?
from datetime import datetime def password(p): a = datetime.now() if not p.isdigit(): return "Please, don't print letters.\nReset the program." return "ACCESS CONFIRMED" if p == f"{a.hour}{a.minute}" else "ACCESS DENIED" # Outside the codewar you can use the lines below. # b = input("Please, print the password here (without letters!): ") # print(password(b))1 1 from datetime import datetime 2 2 3 3 def password(p): 4 4 a = datetime.now() 5 - c = str(a.hour) + str(a.minute) 6 - 7 - if p.isdigit(): 8 - if(p == c): 9 - return("ACCESS CONFIRMED") 10 - else: 11 - return("ACCESS DENIED") 12 - else: 13 - return("Please, don't print letters.\nReset the program.") 5 + if not p.isdigit(): 6 + return "Please, don't print letters.\nReset the program." 7 + return "ACCESS CONFIRMED" if p == f"{a.hour}{a.minute}" else "ACCESS DENIED" 14 14 15 15 # Outside the codewar you can use the lines below. 16 16 # b = input("Please, print the password here (without letters!): ") 17 17 # print(password(b))
let helloLangs = { english: "hello", pirate: "yar" } const hello = (whoever, lang="english") => `${helloLangs[lang]} ${whoever}`;1 - const helloLangs = { 1 + let helloLangs = { 2 2 english: "hello", 3 3 pirate: "yar" 4 4 } 5 5 6 6 const hello = (whoever, lang="english") => `${helloLangs[lang]} ${whoever}`;
Don't know how this "kumite" stuff works yet, so i may be doing sth wrong.
This is about finding better/more efficient ways to permutate a list starting with my sorry attempt. The result requires types of the typeclass Ord, to get a common result for the test cases. Havent thought about a way to solve that differently yet.
module Permutation where
import Data.List (sort)
permu :: [a] ->[[a]]
permu [] = []
permu [x] = [[x]]
permu x = fuzz (length x) 0 x
where fuzz l n (x:xs) |n == l = []
|otherwise = map ((:) x) (permu xs) ++ fuzz l (n+1) (xs ++ [x])
permutation :: Ord a => [a] -> [[a]]
permutation x = permu xmodule PermuSpec where
import Test.Hspec
import Data.List (sort)
import Permutation
-- `spec` of type `Spec` must exist
spec :: Spec
spec = do
describe "Permutation" $ do
it "Basic Tests" $ do
shouldBe (sort $ permutation [1,2,3]) [[1,2,3],[1,3,2],[2,1,3],[2,3,1],[3,1,2],[3,2,1]]
shouldBe (sort $ permutation [1..4]) [[1,2,3,4],[1,2,4,3],[1,3,2,4],[1,3,4,2],[1,4,2,3],[1,4,3,2],[2,1,3,4],[2,1,4,3],[2,3,1,4],[2,3,4,1],[2,4,1,3],[2,4,3,1],[3,1,2,4],[3,1,4,2],[3,2,1,4],[3,2,4,1],[3,4,1,2],[3,4,2,1],[4,1,2,3],[4,1,3,2],[4,2,1,3],[4,2,3,1],[4,3,1,2],[4,3,2,1]]
shouldBe (sort $ permutation "wup") ["puw","pwu","upw","uwp","wpu","wup"]Return addresses are just normal stack entries, and nasm lets you jump to an address from a register.
global stack_push, stack_pop, stack_peek ; , stack_is_empty section .text stack_push: xchg rsi, [rsp] jmp rsi stack_pop: pop rsi pop rax jmp rsi stack_peek: pop rsi mov rax, [rsp] jmp rsi1 1 global stack_push, stack_pop, stack_peek ; , stack_is_empty 2 2 section .text 3 3 stack_push: 4 - push rsi 5 - ret 4 + xchg rsi, [rsp] 5 + jmp rsi 6 6 stack_pop: 7 7 pop rsi 8 - ret 8 + pop rax 9 + jmp rsi 9 9 stack_peek: 10 10 pop rsi 11 - push rsi 12 - ret 12 + mov rax, [rsp] 13 + jmp rsi
class Functionator attr_reader :allowed_methods, :callers, :next_caller def initialize(s) @allowed_methods = s.split init_caller end def method_missing(method, *args) method = method.to_s raise NoMethodError, 'Not exists' unless @allowed_methods.include?(method) raise NoMethodError, 'Wrong order' unless @next_caller == method wait_next_caller self end private def wait_next_caller @next_caller = @callers.next rescue StopIteration init_caller end def init_caller @callers = @allowed_methods.each @next_caller = @callers.next end end def functionator(methods) Functionator.new methods end1 1 class Functionator 2 + attr_reader :allowed_methods, :callers, :next_caller 3 + 2 2 def initialize(s) 3 - s.split(' ').each { | i | define_singleton_method :"#{i}" do Functionator.new(s.split(' ')[1..-1].join(' ')) end } 5 + @allowed_methods = s.split 6 + init_caller 7 + end 8 + 9 + def method_missing(method, *args) 10 + method = method.to_s 11 + raise NoMethodError, 'Not exists' unless @allowed_methods.include?(method) 12 + raise NoMethodError, 'Wrong order' unless @next_caller == method 13 + wait_next_caller 14 + self 15 + end 16 + 17 + private 18 + 19 + def wait_next_caller 20 + @next_caller = @callers.next 21 + rescue StopIteration 22 + init_caller 23 + end 24 + 25 + def init_caller 26 + @callers = @allowed_methods.each 27 + @next_caller = @callers.next 4 4 end 5 5 end 6 6 7 - def functionator(string) 8 - Functionator.new(string) 31 + def functionator(methods) 32 + Functionator.new methods 9 9 end
describe 'Functionator' do subject(:func) { functionator(input_data) } context 'when first chain is correct' do let(:input_data) { 'there are two kinds of people' } it do expect { func.there().are().two().kinds().of().people() }.not_to raise_error end end context 'when second chain is correct' do let(:input_data) { 'hello codewars world' } it do expect { func.hello().codewars().world() }.not_to raise_error end end context 'when third chain is NOT correct' do let(:input_data) { 'theraretwokindsofpeople' } it do expect { func.is_expected.theraretwokindsofpeople }.to raise_error StandardError end end context 'when fourth chain is NOT correct' do let(:input_data) { 'hello word' } it do expect { func.is_expected.word().hello() }.to raise_error StandardError end end context 'when fifth chain is NOT correct' do let(:input_data) { 'hello word' } it do expect { func.is_expected.hello().word }.to raise_error StandardError end end end1 - # TODO: Replace examples and use TDD development by writing your own tests 2 - # These are some of the methods available: 3 - # Test.expect(boolean, [optional] message) 4 - # Test.assert_equals(actual, expected, [optional] message) 5 - # Test.assert_not_equals(actual, expected, [optional] message) 6 - 7 - describe "t e s t s" do 8 - it "t e s t s" do 9 - obj = functionator('there are two kinds of people') 10 - Test.expect(obj.there().are().two().kinds().of().people(),'Chain is incorrect'); 1 + describe 'Functionator' do 2 + subject(:func) { functionator(input_data) } 11 11 12 - obj = functionator('hello codewars world') 13 - Test.expect(obj.hello().codewars().world(),'Chain is incorrect'); 4 + context 'when first chain is correct' do 5 + let(:input_data) { 'there are two kinds of people' } 14 14 15 - obj = functionator('theraretwokindsofpeople') 16 - Test.expect(obj.theraretwokindsofpeople,'theraretwokindsofpeople is not defined'); 7 + it do 8 + expect { func.there().are().two().kinds().of().people() }.not_to raise_error 9 + end 10 + end 11 + 12 + context 'when second chain is correct' do 13 + let(:input_data) { 'hello codewars world' } 14 + 15 + it do 16 + expect { func.hello().codewars().world() }.not_to raise_error 17 + end 18 + end 19 + 20 + context 'when third chain is NOT correct' do 21 + let(:input_data) { 'theraretwokindsofpeople' } 22 + 23 + it do 24 + expect { func.is_expected.theraretwokindsofpeople }.to raise_error StandardError 25 + end 26 + end 27 + 28 + context 'when fourth chain is NOT correct' do 29 + let(:input_data) { 'hello word' } 30 + 31 + it do 32 + expect { func.is_expected.word().hello() }.to raise_error StandardError 33 + end 34 + end 35 + 36 + context 'when fifth chain is NOT correct' do 37 + let(:input_data) { 'hello word' } 38 + 39 + it do 40 + expect { func.is_expected.hello().word }.to raise_error StandardError 41 + end 17 17 end 18 18 end
Let's just hide that the Stack is implemented with an array, so that we're not tempted to use other methods as shift() 😇
class Stack { // Just to hide the use of array implementation constructor() { this._items = []; } push(data) { this._items.push(data); } pop() { return this._items.pop(); } length() { return this._items.length; } } class Queue { constructor() { this._stack = new Stack(); } enqueue(data) { this._stack.push(data); } dequeue() { if (this._stack.length() === 1) return this._stack.pop(); else { var tmp = this._stack.pop(), result = this.dequeue(); this.enqueue(tmp); return result; } } }1 + class Stack { // Just to hide the use of array implementation 2 + constructor() { 3 + this._items = []; 4 + } 5 + push(data) { 6 + this._items.push(data); 7 + } 8 + pop() { 9 + return this._items.pop(); 10 + } 11 + length() { 12 + return this._items.length; 13 + } 14 + } 15 + 1 1 class Queue { 2 2 constructor() { 3 - this._stack = []; // We will be using this array as a stack - only 4 - // its push and pop operations will ever be called 18 + this._stack = new Stack(); 5 5 } 6 6 enqueue(data) { 7 7 this._stack.push(data); 8 8 } 9 9 dequeue() { 10 - if (this._stack.length === 1) 24 + if (this._stack.length() === 1) 11 11 return this._stack.pop(); 12 12 else { 13 13 var tmp = this._stack.pop(), result = this.dequeue(); 14 14 this.enqueue(tmp); 15 15 return result; 16 16 } 17 17 } 18 18 }
def array_of_two(n) [n.to_int, n.to_int] end1 1 def array_of_two(n) 2 - raise 'n is not a number' unless n.is_a?(Numeric) # comment to fail test case 3 - [n, n] 2 + [n.to_int, n.to_int] 4 4 end
describe "array_of_two" do context "When raise an exception if N is not a number" do it do expect { array_of_two('hello world') }.to raise_error StandardError end it do expect { array_of_two('2') }.to raise_error StandardError end end context "When array of two integer" do subject { array_of_two(2) } it { is_expected.to eq [2, 2] } end end1 - describe "Test#expect_error" do 2 - Test.expect_error("array_of_two should raise an exception if N is not a number") { array_of_two('hello world') } 1 + describe "array_of_two" do 2 + context "When raise an exception if N is not a number" do 3 + it do 4 + expect { array_of_two('hello world') }.to raise_error StandardError 5 + end 6 + it do 7 + expect { array_of_two('2') }.to raise_error StandardError 8 + end 9 + end 10 + context "When array of two integer" do 11 + subject { array_of_two(2) } 12 + 13 + it { is_expected.to eq [2, 2] } 14 + end 3 3 end
A mistake they don't want to fix...
