(U, V, k) return U, V, subscript def doubleK(U, V, subscript): return (U*V) % n, (pow(V, 2, n) - 2 * pow(Q, subscript, n)) % n, subscript << 1 def incrementK(U, V, subscript): U, V = (P*U + V), (D*U + P*V) makeEven = lambda x: x+n if x&1 else x div2modn = lambda x: (x >> 1) % n return (div2modn(makeEven(U)), div2modn(makeEven(V)), subscript+1) # Weak check. U, V, k = computeLucasValue(n+1) if U != 0: return False # Strong check. (factor, exponent) = factorizeBase2(n + 1) U, V, k = computeLucasValue(factor) if U == 0 or V == 0: return True for r in range(exponent-1): U, V, k = doubleK(U, V, k) if V == 0: return True def factorizeBase2(factor, exponent=0): """Factor out 2 from a number. For example factorizeBase2(80) returns (5, 4), which indicates that 2 ** 5 + 4 == 80.""" if factor&1: return (factor, exponent) return factorizeBase2(factor >> 1, exponent + 1) def jacobi(a, n): """Compute the Jacobi symbol. The code uses ideas from: https://www.academia.edu/1012630/A_binary_algorithm_for_the_Jacobi_symbol""" t = 1 while a: if a < 0: a = -a if n&3 == 3: t = -t while not a&1: a = a >> 1 if n&7 == 3 or n&7 == 5: t = -t if (a < n): a, n = n, a if a&3 == 3 and n&3 == 3: t = -t a = (a - n) >> 1 if n&7 == 3 or n&7 == 5: t = -t return t if n == 1 else 0 def sieve(until): """This is an optimized sieve-algorithm that I created for an exercism.io assignment. On my system, it is able to produce primes until 10,000,000 in half a second. See: http://exercism.io/submissions/a6085623b76a6747d300420e""" if until < 2: return [] store_len = until >> 1 is_prime = [True] * store_len for offset, number in enumerate(range(3, int(sqrt(until)) + 1, 2)): if is_prime[offset]: first_compound_at = (number*number-3) >> 1 nr_of_compounds = int(ceil((store_len-first_compound_at) / number)) is_prime[first_compound_at::number] = [False] * nr_of_compounds return [2] + list(compress(range(3, until + 1, 2), is_prime)) lowPrimes = set(sieve(TRIAL_DIVISION_UNTIL))1 - import math 2 - def isprime(num): 3 - if num<2 or int(num)!=num: return False 4 - if not num%2 and num>2: return False 5 - for n in range(3,math.ceil((num-1)**.5)+1,2): 6 - if not num%n: 7 - return False 8 - return True 1 + from math import sqrt, ceil 2 + from itertools import compress 3 + 4 + TRIAL_DIVISION_UNTIL=1000 5 + 6 + 7 + def isPrime(n): 8 + """This primality check implements the composite Baillie-PSW test. 9 + See: https://en.wikipedia.org/wiki/Baillie%E2%80%93PSW_primality_test 10 + 11 + Input: 12 + n: the number to check 13 + Output: 14 + a tuple containing two elements: 15 + - True if (probable) prime, False otherwise 16 + - The name of the test that lead to that conclusion 17 + """ 18 + if not isInteger(n): 19 + return (False, "not an integer") 20 + if isBelowLowestPrime(n): 21 + return (False, "below lowest prime") 22 + if isLowPrime(n): 23 + return (True, "low prime") 24 + if isTrialDivisionCompound(n): 25 + return (False, "trial division") 26 + if not isRabinMillerProbablePrime(n): 27 + return (False, "rabin-miller") 28 + if isPerfectSquare(n): 29 + return (False, "perfect square") 30 + if not isLucasProbablePrime(n): 31 + return (False, "lucas") 32 + return (True, "passed all tests") 33 + 34 + 35 + def isInteger(n): 36 + return int(n) == n 37 + 38 + 39 + def isBelowLowestPrime(n): 40 + return n < 2 41 + 42 + 43 + def isLowPrime(n): 44 + return ( 45 + n <= TRIAL_DIVISION_UNTIL and 46 + n in lowPrimes 47 + ) 48 + 49 + 50 + def isTrialDivisionCompound(n): 51 + return any( 52 + n % prime == 0 53 + for prime in lowPrimes 54 + if prime < n 55 + ) 56 + 57 + 58 + def isRabinMillerProbablePrime(n): 59 + """Based on pseudo code for the Rabin-Miller algorithm. 60 + See: https://en.wikipedia.org/wiki/Miller-Rabin_primality_test 61 + This simple version implements only a single pass using base 2, 62 + as prescribed by the Baillie-PSW specification.""" 63 + (factor, exponent) = factorizeBase2(n - 1) 64 + x = pow(2, factor, n) 65 + if x == 1 or x == n - 1: 66 + return True 67 + for _ in range(exponent - 1): 68 + x = pow(x, 2, n) 69 + if x == 1: 70 + return False 71 + elif x == n - 1: 72 + return True 73