function describePhp() {
return 2 * 2 == 4 ? 'php is good' : 2 * 2 == 5 ? 'php is weird' : 'php has features';
}class TestPhpQualities extends TestCase {
public function testPhpIsNice() {
$this->assertEquals('php is good', describePhp());
}
}function pairs(target_value, array) { array.map(i => { array.map(j => { (i !== j && array[i] === array[j])? 1 : 0 }) }) } //shorter way to write what you wrote1 1 function pairs(target_value, array) { 2 - var num_elements = array.length; 3 - 4 - for ( var i = 0; i < num_elements; i++ ) { 5 - for ( var j = 0; j < num_elements; j++ ) { 6 - if ( i !== j && array[i] === array[j] ) { 7 - return -1; 8 - } 9 - } 10 - } 11 - 12 - return 0; 2 + array.map(i => { array.map(j => { 3 + (i !== j && array[i] === array[j])? 1 : 0 4 + }) 5 + }) 13 13 } 7 + 8 + //shorter way to write what you wrote
#include <stdlib.h> typedef struct IntVector { int *data; } IntVector; static void IntVector_construct(IntVector *this, size_t size) { this->data = calloc(sizeof(*this->data), size); } static void IntVector_destruct(IntVector *this) { free(this->data); } static int IntVector_get(const IntVector *this, size_t index) { return this->data[index]; } static void IntVector_set(const IntVector *this, size_t index, int value) { return this->data[index] = value; }1 1 #include <stdlib.h> 2 2 3 3 typedef struct IntVector { 4 4 int *data; 5 5 } IntVector; 6 6 7 - IntVector *IntVector_new(size_t size) { 8 - IntVector *this = malloc(sizeof(IntVector)); 7 + static void IntVector_construct(IntVector *this, size_t size) { 9 9 this->data = calloc(sizeof(*this->data), size); 10 - return this; 11 11 } 12 12 13 - void IntVector_free(IntVector *this) { 11 + static void IntVector_destruct(IntVector *this) { 14 14 free(this->data); 15 - free(this); 16 16 } 17 17 18 - int IntVector_get(const IntVector *this, size_t index) { 15 + static int IntVector_get(const IntVector *this, size_t index) { 19 19 return this->data[index]; 20 20 } 21 21 22 - void IntVector_set(IntVector *this, size_t index, int value) { 19 + static void IntVector_set(const IntVector *this, size_t index, int value) { 23 23 return this->data[index] = value; 24 24 }
#include <criterion/criterion.h> #include "/home/codewarrior/solution.txt" typedef struct IntVector IntVector; Test(type_IntVector, should_be_implemented) { IntVector v; IntVector_construct(&v, 2); cr_assert_eq(IntVector_get(&v, 0), 0); cr_assert_eq(IntVector_get(&v, 1), 0); IntVector_set(&v, 0, 1); IntVector_set(&v, 1, 2); cr_assert_eq(IntVector_get(&v, 0), 1); cr_assert_eq(IntVector_get(&v, 1), 2); IntVector_destruct(&v); }1 1 #include <criterion/criterion.h> 2 + #include "/home/codewarrior/solution.txt" 2 2 3 3 typedef struct IntVector IntVector; 4 4 5 5 Test(type_IntVector, should_be_implemented) { 6 - IntVector *v = IntVector_new(2); 7 - cr_assert_eq(IntVector_get(v, 0), 0); 8 - cr_assert_eq(IntVector_get(v, 1), 0); 9 - IntVector_set(v, 0, 1); 10 - IntVector_set(v, 1, 2); 11 - cr_assert_eq(IntVector_get(v, 0), 1); 12 - cr_assert_eq(IntVector_get(v, 1), 2); 13 - IntVector_free(v); 7 + IntVector v; 8 + IntVector_construct(&v, 2); 9 + cr_assert_eq(IntVector_get(&v, 0), 0); 10 + cr_assert_eq(IntVector_get(&v, 1), 0); 11 + IntVector_set(&v, 0, 1); 12 + IntVector_set(&v, 1, 2); 13 + cr_assert_eq(IntVector_get(&v, 0), 1); 14 + cr_assert_eq(IntVector_get(&v, 1), 2); 15 + IntVector_destruct(&v); 14 14 }
Algorithms
String.prototype.toBase64 = function () { const characters = 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/='; let result = ''; let i = 0; while (i < this.length) { let a = this.charCodeAt(i++) || 0; let b = this.charCodeAt(i++) || 0; let c = this.charCodeAt(i++) || 0; let b1 = (a >> 2) & 0x3F; let b2 = ((a & 0x3) << 4) | ((b >> 4) & 0xF); let b3 = ((b & 0xF) << 2) | ((c >> 6) & 0x3); let b4 = c & 0x3F; if (!b) b3 = b4 = 64; else if (!c) b4 = 64; result += characters.charAt(b1) + characters.charAt(b2) + characters.charAt(b3) + characters.charAt(b4); } return result; } const hexToBase64 = hex => hex .match(/.{1,2}/g) .map(v => String.fromCharCode(parseInt(v, 16))) .join`` .toBase64();1 - function hexToBase64(hex) { 2 - return hex; 1 + String.prototype.toBase64 = function () { 2 + const characters = 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/='; 3 + let result = ''; 4 + let i = 0; 5 + while (i < this.length) { 6 + let a = this.charCodeAt(i++) || 0; 7 + let b = this.charCodeAt(i++) || 0; 8 + let c = this.charCodeAt(i++) || 0; 9 + 10 + let b1 = (a >> 2) & 0x3F; 11 + let b2 = ((a & 0x3) << 4) | ((b >> 4) & 0xF); 12 + let b3 = ((b & 0xF) << 2) | ((c >> 6) & 0x3); 13 + let b4 = c & 0x3F; 14 + 15 + if (!b) b3 = b4 = 64; 16 + else if (!c) b4 = 64; 17 + 18 + result += characters.charAt(b1) + 19 + characters.charAt(b2) + 20 + characters.charAt(b3) + 21 + characters.charAt(b4); 22 + } 23 + return result; 3 3 } 25 + 26 + const hexToBase64 = hex => 27 + hex 28 + .match(/.{1,2}/g) 29 + .map(v => String.fromCharCode(parseInt(v, 16))) 30 + .join`` 31 + .toBase64(); 32 +
This one should be faster since we only compute 2 products of less numbers.
module NCR where --Combinations nCr comb:: Integer -> Integer -> Integer comb n r = product [n-r+1..n] `div` product [2..r]1 1 module NCR where 2 2 3 3 --Combinations nCr 4 4 comb:: Integer -> Integer -> Integer 5 - comb n r = factorial n `div` (factorial r * factorial (n-r)) 6 - where 7 - factorial n = product [1 .. n] 5 + comb n r = product [n-r+1..n] `div` product [2..r]
Data Structures
Algorithms
Binary Search Trees
Trees
Binary
Maps
Map/Dictionary/Associative Array as a binary search tree of entries
Suggested reading: Binary Search Tree - Wikipedia
Last time we saw how the map/dictionary/assoc array datatype can be implemented as a linked list of entries. We also noted how this implementation is seldomly used in real-world applications due to its sheer inefficiency for pretty much every operation.
So is there a way to make this data type more efficient? As it turns out, using a different data structure can really make an impact on the runtime complexity of operations on maps. One particular data structure that suits maps pretty well is the binary search tree (BST). A binary search tree is a special case of a binary tree where when one traverses its elements pre-order (left -> value -> right), the sequence of elements are in order. When the BST is perfectly balanced (i.e. all its branches have the same depth), its insertion, lookup and deletion operations are all logarithmic in time (O(log n)) because for every level you advance through the tree, you can effectively discard half of the tree. Another advantage of using a BST in our map is that we can implement a function converting the map into an iterator (if we wish to iterate through our key-value pairs in the map) such that the sequence of elements in the iterator are guaranteed to arrive in-order. However, the major drawback of (ordinary) BSTs is that if the elements are inserted in-order (or in reversed order), it degenerates into a linked list so its operations become O(n) again. Furthermore, if one inserts elements randomly into a BST, its operations converge towards an O(sqrt n) time complexity which is significantly less efficient than O(log n).
If only there were a way to ensure that our BST is sufficiently balanced at all times ... ;)
#include <stddef.h> typedef struct { // Denotes a key-value pair of integers, e.g. 7 => 34 int key, value; } Entry; typedef struct node_t { // A node of a binary (search) tree - the internal implementation of our map Entry *entry; struct node_t *left, *right; } Node; typedef struct { // Our map datatype, implemented as a simple wrapper around our BST // This allows us to insert elements to a map by object reference and // reserves NULL for indicating an invalid reference to a Map (instead // of an empty map) Node *root; } Map; int map_get(const Map *map, int key) { // Retrieves the corresponding value for a given key in a map // Assumption: The given key-value pair in the map exists const Node *nd = map->root; while (nd->entry->key != key) nd = key < nd->entry->key ? nd->left : nd->right; return nd->entry->value; } void map_set(Map *map, int key, int value) { // Adds the key-value pair to the map if no entry with the given key exists; // otherwise modifies the value of the entry with the given key to the given value if (map->root == NULL) { map->root = malloc(sizeof(Node)); map->root->entry = malloc(sizeof(Entry)); map->root->entry->key = key; map->root->entry->value = value; map->root->left = map->root->right = NULL; } else { Node *nd = map->root; while (nd->entry->key != key) { const Node *tmp = key < nd->entry->key ? nd->left : nd->right; if (tmp == NULL) break; nd = tmp; } if (nd->entry->key == key) nd->entry->value = value; else if (key < nd->entry->key) { nd->left = malloc(sizeof(Node)); nd->left->entry = malloc(sizeof(Entry)); nd->left->entry->key = key; nd->left->entry->value = value; nd->left->left = nd->left->right = NULL; } else { nd->right = malloc(sizeof(Node)); nd->right->entry = malloc(sizeof(Entry)); nd->right->entry->key = key; nd->right->entry->value = value; nd->right->left = nd->right->right = NULL; } } } void map_remove(Map *map, int key) { // Removes the key-value entry from the map with the given key // Assumption: The key-value pair in the map exists if (map->root->entry->key == key) { if (map->root->right == NULL) { Node *tmp = map->root->left; free(map->root->entry); free(map->root); map->root = tmp; } else if (map->root->left == NULL) { Node *tmp = map->root->right; free(map->root->entry); free(map->root); map->root = tmp; } else if (rand() % 2) { Node *parent = map->root, *child = parent->left; while (child->right != NULL) { parent = child; child = child->right; } if (parent->left == child) parent->left = child->left; else parent->right = child->left; map->root->entry->key = child->entry->key; map->root->entry->value = child->entry->value; free(child->entry); free(child); } else { Node *parent = map->root, *child = parent->right; while (child->left != NULL) { parent = child; child = child->left; } if (parent->left == child) parent->left = child->right; else parent->right = child->right; map->root->entry->key = child->entry->key; map->root->entry->value = child->entry->value; free(child->entry); free(child); } } else { Node *nd_parent = map->root, *nd = key < nd_parent->entry->key ? nd_parent->left : nd_parent->right; while (nd->entry->key != key) { nd_parent = nd; nd = key < nd->entry->key ? nd->left : nd->right; } if (nd->right == NULL) { if (nd_parent->left == nd) nd_parent->left = nd->left; else nd_parent->right = nd->left; free(nd->entry); free(nd); } else if (nd->left == NULL) { if (nd_parent->left == nd) nd_parent->left = nd->right; else nd_parent->right = nd->right; free(nd->entry); free(nd); } else if (rand() % 2) { Node *parent = nd, *child = parent->left; while (child->right != NULL) { parent = child; child = child->right; } if (parent->left == child) parent->left = child->left; else parent->right = child->left; nd->entry->key = child->entry->key; nd->entry->value = child->entry->value; free(child->entry); free(child); } else { Node *parent = nd, *child = parent->right; while (child->left != NULL) { parent = child; child = child->left; } if (parent->left == child) parent->left = child->right; else parent->right = child->right; nd->entry->key = child->entry->key; nd->entry->value = child->entry->value; free(child->entry); free(child); } } }1 1 #include <stddef.h> 2 2 3 3 typedef struct { 4 - // A key-value pair of integers 4 + // Denotes a key-value pair of integers, e.g. 7 => 34 5 5 int key, value; 6 6 } Entry; 7 7 8 8 typedef struct node_t { 9 - // A node in a linked list - internal implementation of a Map 10 - Entry *entry; // The current entry in our map 11 - struct node_t *next; // The rest of our map 9 + // A node of a binary (search) tree - the internal implementation of our map 10 + Entry *entry; 11 + struct node_t *left, *right; 12 12 } Node; 13 13 14 14 typedef struct { 15 - // Outer map wrapper (to hide interal implementation and 16 - // reserve `NULL` for representing an invalid map reference instead of an empty map) 15 + // Our map datatype, implemented as a simple wrapper around our BST 16 + // This allows us to insert elements to a map by object reference and 17 + // reserves NULL for indicating an invalid reference to a Map (instead 18 + // of an empty map) 17 17 Node *root; 18 18 } Map; 19 19 20 20 int map_get(const Map *map, int key) { 21 - // Returns the corresponding value to the key in the map 22 - // Assumption: the key is present in the map 23 - // (querying a nonexistent key yields undefined behavior) 24 - const Node *n = map->root; 25 - while (n->entry->key != key) 26 - n = n->next; 27 - return n->entry->value; 23 + // Retrieves the corresponding value for a given key in a map 24 + // Assumption: The given key-value pair in the map exists 25 + const Node *nd = map->root; 26 + while (nd->entry->key != key) 27 + nd = key < nd->entry->key ? nd->left : nd->right; 28 + return nd->entry->value; 28 28 } 29 29 30 30 void map_set(Map *map, int key, int value) { 31 - // Adds the key-value pair to the map if not present; 32 - // otherwise reassigns it at the corresponding entry 33 - Node *n = map->root; 34 - while (n != NULL && n->entry->key != key) 35 - n = n->next; 36 - if (n != NULL) 37 - n->entry->value = value; 38 - else { 39 - Node *tmp = map->root; 32 + // Adds the key-value pair to the map if no entry with the given key exists; 33 + // otherwise modifies the value of the entry with the given key to the given value 34 + if (map->root == NULL) { 40 40 map->root = malloc(sizeof(Node)); 41 41 map->root->entry = malloc(sizeof(Entry)); 42 42 map->root->entry->key = key; 43 43 map->root->entry->value = value; 44 - map->root->next = tmp; 39 + map->root->left = map->root->right = NULL; 40 + } else { 41 + Node *nd = map->root; 42 + while (nd->entry->key != key) { 43 + const Node *tmp = key < nd->entry->key ? nd->left : nd->right; 44 + if (tmp == NULL) 45 + break; 46 + nd = tmp; 47 + } 48 + if (nd->entry->key == key) 49 + nd->entry->value = value; 50 + else if (key < nd->entry->key) { 51 + nd->left = malloc(sizeof(Node)); 52 + nd->left->entry = malloc(sizeof(Entry)); 53 + nd->left->entry->key = key; 54 + nd->left->entry->value = value; 55 + nd->left->left = nd->left->right = NULL; 56 + } else { 57 + nd->right = malloc(sizeof(Node)); 58 + nd->right->entry = malloc(sizeof(Entry)); 59 + nd->right->entry->key = key; 60 + nd->right->entry->value = value; 61 + nd->right->left = nd->right->right = NULL; 62 + } 45 45 } 46 46 } 47 47 48 48 void map_remove(Map *map, int key) { 49 - // Removes an entry from the map with the given key 50 - // Assumption: The given key-value pair exists 51 - // (attempting to delete a nonexistent entry yields undefined behavior) 52 - // This also implies that the map cannot be empty 67 + // Removes the key-value entry from the map with the given key 68 + // Assumption: The key-value pair in the map exists 53 53 if (map->root->entry->key == key) { 54 - Node *tmp = map->root->next; 55 - free(map->root->entry); 56 - free(map->root); 57 - map->root = tmp; 70 + if (map->root->right == NULL) { 71 + Node *tmp = map->root->left; ... lines 72 to 108 have been collapsed. expand 72 + free(map->root->entry); 73 + free(map->root); 74 + map->root = tmp; 75 + } else if (map->root->left == NULL) { 76 + Node *tmp = map->root->right; 77 + free(map->root->entry); 78 + free(map->root); 79 + map->root = tmp; 80 + } else if (rand() % 2) { 81 + Node *parent = map->root, *child = parent->left; 82 + while (child->right != NULL) { 83 + parent = child; 84 + child = child->right; 85 + } 86 + if (parent->left == child) 87 + parent->left = child->left; 88 + else 89 + parent->right = child->left; 90 + map->root->entry->key = child->entry->key; 91 + map->root->entry->value = child->entry->value; 92 + free(child->entry); 93 + free(child); 94 + } else { 95 + Node *parent = map->root, *child = parent->right; 96 + while (child->left != NULL) { 97 + parent = child; 98 + child = child->left; 99 + } 100 + if (parent->left == child) 101 + parent->left = child->right; 102 + else 103 + parent->right = child->right; 104 + map->root->entry->key = child->entry->key; 105 + map->root->entry->value = child->entry->value; 106 + free(child->entry); 107 + free(child); 108 + } 58 58 } else { 59 - Node *parent = map->root, *child = parent->next; 60 - while (child->next != NULL && child->entry->key != key) { 61 - parent = child; 62 - child = child->next; ... lines 110 to 156 have been collapsed. expand 110 + Node *nd_parent = map->root, *nd = key < nd_parent->entry->key ? nd_parent->left : nd_parent->right; 111 + while (nd->entry->key != key) { 112 + nd_parent = nd; 113 + nd = key < nd->entry->key ? nd->left : nd->right; 114 + } 115 + if (nd->right == NULL) { 116 + if (nd_parent->left == nd) 117 + nd_parent->left = nd->left; 118 + else 119 + nd_parent->right = nd->left; 120 + free(nd->entry); 121 + free(nd); 122 + } else if (nd->left == NULL) { 123 + if (nd_parent->left == nd) 124 + nd_parent->left = nd->right; 125 + else 126 + nd_parent->right = nd->right; 127 + free(nd->entry); 128 + free(nd); 129 + } else if (rand() % 2) { 130 + Node *parent = nd, *child = parent->left; 131 + while (child->right != NULL) { 132 + parent = child; 133 + child = child->right; 134 + } 135 + if (parent->left == child) 136 + parent->left = child->left; 137 + else 138 + parent->right = child->left; 139 + nd->entry->key = child->entry->key; 140 + nd->entry->value = child->entry->value; 141 + free(child->entry); 142 + free(child); 143 + } else { 144 + Node *parent = nd, *child = parent->right; 145 + while (child->left != NULL) { 146 + parent = child; 147 + child = child->left; 148 + } 149 + if (parent->left == child) 150 + parent->left = child->right; 151 + else 152 + parent->right = child->right; 153 + nd->entry->key = child->entry->key; 154 + nd->entry->value = child->entry->value; 155 + free(child->entry); 156 + free(child); 63 63 } 64 - parent->next = child->next; 65 - free(child->entry); 66 - free(child); 67 67 } 68 68 }
#include <criterion/criterion.h> typedef struct { // Denotes a key-value pair of integers, e.g. 7 => 34 int key, value; } Entry; typedef struct node_t { // A node of a binary (search) tree - the internal implementation of our map Entry *entry; struct node_t *left, *right; } Node; typedef struct { // Our map datatype, implemented as a simple wrapper around our BST // This allows us to insert elements to a map by object reference and // reserves NULL for indicating an invalid reference to a Map (instead // of an empty map) Node *root; } Map; static void print_tree_pre_order(const Node *nd) { // Prints the key-value entries in the tree recursively in pre-order fashion if (nd != NULL) { print_tree_pre_order(nd->left); printf("%d => %d\n", nd->entry->key, nd->entry->value); print_tree_pre_order(nd->right); } } static void print_map(const Map *map) { // Prints each entry in the map by traversing the tree pre-order // If the tree within the map is a valid BST then the keys should // appear in order print_tree_pre_order(map->root); } static void print_tree_in_order(const Node *nd) { // Prints the key-value pairs of the tree recursively in-order if (nd != NULL) { printf("%d => %d\n", nd->entry->key, nd->entry->value); print_tree_in_order(nd->left); print_tree_in_order(nd->right); } } static void print_map_in_order(const Map *map) { // Prints each entry in the map by traversing the underlying tree in-order // This reveals a bit more about the actual structure of the BST maintained // within the map print_tree_in_order(map->root); } static void free_tree(Node *nd) { if (nd != NULL) { free_tree(nd->left); free_tree(nd->right); free(nd->entry); free(nd); } } static int tree_size(Node *nd) { return nd == NULL ? 0 : 1 + tree_size(nd->left) + tree_size(nd->right); } Map *map; Test(Map, should_have_a_functioning_get_operation) { // Example map: // { // 1 => 13, // 2 => 22, // 3 => -1, // 4 => 5, // 5 => 4, // 6 => 676, // 7 => -102 // } // The internal BST of the map is structured as follows (keys shown only for simplicity): // 4 // / \ // / \ // / \ // 2 6 // / \ / \ // 1 3 5 7 map = &((Map){ .root = &((Node){ .left = &((Node){ .left = &((Node){ .left = NULL, .entry = &((Entry){ .key = 1, .value = 13 }), .right = NULL }), .entry = &((Entry){ .key = 2, .value = 22 }), .right = &((Node){ .left = NULL, .entry = &((Entry){ .key = 3, .value = -1 }), .right = NULL }) }), .entry = &((Entry){ .key = 4, .value = 5 }), .right = &((Node){ .left = &((Node){ .left = NULL, .entry = &((Entry){ .key = 5, .value = 4 }), .right = NULL }), .entry = &((Entry){ .key = 6, .value = 676 }), .right = &((Node){ .left = NULL, .entry = &((Entry){ .key = 7, .value = -102 }), .right = NULL }) }) }) }); printf("Our map has the following key-value pairs:\n\n"); print_map(map); printf("\nIf we traverse its entries in-order, our map looks like this instead:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 1), 13); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), -1); cr_assert_eq(map_get(map, 4), 5); cr_assert_eq(map_get(map, 5), 4); cr_assert_eq(map_get(map, 6), 676); cr_assert_eq(map_get(map, 7), -102); } Test(Map, should_have_a_functioning_set_operation) { map = malloc(sizeof(Map)); map->root = NULL; // Empty map // Optimal insertion order map_set(map, 4, 5); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 4), 5); map_set(map, 2, 22); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 4), 5); map_set(map, 3, -1); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), -1); cr_assert_eq(map_get(map, 4), 5); map_set(map, 6, 676); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), -1); cr_assert_eq(map_get(map, 4), 5); cr_assert_eq(map_get(map, 6), 676); map_set(map, 1, 13); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 1), 13); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), -1); cr_assert_eq(map_get(map, 4), 5); cr_assert_eq(map_get(map, 6), 676); map_set(map, 5, 4); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 1), 13); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), -1); cr_assert_eq(map_get(map, 4), 5); cr_assert_eq(map_get(map, 5), 4); cr_assert_eq(map_get(map, 6), 676); map_set(map, 7, -102); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 1), 13); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), -1); cr_assert_eq(map_get(map, 4), 5); cr_assert_eq(map_get(map, 5), 4); cr_assert_eq(map_get(map, 6), 676); cr_assert_eq(map_get(map, 7), -102); // Reassigning values to existing key-value pairs map_set(map, 3, 8); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 1), 13); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), 8); cr_assert_eq(map_get(map, 4), 5); cr_assert_eq(map_get(map, 5), 4); cr_assert_eq(map_get(map, 6), 676); cr_assert_eq(map_get(map, 7), -102); map_set(map, 6, -23); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 1), 13); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), 8); cr_assert_eq(map_get(map, 4), 5); cr_assert_eq(map_get(map, 5), 4); cr_assert_eq(map_get(map, 6), -23); cr_assert_eq(map_get(map, 7), -102); map_set(map, 4, 0); printf("Current state of map:\n\n"); print_map(map); printf("\nUsing in-order traversal:\n\n"); print_map_in_order(map); cr_assert_eq(map_get(map, 1), 13); cr_assert_eq(map_get(map, 2), 22); cr_assert_eq(map_get(map, 3), 8); cr_assert_eq(map_get(map, 4), 0); cr_assert_eq(map_get(map, 5), 4); cr_assert_eq(map_get(map, 6), -23); cr_assert_eq(map_get(map, 7), -102); free_tree(map->root); free(map); } Test(Map, should_have_a_functioning_remove_operation) { srand(time(NULL)); map = malloc(sizeof(Map)); map->root = NULL; map_set(map, 4, 7); map_set(map, 6, 14); map_set(map, 7, 21); map_set(map, 2, 28); map_set(map, 5, 35); map_set(map, 1, 42); map_set(map, 3, 49); printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(tree_size(map->root), 7); cr_assert_eq(map_get(map, 1), 42); cr_assert_eq(map_get(map, 2), 28); cr_assert_eq(map_get(map, 3), 49); cr_assert_eq(map_get(map, 4), 7); cr_assert_eq(map_get(map, 5), 35); cr_assert_eq(map_get(map, 6), 14); cr_assert_eq(map_get(map, 7), 21); map_remove(map, 5); // Deleting a node with no children printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(tree_size(map->root), 6); cr_assert_eq(map_get(map, 1), 42); cr_assert_eq(map_get(map, 2), 28); cr_assert_eq(map_get(map, 3), 49); cr_assert_eq(map_get(map, 4), 7); cr_assert_eq(map_get(map, 6), 14); cr_assert_eq(map_get(map, 7), 21); map_remove(map, 6); // Deleting a node with one child printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(tree_size(map->root), 5); cr_assert_eq(map_get(map, 1), 42); cr_assert_eq(map_get(map, 2), 28); cr_assert_eq(map_get(map, 3), 49); cr_assert_eq(map_get(map, 4), 7); cr_assert_eq(map_get(map, 7), 21); map_remove(map, 2); // Delete a node with two children printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(tree_size(map->root), 4); cr_assert_eq(map_get(map, 1), 42); cr_assert_eq(map_get(map, 3), 49); cr_assert_eq(map_get(map, 4), 7); cr_assert_eq(map_get(map, 7), 21); map_remove(map, 4); printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(tree_size(map->root), 3); cr_assert_eq(map_get(map, 1), 42); cr_assert_eq(map_get(map, 3), 49); cr_assert_eq(map_get(map, 7), 21); map_remove(map, 1); printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(tree_size(map->root), 2); cr_assert_eq(map_get(map, 3), 49); cr_assert_eq(map_get(map, 7), 21); map_remove(map, 3); printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(tree_size(map->root), 1); cr_assert_eq(map_get(map, 7), 21); map_remove(map, 7); printf("\nCurrent state of map:\n\n"); print_map(map); cr_assert_eq(map->root, NULL); free_tree(map->root); free(map); }1 1 #include <criterion/criterion.h> 2 2 3 3 typedef struct { 4 - // A key-value pair of integers 4 + // Denotes a key-value pair of integers, e.g. 7 => 34 5 5 int key, value; 6 6 } Entry; 7 7 8 8 typedef struct node_t { 9 - // A node in a linked list - internal implementation of a Map 10 - Entry *entry; // The current entry in our map 11 - struct node_t *next; // The rest of our map 9 + // A node of a binary (search) tree - the internal implementation of our map 10 + Entry *entry; 11 + struct node_t *left, *right; 12 12 } Node; 13 13 14 14 typedef struct { 15 - // Outer map wrapper (to hide interal implementation and 16 - // reserve `NULL` for representing an invalid map reference instead of an empty map) 15 + // Our map datatype, implemented as a simple wrapper around our BST 16 + // This allows us to insert elements to a map by object reference and 17 + // reserves NULL for indicating an invalid reference to a Map (instead 18 + // of an empty map) 17 17 Node *root; 18 18 } Map; 19 19 20 - int map_get(const Map *map, int key); 21 - void map_set(Map *map, int key, int value); 22 - void map_remove(Map *map, int key); 23 - 24 - Map *m; 25 - 26 - Test(the_map_datatype, should_allow_querying_by_integer_key) { 27 - // Map { 5 => 373, 12 => 23, -3 => 133 } 28 - m = &((Map){ 22 + static void print_tree_pre_order(const Node *nd) { 23 + // Prints the key-value entries in the tree recursively in pre-order fashion 24 + if (nd != NULL) { 25 + print_tree_pre_order(nd->left); 26 + printf("%d => %d\n", nd->entry->key, nd->entry->value); 27 + print_tree_pre_order(nd->right); 28 + } 29 + } 30 + 31 + static void print_map(const Map *map) { 32 + // Prints each entry in the map by traversing the tree pre-order 33 + // If the tree within the map is a valid BST then the keys should 34 + // appear in order 35 + print_tree_pre_order(map->root); 36 + } 37 + 38 + static void print_tree_in_order(const Node *nd) { 39 + // Prints the key-value pairs of the tree recursively in-order 40 + if (nd != NULL) { 41 + printf("%d => %d\n", nd->entry->key, nd->entry->value); 42 + print_tree_in_order(nd->left); 43 + print_tree_in_order(nd->right); 44 + } 45 + } 46 + 47 + static void print_map_in_order(const Map *map) { 48 + // Prints each entry in the map by traversing the underlying tree in-order 49 + // This reveals a bit more about the actual structure of the BST maintained 50 + // within the map 51 + print_tree_in_order(map->root); 52 + } 53 + 54 + static void free_tree(Node *nd) { 55 + if (nd != NULL) { 56 + free_tree(nd->left); 57 + free_tree(nd->right); 58 + free(nd->entry); 59 + free(nd); 60 + } 61 + } 62 + 63 + static int tree_size(Node *nd) { 64 + return nd == NULL ? 0 : 1 + tree_size(nd->left) + tree_size(nd->right); 65 + } 66 + 67 + Map *map; 68 + 69 + Test(Map, should_have_a_functioning_get_operation) { 70 + // Example map: 71 + // { 72 + // 1 => 13, 73 + // 2 => 22, 74 + // 3 => -1, 75 + // 4 => 5, 76 + // 5 => 4, 77 + // 6 => 676, 78 + // 7 => -102 79 + // } 80 + 81 + // The internal BST of the map is structured as follows (keys shown only for simplicity): 82 + // 4 83 + // / \ 84 + // / \ 85 + // / \ 86 + // 2 6 87 + // / \ / \ 88 + // 1 3 5 7 89 + map = &((Map){ 29 29 .root = &((Node){ 91 + .left = &((Node){ 92 + .left = &((Node){ 93 + .left = NULL, 94 + .entry = &((Entry){ 95 + .key = 1, 96 + .value = 13 ... lines 97 to 107 have been collapsed. expand 97 + }), 98 + .right = NULL 99 + }), 100 + .entry = &((Entry){ 101 + .key = 2, 102 + .value = 22 103 + }), 104 + .right = &((Node){ 105 + .left = NULL, 106 + .entry = &((Entry){ 107 + .key = 3, 108 + .value = -1 109 + }), 110 + .right = NULL 111 + }) 112 + }), 30 30 .entry = &((Entry){ 31 - .key = 5, 32 - .value = 373 114 + .key = 4, 115 + .value = 5 33 33 }), 34 - .next = &((Node){ 117 + .right = &((Node){ 118 + .left = &((Node){ 119 + .left = NULL, 120 + .entry = &((Entry){ 121 + .key = 5, 122 + .value = 4 123 + }), 124 + .right = NULL 125 + }), 35 35 .entry = &((Entry){ 36 - .key = 12, 37 - .value = 23 127 + .key = 6, 128 + .value = 676 38 38 }), 39 - .next = &((Node){ 130 + .right = &((Node){ 131 + .left = NULL, 40 40 .entry = &((Entry){ 41 - .key = -3, 42 - .value = 133 133 + .key = 7, 134 + .value = -102 43 43 }), 44 - .next = NULL 136 + .right = NULL 45 45 }) 46 46 }) 47 47 }) 48 48 }); 49 - cr_assert_eq(map_get(m, 12), 23); 50 - cr_assert_eq(map_get(m, -3), 133); 51 - cr_assert_eq(map_get(m, 5), 373); 52 - cr_assert_eq(map_get(m, -3), 133, "A key-value pair should be able to be queried more than once"); 53 - } 54 - Test(the_map_datatype, should_allow_us_to_set_key_value_pairs) { 55 - m = malloc(sizeof(Map)); 56 - m->root = NULL; // `m` is now a properly initialized empty map 57 - map_set(m, 3, 5); 58 - cr_assert_eq(map_get(m, 3), 5); 59 - map_set(m, 2, 7); 60 - cr_assert_eq(map_get(m, 2), 7); 61 - map_set(m, -1, -1); 62 - cr_assert_eq(map_get(m, -1), -1); 63 - map_set(m, 10, -187); 64 - cr_assert_eq(map_get(m, 10), -187); 65 - map_set(m, 3, 663); 66 - cr_assert_eq(map_get(m, 3), 663); 67 - map_set(m, 10, 2); 68 - cr_assert_eq(map_get(m, 10), 2); 69 - Node *n = m->root; 70 - size_t size = 0; 71 - while (n != NULL) { 72 - size++; 73 - n = n->next; 74 - } 75 - cr_assert_eq(size, 4, "The map should contain 4 elements at this point"); 76 - cr_assert_neq(size, 6, "The map should not contain 6 elements at this point"); 77 - n = m->root; 78 - while (n != NULL) { 79 - Node *tmp = n->next; 80 - free(n->entry); 81 - free(n); 82 - n = tmp; 83 - } 84 - free(m); ... lines 141 to 149 have been collapsed. expand 141 + 142 + printf("Our map has the following key-value pairs:\n\n"); 143 + print_map(map); 144 + printf("\nIf we traverse its entries in-order, our map looks like this instead:\n\n"); 145 + print_map_in_order(map); 146 + 147 + cr_assert_eq(map_get(map, 1), 13); 148 + cr_assert_eq(map_get(map, 2), 22); 149 + cr_assert_eq(map_get(map, 3), -1); 150 + cr_assert_eq(map_get(map, 4), 5); 151 + cr_assert_eq(map_get(map, 5), 4); 152 + cr_assert_eq(map_get(map, 6), 676); 153 + cr_assert_eq(map_get(map, 7), -102); 85 85 } 86 - Test(the_map_datatype, should_allow_us_to_remove_elements_from_it) { 87 - m = malloc(sizeof(Map)); 88 - m->root = NULL; 89 - map_set(m, 3, 5); 90 - map_set(m, 2, 7); 91 - map_set(m, -1, -1); 92 - map_set(m, 10, -187); 93 - map_set(m, 3, 663); 94 - map_set(m, 10, 2); 95 - cr_assert_eq(map_get(m, 3), 663); 96 - cr_assert_eq(map_get(m, 2), 7); ... lines 97 to 107 have been collapsed. expand 97 - cr_assert_eq(map_get(m, -1), -1); 98 - cr_assert_eq(map_get(m, 10), 2); 99 - map_remove(m, -1); 100 - cr_assert_eq(map_get(m, 3), 663); 101 - cr_assert_eq(map_get(m, 2), 7); 102 - cr_assert_eq(map_get(m, 10), 2); 103 - Node *n = m->root; 104 - size_t size = 0; 105 - while (n != NULL) { 106 - size++; 107 - n = n->next; 108 - } 109 - cr_assert_eq(size, 3, "The map should contain 3 elements at this point"); 110 - map_remove(m, 2); 111 - cr_assert_eq(map_get(m, 3), 663); 112 - cr_assert_eq(map_get(m, 10), 2); 113 - n = m->root; 114 - size = 0; 115 - while (n != NULL) { 116 - size++; 117 - n = n->next; 118 - } 119 - cr_assert_eq(size, 2, "The map should contain 2 elements at this point"); 120 - map_remove(m, 10); 121 - cr_assert_eq(map_get(m, 3), 663); 122 - n = m->root; 123 - size = 0; 124 - while (n != NULL) { 125 - size++; 126 - n = n->next; 127 - } 128 - cr_assert_eq(size, 1, "The map should contain 1 element at this point"); 129 - map_remove(m, 3); 130 - cr_assert_eq(m->root, NULL, "The map should be empty at this point"); 131 - free(m); 155 + 156 + Test(Map, should_have_a_functioning_set_operation) { 157 + map = malloc(sizeof(Map)); 158 + map->root = NULL; // Empty map 159 + 160 + // Optimal insertion order 161 + 162 + map_set(map, 4, 5); 163 + printf("Current state of map:\n\n"); 164 + print_map(map); 165 + printf("\nUsing in-order traversal:\n\n"); 166 + print_map_in_order(map); 167 + cr_assert_eq(map_get(map, 4), 5); 168 + 169 + map_set(map, 2, 22); 170 + printf("Current state of map:\n\n"); 171 + print_map(map); 172 + printf("\nUsing in-order traversal:\n\n"); 173 + print_map_in_order(map); 174 + cr_assert_eq(map_get(map, 2), 22); 175 + cr_assert_eq(map_get(map, 4), 5); 176 + 177 + map_set(map, 3, -1); 178 + printf("Current state of map:\n\n"); 179 + print_map(map); 180 + printf("\nUsing in-order traversal:\n\n"); 181 + print_map_in_order(map); 182 + cr_assert_eq(map_get(map, 2), 22); 183 + cr_assert_eq(map_get(map, 3), -1); 184 + cr_assert_eq(map_get(map, 4), 5); 185 + 186 + map_set(map, 6, 676); 187 + printf("Current state of map:\n\n"); 188 + print_map(map); 189 + printf("\nUsing in-order traversal:\n\n"); 190 + print_map_in_order(map); 191 + cr_assert_eq(map_get(map, 2), 22); 192 + cr_assert_eq(map_get(map, 3), -1); 193 + cr_assert_eq(map_get(map, 4), 5); 194 + cr_assert_eq(map_get(map, 6), 676); 195 + 196 + map_set(map, 1, 13); 197 + printf("Current state of map:\n\n"); 198 + print_map(map); 199 + printf("\nUsing in-order traversal:\n\n"); 200 + print_map_in_order(map); 201 + cr_assert_eq(map_get(map, 1), 13); 202 + cr_assert_eq(map_get(map, 2), 22); 203 + cr_assert_eq(map_get(map, 3), -1); 204 + cr_assert_eq(map_get(map, 4), 5); 205 + cr_assert_eq(map_get(map, 6), 676); 206 + 207 + map_set(map, 5, 4); 208 + printf("Current state of map:\n\n"); 209 + print_map(map); 210 + printf("\nUsing in-order traversal:\n\n"); 211 + print_map_in_order(map); 212 + cr_assert_eq(map_get(map, 1), 13); 213 + cr_assert_eq(map_get(map, 2), 22); 214 + cr_assert_eq(map_get(map, 3), -1); 215 + cr_assert_eq(map_get(map, 4), 5); 216 + cr_assert_eq(map_get(map, 5), 4); 217 + cr_assert_eq(map_get(map, 6), 676); 218 + 219 + map_set(map, 7, -102); 220 + printf("Current state of map:\n\n"); 221 + print_map(map); 222 + printf("\nUsing in-order traversal:\n\n"); 223 + print_map_in_order(map); 224 + cr_assert_eq(map_get(map, 1), 13); 225 + cr_assert_eq(map_get(map, 2), 22); 226 + cr_assert_eq(map_get(map, 3), -1); 227 + cr_assert_eq(map_get(map, 4), 5); 228 + cr_assert_eq(map_get(map, 5), 4); 229 + cr_assert_eq(map_get(map, 6), 676); 230 + cr_assert_eq(map_get(map, 7), -102); 231 + 232 + // Reassigning values to existing key-value pairs 233 + 234 + map_set(map, 3, 8); 235 + printf("Current state of map:\n\n"); 236 + print_map(map); 237 + printf("\nUsing in-order traversal:\n\n"); 238 + print_map_in_order(map); 239 + cr_assert_eq(map_get(map, 1), 13); 240 + cr_assert_eq(map_get(map, 2), 22); 241 + cr_assert_eq(map_get(map, 3), 8); 242 + cr_assert_eq(map_get(map, 4), 5); 243 + cr_assert_eq(map_get(map, 5), 4); 244 + cr_assert_eq(map_get(map, 6), 676); 245 + cr_assert_eq(map_get(map, 7), -102); 246 + 247 + map_set(map, 6, -23); 248 + printf("Current state of map:\n\n"); 249 + print_map(map); 250 + printf("\nUsing in-order traversal:\n\n"); 251 + print_map_in_order(map); 252 + cr_assert_eq(map_get(map, 1), 13); 253 + cr_assert_eq(map_get(map, 2), 22); 254 + cr_assert_eq(map_get(map, 3), 8); 255 + cr_assert_eq(map_get(map, 4), 5); 256 + cr_assert_eq(map_get(map, 5), 4); 257 + cr_assert_eq(map_get(map, 6), -23); 258 + cr_assert_eq(map_get(map, 7), -102); 259 + 260 + map_set(map, 4, 0); 261 + printf("Current state of map:\n\n"); 262 + print_map(map); 263 + printf("\nUsing in-order traversal:\n\n"); 264 + print_map_in_order(map); 265 + cr_assert_eq(map_get(map, 1), 13); 266 + cr_assert_eq(map_get(map, 2), 22); 267 + cr_assert_eq(map_get(map, 3), 8); 268 + cr_assert_eq(map_get(map, 4), 0); 269 + cr_assert_eq(map_get(map, 5), 4); 270 + cr_assert_eq(map_get(map, 6), -23); 271 + cr_assert_eq(map_get(map, 7), -102); 272 + 273 + free_tree(map->root); 274 + free(map); 275 + } 276 + 277 + Test(Map, should_have_a_functioning_remove_operation) { 278 + srand(time(NULL)); 279 + map = malloc(sizeof(Map)); 280 + map->root = NULL; 281 + 282 + map_set(map, 4, 7); 283 + map_set(map, 6, 14); 284 + map_set(map, 7, 21); 285 + map_set(map, 2, 28); 286 + map_set(map, 5, 35); 287 + map_set(map, 1, 42); 288 + map_set(map, 3, 49); 289 + printf("\nCurrent state of map:\n\n"); 290 + print_map(map); 291 + cr_assert_eq(tree_size(map->root), 7); 292 + cr_assert_eq(map_get(map, 1), 42); 293 + cr_assert_eq(map_get(map, 2), 28); 294 + cr_assert_eq(map_get(map, 3), 49); 295 + cr_assert_eq(map_get(map, 4), 7); 296 + cr_assert_eq(map_get(map, 5), 35); 297 + cr_assert_eq(map_get(map, 6), 14); 298 + cr_assert_eq(map_get(map, 7), 21); 299 + 300 + map_remove(map, 5); // Deleting a node with no children 301 + printf("\nCurrent state of map:\n\n"); 302 + print_map(map); 303 + cr_assert_eq(tree_size(map->root), 6); 304 + cr_assert_eq(map_get(map, 1), 42); 305 + cr_assert_eq(map_get(map, 2), 28); 306 + cr_assert_eq(map_get(map, 3), 49); 307 + cr_assert_eq(map_get(map, 4), 7); 308 + cr_assert_eq(map_get(map, 6), 14); 309 + cr_assert_eq(map_get(map, 7), 21); 310 + 311 + map_remove(map, 6); // Deleting a node with one child 312 + printf("\nCurrent state of map:\n\n"); 313 + print_map(map); 314 + cr_assert_eq(tree_size(map->root), 5); 315 + cr_assert_eq(map_get(map, 1), 42); 316 + cr_assert_eq(map_get(map, 2), 28); 317 + cr_assert_eq(map_get(map, 3), 49); 318 + cr_assert_eq(map_get(map, 4), 7); 319 + cr_assert_eq(map_get(map, 7), 21); 320 + 321 + map_remove(map, 2); // Delete a node with two children 322 + printf("\nCurrent state of map:\n\n"); 323 + print_map(map); 324 + cr_assert_eq(tree_size(map->root), 4); 325 + cr_assert_eq(map_get(map, 1), 42); 326 + cr_assert_eq(map_get(map, 3), 49); 327 + cr_assert_eq(map_get(map, 4), 7); 328 + cr_assert_eq(map_get(map, 7), 21); 329 + 330 + map_remove(map, 4); 331 + printf("\nCurrent state of map:\n\n"); 332 + print_map(map); 333 + cr_assert_eq(tree_size(map->root), 3); 334 + cr_assert_eq(map_get(map, 1), 42); 335 + cr_assert_eq(map_get(map, 3), 49); 336 + cr_assert_eq(map_get(map, 7), 21); 337 + 338 + map_remove(map, 1); 339 + printf("\nCurrent state of map:\n\n"); 340 + print_map(map); 341 + cr_assert_eq(tree_size(map->root), 2); 342 + cr_assert_eq(map_get(map, 3), 49); 343 + cr_assert_eq(map_get(map, 7), 21); 344 + 345 + map_remove(map, 3); 346 + printf("\nCurrent state of map:\n\n"); 347 + print_map(map); 348 + cr_assert_eq(tree_size(map->root), 1); 349 + cr_assert_eq(map_get(map, 7), 21); 350 + 351 + map_remove(map, 7); 352 + printf("\nCurrent state of map:\n\n"); 353 + print_map(map); 354 + cr_assert_eq(map->root, NULL); 355 + 356 + free_tree(map->root); 357 + free(map); 132 132 }
TIL that
instance Foldable ((,) a) where
foldMap f (_, y) = f y
foldr f z (_, y) = f y z
module FoldableTuple2 where
-- see the testsmodule FoldableTuple2Spec where
import Test.Hspec
import Test.QuickCheck
spec :: Spec
spec = do
describe "(,) a" $ do
it "can be used with `length`" $
property $ \x -> length (x :: (Int, String)) `shouldBe` 1
it "can be used with `concat`" $
property $ \x -> concat (x :: (Int, String)) `shouldBe` snd xFundamentals
Strings
You will be given a number of minutes. Your task is to return a string on the heap that formats the number into 'hours:minutes".
Make sure you always return two integers for the minutes section of the conversion.
i.e. ('0:01' instead of '0:1')
Example:
minutes(90) => '1:30'
char *minutes(int num){ char *ret = calloc(64, sizeof(char)); sprintf(ret, "%d:%02d", (num / 60), (num % 60)); return ret; }1 - function minutes(num){ 2 - return num % 60 < 10 ? Math.floor(num/60) + ':' + '0' + (num % 60) : Math.floor(num/60) + ':' + (num % 60) 1 + char *minutes(int num){ 2 + char *ret = calloc(64, sizeof(char)); 3 + sprintf(ret, "%d:%02d", (num / 60), (num % 60)); 4 + return ret; 3 3 }
#include <criterion/criterion.h> #include <stdio.h> char *minutes(int); Test(minutes, sample_tests) { char *ptr; ptr = minutes(0); cr_assert_eq(strcmp(ptr, "0:00"), 0); free(ptr); ptr = minutes(1); cr_assert_eq(strcmp(ptr, "0:01"), 0); free(ptr); ptr = minutes(18); cr_assert_eq(strcmp(ptr, "0:18"), 0); free(ptr); ptr = minutes(13267); cr_assert_eq(strcmp(ptr, "221:07"), 0); free(ptr); ptr = minutes(351); cr_assert_eq(strcmp(ptr, "5:51"), 0); free(ptr); ptr = minutes(985); cr_assert_eq(strcmp(ptr, "16:25"), 0); free(ptr); ptr = minutes(156113); cr_assert_eq(strcmp(ptr, "2601:53"), 0); free(ptr); }1 - describe("Solution", function(){ 2 - it("Did you make the correct conversion?", function(){ 3 - Test.assertEquals(minutes(0), "0:00", "better try again"); 4 - Test.assertEquals(minutes(1), "0:01", "better try again"); 5 - Test.assertEquals(minutes(18), "0:18", "better try again"); 6 - Test.assertEquals(minutes(13267), "221:07", "better try again"); 7 - Test.assertEquals(minutes(985), "16:25", "better try again"); 8 - Test.assertEquals(minutes(351), "5:51", "better try again"); 9 - Test.assertEquals(minutes(156113), "2601:53", "better try again"); 10 - }); 11 - }); 1 + #include <criterion/criterion.h> 2 + #include <stdio.h> 3 + 4 + char *minutes(int); 5 + 6 + Test(minutes, sample_tests) { 7 + char *ptr; 8 + ptr = minutes(0); 9 + cr_assert_eq(strcmp(ptr, "0:00"), 0); 10 + free(ptr); 11 + 12 + ptr = minutes(1); 13 + cr_assert_eq(strcmp(ptr, "0:01"), 0); 14 + free(ptr); 15 + 16 + ptr = minutes(18); 17 + cr_assert_eq(strcmp(ptr, "0:18"), 0); 18 + free(ptr); 19 + 20 + ptr = minutes(13267); 21 + cr_assert_eq(strcmp(ptr, "221:07"), 0); 22 + free(ptr); 23 + 24 + ptr = minutes(351); 25 + cr_assert_eq(strcmp(ptr, "5:51"), 0); 26 + free(ptr); 27 + 28 + ptr = minutes(985); 29 + cr_assert_eq(strcmp(ptr, "16:25"), 0); 30 + free(ptr); 31 + 32 + ptr = minutes(156113); 33 + cr_assert_eq(strcmp(ptr, "2601:53"), 0); 34 + free(ptr); 35 + }
function throttle(wait, onLast, onFirst, interval, timestamps) { ret = []; if(onFirst) { ret.push(timestamps[0]); // account for first element } let clusterStart = timestamps[0]; for(let i=1; i<timestamps.length; i++) { if(timestamps[i] - timestamps[i-1] > wait) { // 2.) new cluster clusterStart = timestamps[i]; if(onFirst) { ret.push(clusterStart); // push cluster start } } if(interval !=0 && (timestamps[i+1] - timestamps[i] > wait || i == timestamps.length-1)) { // 1.) do interval shit let intervalVal = clusterStart + interval; let loopInvariant = timestamps[i-1]; if(i == timestamps.length-1){ loopInvariant = timestamps[i]; } if(onLast) { loopInvariant += wait; } console.log('intervalVal: ' + intervalVal); console.log('loopInvariant: ' + loopInvariant); while(intervalVal <= loopInvariant) { console.log('pushing intervalVal: ' + intervalVal); ret.push(intervalVal); intervalVal += interval; } } if(timestamps[i+1] - timestamps[i] > wait) { // 2.) new cluster if(onLast) { ret.push(timestamps[i] + wait); // push cluster end } } if(i == timestamps.length-1 && onLast && interval == 0) { // 3.) Account for last element (needs updating) ret.push(timestamps[i] + wait); } } return ret; }1 1 function throttle(wait, onLast, onFirst, interval, timestamps) { 2 - let ret = []; 3 - let cluster = [timestamps[0]]; 2 + ret = []; 3 + if(onFirst) { 4 + ret.push(timestamps[0]); // account for first element 5 + } 6 + let clusterStart = timestamps[0]; 4 4 5 5 for(let i=1; i<timestamps.length; i++) { 6 - if(timestamps[i] - timestamps[i-1] <= wait) { 7 - cluster.push(timestamps[i]); 8 - } else { 9 - let clusterEventTimes = evaluateCluster(wait, onLast, onFirst, interval, cluster); 10 - clusterEventTimes.forEach( function(el){ ret.push(el); }); 11 - cluster = [timestamps[i]]; 12 - } 13 - 14 - if(i == timestamps.length-1) { 15 - let clusterEventTimes = evaluateCluster(wait, onLast, onFirst, interval, cluster); 16 - clusterEventTimes.forEach( function(el){ ret.push(el); }); 9 + if(timestamps[i] - timestamps[i-1] > wait) { // 2.) new cluster 10 + clusterStart = timestamps[i]; 11 + if(onFirst) { 12 + ret.push(clusterStart); // push cluster start 13 + } 17 17 } 18 - } 19 - 20 - return ret; 21 - } 22 - 23 - // Determines all times when an event needs to be fired 24 - function evaluateCluster(wait, onLast, onFirst, interval, cluster){ 25 - let ret = []; 15 + if(interval !=0 && (timestamps[i+1] - timestamps[i] > wait || i == timestamps.length-1)) { // 1.) do interval shit 16 + let intervalVal = clusterStart + interval; 17 + let loopInvariant = timestamps[i-1]; 18 + if(i == timestamps.length-1){ 19 + loopInvariant = timestamps[i]; 20 + } 21 + if(onLast) { 22 + loopInvariant += wait; 23 + } 26 26 27 - if(onFirst) { 28 - ret.push(cluster[0]); // push cluster start 29 - } 30 - if(interval != 0) { 31 - let maxInterval = cluster[cluster.length-1]; 32 - if(onLast) { 33 - maxInterval += wait; 25 + console.log('intervalVal: ' + intervalVal); 26 + console.log('loopInvariant: ' + loopInvariant); 27 + while(intervalVal <= loopInvariant) { 28 + console.log('pushing intervalVal: ' + intervalVal); 29 + ret.push(intervalVal); 30 + intervalVal += interval; 31 + } 34 34 } 35 - for(let intEv = cluster[0]+interval; intEv < maxInterval; intEv+=interval) { 36 - ret.push(intEv); 33 + 34 + if(timestamps[i+1] - timestamps[i] > wait) { // 2.) new cluster 35 + if(onLast) { 36 + ret.push(timestamps[i] + wait); // push cluster end 37 + } 37 37 } 38 - } 39 - if(onLast) { 40 - ret.push(cluster[cluster.length-1]+wait); // push cluster end 41 - } 42 42 40 + if(i == timestamps.length-1 && onLast && interval == 0) { // 3.) Account for last element (needs updating) 41 + ret.push(timestamps[i] + wait); 42 + } 43 + } 44 + 43 43 return ret; 44 44 }
i know it's too late to reply ...but as said in the previous comment your Code is fine you just need some little changes..and because i am a bad explainer i am just going to show my simple version of the code .....
//if you have any Suggestion or noticed a mistake in my code ...tell me...i would need that... function test(n) { var sum=0; for (i=1; i<n; i++){ if ((i%3==0) || (i%5==0)){ sum+=i; } } return sum; }1 - function test() { 2 - var a = []; 3 - for (i=1; i<10; i++){ 1 + //if you have any Suggestion or noticed a mistake in my code ...tell me...i would need that... 2 + function test(n) { 3 + var sum=0; 4 + for (i=1; i<n; i++){ 4 4 if ((i%3==0) || (i%5==0)){ 5 - a.push(i); 6 + sum+=i; 6 6 } 7 7 } 8 - return a; 9 + return sum; 9 9 } 10 - 11 - function sum(number){ 12 - var sum= 0; 13 - for(i=0; i<number.length; i++){ 14 - sum += number[i]; 15 - } 16 - return sum; 17 - } 18 - var ab = test(); 19 - var abc = sum(ab); 20 - console.log(abc);
Test.assertDeepEquals(test(11),33); Test.assertDeepEquals(test(10),23); Test.assertDeepEquals(test(0),0); Test.assertDeepEquals(test(4),3);1 - function test() { 2 - var a = []; 3 - for (i=1; i<10; i++){ 4 - if ((i%3==0) || (i%5==0)){ 5 - a.push(i); 6 - } 7 - } 8 - return a; 9 - } 10 - 11 - function sum(number){ 12 - var sum= 0; 13 - for(i=0; i<number.length; i++){ 14 - sum += number[i]; 15 - } 16 - return sum; 17 - } 18 - var ab = test(); 19 - var abc = sum(ab); 20 - console.log(abc); 1 + Test.assertDeepEquals(test(11),33); 2 + Test.assertDeepEquals(test(10),23); 3 + Test.assertDeepEquals(test(0),0); 4 + Test.assertDeepEquals(test(4),3);
Algorithms
update for ES6 with spread operator
const flatten = arr => arr.reduce((acc, item) => [...acc, ...(Array.isArray(item) ? flatten(item) : [item])],[]);1 1 const flatten = arr => 2 - arr.reduce((acc, item) => acc.concat(Array.isArray(item) ? flatten(item) : item), []); 2 + arr.reduce((acc, item) => [...acc, ...(Array.isArray(item) ? flatten(item) : [item])],[]);
It should be as easy as this?
#include <criterion/criterion.h> #include <criterion/logging.h> Test(the_multiply_function, should_pass_all_the_tests_provided) { for (int i = 0; i < 50; i++) { cr_log_info("blah blah blah, i = %d\n", i); cr_expect_eq(1, 0); } }1 1 #include <criterion/criterion.h> 2 - #include <stdio.h> 2 + #include <criterion/logging.h> 3 3 4 4 Test(the_multiply_function, should_pass_all_the_tests_provided) { 5 5 for (int i = 0; i < 50; i++) { 6 - puts("blah blah blah\n"); 6 + cr_log_info("blah blah blah, i = %d\n", i); 7 7 cr_expect_eq(1, 0); 8 8 } 9 9 }
Testing
replicate in one line
using System; using System.Linq; public static class Kata { public static int ArraySum(params int[][] arrs) { return arrs.SelectMany(arr => arr).Sum(); } }1 1 using System; 2 2 using System.Linq; 3 3 4 4 public static class Kata 5 5 { 6 6 public static int ArraySum(params int[][] arrs) 7 7 { 8 - int sum = 0; 9 - foreach (int[] arr in arrs) 10 - { 11 - sum += arr.Sum(); 12 - } 13 - return sum; 8 + return arrs.SelectMany(arr => arr).Sum(); 14 14 } 15 15 }
Strings
package kata // CalcAgeOnMars calculates the age on Mars from on a age on Earth func CalcAgeOnMars(age int) int { return age * 365 / 687 }1 - package main 1 + package kata 2 2 3 - import "fmt" 4 - 5 - func main() { 6 - var age int 7 - fmt.Printf("Enter your age on Earth: ") 8 - _, err := fmt.Scanf("%d", &age) 9 - if (err != nil) { 10 - fmt.Println(err) 11 - } 12 - age = age * 365 / 687 13 - fmt.Printf("Your age on the surface of Mars is %d years old.\n", age) 3 + // CalcAgeOnMars calculates the age on Mars from on a age on Earth 4 + func CalcAgeOnMars(age int) int { 5 + return age * 365 / 687 14 14 }
package kata_test import ( . "github.com/onsi/ginkgo" . "github.com/onsi/gomega" . "codewarrior/kata" ) var _ = Describe("When calculating the age in mars", func() { It("should result 3 martian years for 7 earth years", func() { Expect(CalcAgeOnMars(7)).To(Equal(3)) }) It("should result 10 martian years for 20 earth years", func() { Expect(CalcAgeOnMars(20)).To(Equal(10)) }) It("should result 22 martian years for 42 earth years", func() { Expect(CalcAgeOnMars(42)).To(Equal(22)) }) })1 - 1 + package kata_test 2 + import ( 3 + . "github.com/onsi/ginkgo" 4 + . "github.com/onsi/gomega" 5 + . "codewarrior/kata" 6 + ) 7 + var _ = Describe("When calculating the age in mars", func() { 8 + It("should result 3 martian years for 7 earth years", func() { 9 + Expect(CalcAgeOnMars(7)).To(Equal(3)) 10 + }) 11 + It("should result 10 martian years for 20 earth years", func() { 12 + Expect(CalcAgeOnMars(20)).To(Equal(10)) 13 + }) 14 + It("should result 22 martian years for 42 earth years", func() { 15 + Expect(CalcAgeOnMars(42)).To(Equal(22)) 16 + }) 17 + 18 + })
Yet another one-liner.
type Gender = Male | Female type Person = { Name : string; Gender : Gender } let alice = { Name = "Alice"; Gender = Female } let bob = { Name = "Bob"; Gender = Male } let femaleOrMale = function | { Name = name; Gender = Female } -> name + " is female." | { Name = name; Gender = Male } -> name + " is male."1 1 type Gender = Male | Female 2 2 type Person = { Name : string; Gender : Gender } 3 3 4 4 let alice = { Name = "Alice"; Gender = Female } 5 5 let bob = { Name = "Bob"; Gender = Male } 6 6 7 - let femaleOrMale p = 8 - match p.Gender with 9 - | Female -> p.Name + " is female." 10 - | Male -> p.Name + " is male." 7 + let femaleOrMale = function 8 + | { Name = name; Gender = Female } -> name + " is female." 9 + | { Name = name; Gender = Male } -> name + " is male."
Objective: given 1 <= K <= 26, 0 <= N count the number of different strings of length N that contain exactly K different characters from the alphabet.
Ideas: for small values of N it should be bruteforce-able.
For large values of N?
Clarifications:
-> "The alphabet" is the 26 lowercase letters of the English alphabet
alphabet = 'abcdefghijklmnopqrstuvwxyz'
import itertools
def counter(N, K):
return counterNaive(N, K)
def counterNaive(N, K):
# print(f"counterNaive({K}, {N})")
allCombs = [x for x in itertools.product(alphabet, repeat=N)]
# print(f"All combinations of length {N}: 26^N = {26**N}")
return sum( len(set(x)) == K for x in allCombs )
def counterSmart(N, K):
# Idea:
# Find all ways of splitting N in K parts
# For each such way, once we know the lenght of the parts K1, ..., Kn
# (And they must be such that K1+...+Kn = N)
# Calculate the possible combinations: they are N!/(N-K)! options for the choice of K letters
# divided by the product of:
# L! where L = count(Kn == j) for j in range(N)
# to compensate the fact that if letters 'a' and 'b' appear in the same amount,
# then doing (a, b) = (b, a) does not give a different sequenec
# times the permutations of N elements with K1, ..., Kn repetitions
# Then add these up
pass# 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.describe('Small values of N')
test.assert_equals(counter(1, 1), 26, "There are 26 one-length strings.")
test.assert_equals(counter(3, 1), 26, "If you can only choose one letter, there are always 26 possibilities.")
test.assert_equals(counter(3, 3), 26*25*24, "If K = N, the answer is easy to calculate")
test.assert_equals(counter(3, 2), 26*25*3, "This is the first test with non-trivial N and K")
test.assert_equals(counter(5, 3), 26*25*24*25)
Test.describe('Medium values of N')
#This makes the naive code time out.
#test.assert_equals(counter(20, 8), -1, "Obviously unfinished test")Alternative Function Syntax
Just discovered this by looking at a few Fortran code examples online, but it seems that in as early as Fortran 95 (perhaps even earlier!), functions can be defined in at least two ways.
The traditional way:
function FUNCTION_NAME(PARAMETER) ! or parameters
PARAMETER_TYPE :: PARAMETER
RETURN_TYPE :: FUNCTION_NAME ! or explicit result variable
! Function body
end function FUNCTION_NAME
And the second (perhaps more C-like) way:
RETURN_TYPE function FUNCTION_NAME(PARAMETER)
PARAMETER_TYPE :: PARAMETER
! Function body
end function FUNCTION_NAME
Of course, with either syntax, it is possible to add modifiers such as pure, recursive or result(RESULT_VAR).
module Solution
implicit none
contains
integer pure function add(a, b) result(c)
integer, intent(in) :: a, b
c = a + b
end function add
end module Solutionprogram TestCases
use CW2
use Solution
implicit none
call describe("add")
call it("adds integers")
call assertEquals(2, add(1, 1))
call assertEquals(8, add(5, 3))
call assertEquals(69, add(33, 36))
call assertEquals(1079, add(826, 253))
call endContext()
call endContext()
end program TestCasesType Initializers
When you define a derived data type in GNU Fortran, you are automatically given a type initializer which allows you to initialize an instance of your derived data type in one go. One can think of a type initializer as a primitive type of constructor. However, custom-defined constructors weren't available until Fortran 2003 so it may not be available in GNU Fortran (which is an extension of the Fortran 95 standard).
module Solution
implicit none
type Vec3D ! A three-dimensional vector
integer :: x, y, z
end type Vec3D
type(Vec3D) :: v = Vec3D(1, 2, 3) ! Using the type initializer provided by Fortran
end module Solutionprogram TestCases
use CW2
use Solution
implicit none
print "(A20, I0, A2, I0, A2, I0, A1)", "Our 3D vector: v = (", v%x, ", ", v%y, ", ", v%z, ")"
call assertEquals(.true., .true.)
end program TestCasesThis Kumite is created to test JQuery support on Codewars.
var jsdom = require("jsdom/lib/old-api.js");
jsdom.env(
'<!DOCTYPE html><p>Hello world</p><a class="the-link" href="https://github.com/tmpvar/jsdom">jsdom!</a>', ["http://code.jquery.com/jquery.js"],
function(err, window) {
console.log(window.document.querySelector("p").textContent);
var $ = window.$;
$.getJSON('https://www.codewars.com/users/Javatlacati', null, function(data) {
console.log(data);
}).error(function(e) {
console.log("first attempt failed\n" + JSON.stringify(e));
});
var name = "kazk";
var url = "http://anyorigin.com/go?url=" + encodeURIComponent("https://www.codewars.com/users/") + name + "&callback=?";
$.get(url, function(response) {
console.log(response);
}).error(function(e) {
console.log("second attempt failed\n" + JSON.stringify(e));
});
console.log("contents of a.the-link:", window.$("a.the-link").text());
}
);Dynamic Memory Allocation by using C library malloc() function
It is possible to allocate memory dynamically in NASM (obviously, otherwise how would it be possible in C and other higher-level languages?) and the easiest way to do it is probably by relying on the C library function malloc().
global one_two_three
extern malloc ; C library function malloc()
section .text
one_two_three:
mov rdi, 12 ; size_t bytes_required = 3 * sizeof(int) == 12 (because sizeof(int) == 4 on CW)
call malloc ; int *result = malloc(bytes_required)
mov dword [rax], 1 ; result[0] = 1 (`dword` means "double word" where 1 word = 2 bytes)
mov dword [rax + 4], 2 ; result[1] = 2
mov dword [rax + 8], 3 ; result[2] = 3
ret ; return result#include <criterion/criterion.h>
int *one_two_three(void);
Test(the_one_two_three_function, should_return_a_dynamically_allocated_array_of_one_two_three) {
int *a = one_two_three();
cr_assert_eq(a[0], 1);
cr_assert_eq(a[1], 2);
cr_assert_eq(a[2], 3);
free(a);
}Actually, that was double -> int, now int -> double.
global to_double section .text to_double: cvtsi2sd xmm0, edi ret1 - global trunc_ 1 + global to_double 2 2 section .text 3 - trunc_: 4 - cvttsd2si eax, xmm0 3 + to_double: 4 + cvtsi2sd xmm0, edi 5 5 ret
#include <criterion/criterion.h> double to_double(int); Test(add_test, should_add_integers) { cr_assert_eq(to_double(123), 123.0); }1 1 #include <criterion/criterion.h> 2 2 3 - int trunc_(double); 3 + double to_double(int); 4 4 5 5 Test(add_test, should_add_integers) { 6 - cr_assert_eq(trunc_(1.2), 1); 7 - cr_assert_eq(trunc_(1.8), 1); 8 - cr_assert_eq(trunc_(-1.2), -1); 9 - cr_assert_eq(trunc_(-1.8), -1); 6 + cr_assert_eq(to_double(123), 123.0); 10 10 }
String literals are stored as read-only (const), and any attempt to modify the pointer returned will result in a SEGFAULT (crash) in most current computing environments.
Obvserving the following assembly output from GCC:
.file "tst.c"
.text
.section .rodata
.LC0:
.string "Hello World."
.text
.globl Hi
.type Hi, @function
Hi:
You can see string literal referred to by label .LC0 is defined within section '.rodata' meaning ready-only data.
Therefore Hi() should have a return type of const char* to avert the possibility of such faulty access occurring.
const char* Hi (void) { return("Hello World."); } char *oopsHi(void) { return ("Hello World."); }1 - char* Hi (void) 1 + const char* Hi (void) 2 2 { 3 - return("Hello World."); 3 + return("Hello World."); 4 + } 5 + 6 + char *oopsHi(void) 7 + { 8 + return ("Hello World."); 4 4 }
// TODO: Replace examples and use TDD development by writing your own tests. The code provided here is just a how-to example. #include <criterion/criterion.h> // replace with the actual method being tested const char* Hi (); Test(the_multiply_function, should_pass_all_the_tests_provided) { cr_assert_eq(Hi(""), "Hello World."); #if 0 // if'd out, reenable to observe crash char oopsHi(); char *p = oopsHi(); *p = 'X'; #endif }1 1 // TODO: Replace examples and use TDD development by writing your own tests. The code provided here is just a how-to example. 2 2 3 3 #include <criterion/criterion.h> 4 4 5 5 // replace with the actual method being tested 6 - char* Hi (); 6 + const char* Hi (); 7 7 8 8 Test(the_multiply_function, should_pass_all_the_tests_provided) { 9 9 cr_assert_eq(Hi(""), "Hello World."); 10 + 11 + #if 0 // if'd out, reenable to observe crash 12 + char oopsHi(); 13 + char *p = oopsHi(); 14 + *p = 'X'; 15 + #endif 10 10 }
using System; namespace Solution { class FizzBuzz { public static string Convert(int input) { var divisableBy3 = input % 3 == 0; var divisableBy5 = input % 5 == 0; return (!divisableBy3 & !divisableBy5) ? input.ToString() : (divisableBy3 ? "Fizz" : string.Empty) + (divisableBy5 ? "Buzz" : string.Empty); } } }1 1 using System; 2 2 3 3 namespace Solution { 4 4 5 5 class FizzBuzz { 6 6 public static string Convert(int input) 7 7 { 8 - var divisableBy3 = (input % 3 == 0); 9 - var divisableBy5 = (input % 5 == 0); 8 + var divisableBy3 = input % 3 == 0; 9 + var divisableBy5 = input % 5 == 0; 10 10 11 11 return (!divisableBy3 & !divisableBy5) ? input.ToString() 12 12 : (divisableBy3 ? "Fizz" : string.Empty) + (divisableBy5 ? "Buzz" : string.Empty); 13 13 } 14 14 } 15 15 }
Advanced Language Features
Fundamentals
Pointers
Fortran has basic support for pointers. A pointer is a rather primitive type of reference - it is essentially a memory address (associated with a given type) which is said to "point to" the data it is referencing. Unlike C/C++/ObjC, Fortran does not support pointers to pointers, function pointers, arrays of pointers or pointer arithmetic but it is still sufficient to allow us to define simple recursive datatypes such as linked lists or binary trees.
To declare a pointer:
integer, pointer :: p ! `p` is a non-associated integer pointer
To associate a pointer to a target:
! The `target` annotation is required for a pointer to point to it
! Otherwise, `n` is just another ordinary integer
integer, target :: n = 42
integer, pointer :: p => n ! `p` is now associated with `n`
To dereference a pointer:
integer, target :: n = 42
integer, pointer :: p => n ! `p` points to `n`
p = 100 ! `p` is automatically dereferenced and its target `n` set to 100
To associate a pointer to another target:
integer, target :: m = 100, n = 42
integer, pointer :: p => n ! `p` points to `n`
p => m ! `p` now points to `m` instead
To make two (or more) pointers point to the same target:
integer, target :: n = 42
integer, pointer :: p1, p2
p1 => n ! `p1` points to `n`
p2 => p1 ! `p2` now points to the TARGET of `p1` which is `n`
! REMEMBER: `p2` does NOT point to `p1` - pointers
! to pointers are not permitted in Fortran
To define a null pointer (i.e. one that does not reference any data):
integer, pointer :: p => null()
To allocate memory for a pointer instead of pointing it to a pre-existing target:
integer, pointer :: p
allocate(p) ! Allocate memory under pointer (just sufficient for one integer)
! Do something with `p`. Make sure `p` doesn't point to anything else
! before it is deallocated (otherwise a memory leak will occur)!
deallocate(p) ! Free the memory under the pointer
To check whether a pointer is associated with a target:
associated(p) ! Checks whether `p` is associated with a target
! Evaluates to the corresponding logical value
! (.true. if associated, .false. otherwise)
The main code example in this Kumite involves derived data types.
module Pointers
implicit none
type Node ! A node of a singly linked list
integer :: data
type(Node), pointer :: next
end type Node
end module Pointersprogram TestCases
use CW2
use Pointers
implicit none
type(Node), pointer :: oneTwoThree
type(Node), target :: nd1, nd2, nd3
nd3%data = 3
nd3%next => null()
nd2%data = 2
nd2%next => nd3
nd1%data = 1
nd1%next => nd2
oneTwoThree => nd1 ! oneTwoThree <- (1 -> 2 -> 3 -> null())
print "(A63)", "Printing out the contents of our linked list `oneTwoThree` ... "
do while (associated(oneTwoThree))
print "(I0)", oneTwoThree%data
oneTwoThree => oneTwoThree%next
end do
print "(A19)", "End of list reached"
call assertEquals(.true., .true.) ! free pass ;)
end program TestCasesOperator Overloading
In Fortran, operator overloading is done via interfacing. The syntax is almost identical to overloading procedures except the name of the alias is replaced by operator (OPERATOR) (where OPERATOR is a placeholder for the actual operator).
Unlike some programming languages such as Haskell, operators to be overloaded cannot contain arbitrary symbols (or a sequence thereof). Only the following operators and types of operators can be overloaded/defined:
- Symbol / symbol combinations already defined as operators in Fortran (e.g.
+,-,*,/,==,/=, etc.) -
.OPERATOR_NAME.whereOPERATOR_NAMEmay only contain English letters (not even numbers, not even underscore)
Operators can be unary or binary or both (of the form OPERATOR OPERAND or OPERAND_1 OPERATOR OPERAND_2) depending on whether the function(s) implementing it accept one or two arguments. However, for operators intrinsic to Fortran (such as * or /), the functions implemeting their overloads may only accept as many arguments as they were originally defined (e.g. you cannot overload * to accept only one operand).
Note that operators must be pure in Fortran, i.e. they are not permitted to mutate their operands. Therefore, functions implementing the overloaded operator must be declared pure (or if not, at least all input parameters must be declared intent(in)).
module OperatorOverloading
implicit none
private :: realRecip, cmplxRecip ! Hide implementation details of overloaded operator
interface operator (.recip.) ! Operator for finding the reciprocal
! (i.e. multiplicative inverse) of a number
module procedure realRecip, cmplxRecip
end interface
contains
pure function realRecip(x)
real, intent(in) :: x
real :: realRecip
realRecip = 1.0 / x
end function realRecip
pure function cmplxRecip(z)
complex, intent(in) :: z
complex :: cmplxRecip
cmplxRecip = cmplx(1, 0) / z
end function cmplxRecip
end module OperatorOverloadingprogram TestCases
use CW2
use OperatorOverloading
implicit none
call describe(".recip.")
call it("should find the reciprocal of real numbers")
call assertWithinTolerance(1.0 / 3.0, .recip. 3.0, 1e-3)
call assertWithinTolerance(1.0 / 1.2945, .recip. 1.2945, 1e-3)
call assertWithinTolerance(1.0 / 0.017, .recip. 0.017, 1e-3)
call endContext()
call it("should find the reciprocal of complex numbers")
call assertWithinTolerance(cmplx(1, 0) / cmplx(3, 4), .recip. cmplx(3, 4), 1e-3)
call assertWithinTolerance(cmplx(1, 0) / cmplx(-2.1, -0.9), .recip. cmplx(-2.1, -0.9), 1e-3)
call assertWithinTolerance(cmplx(1, 0) / cmplx(0.07, 0.08), .recip. cmplx(0.07, 0.08), 1e-3)
call endContext()
call endContext()
end programJust a simple C function void say_hello() written in NASM v2.11.x which prints Hello World! to the console.
global say_hello
section .text
say_hello:
mov eax, 4 ; system call for write (for Linux)
mov ebx, 1 ; file handle 1 is STDOUT
mov ecx, message ; memory address of output buffer
mov edx, msgLen ; size of output buffer in bytes
int 0x80 ; invoke OS to do the write
ret ; Return to the caller
section .data ; Read-only data
message db "Hello World!", 10 ; message = "Hello World!\n"
msgLen equ $-message ; msgLen = strlen(message)#include <criterion/criterion.h>
void say_hello();
Test(say_hello, should_print_hello_world) {
say_hello();
cr_assert(1);
}Interfaces
Basic Language Features
Object-oriented Programming
Fundamentals
Interfacing
In Fortran modules, it is possible to "overload" a prodecure with several variants, each accepting different types/numbers of arguments through interfacing. An interface is essentially a named alias to one or more defined procedures. For example, when we first introduced functions, our add function was only capable of accepting two default (32-bit) integers and compute its sum (as a 32-bit integer). What if we wanted our add function to work on reals as well? Or complex numbers? In that case, all we have to do is to define three separate functions and implement them accordingly - let's call them addIntegers, addReals and addComplexNumbers. After that, we alias them all under the same name add through interfacing which is achieved by using the interface keyword and has the following syntax (ALL_CAPS denote placeholders):
interface ALIAS_NAME
module procedure PROC_1, PROC_2, ..., PROC_N
end interface ALIAS_NAME
The interface is always placed at the top section of the module, i.e. before the contains keyword:
module InterfacingExample
implicit none
! Our interface
interface add
! The `addIntegers`, `addReals` and `addComplexNumbers`
! functions should all be aliased number the name `add`
module procedure addIntegers, addReals, addComplexNumbers
end interface add
contains
pure function addIntegers(a, b) result(c)
integer, intent(in) :: a, b
integer :: c
c = a + b
end function addIntegers
pure function addReals(a, b) result(c)
real, intent(in) :: a, b
real :: c
c = a + b
end function addReals
pure function addComplexNumbers(a, b) result(c)
complex, intent(in) :: a, b
complex :: c
c = a + b
end function addComplexNumbers
end module InterfacingExample
Now let's test it in our program:
program Main
use InterfacingExample
implicit none
print *, add(1, 2) ! > 3 (perhaps with padding)
print *, add(3.5, 4.5) ! > 8.0 (perhaps with padding)
print *, add(cmplx(3, -4), cmplx(2, 1)) ! > (5.0, -3.0) (perhaps with padding)
end program Main
Our alias works as expected. However, at this point, you might be wondering if the functions are still accessible through their original names (e.g. addIntegers). If that is the case then your doubts are well-founded - the functions are still accessible through their original names (which may not be desirable). To hide the original names of the functions and expose only the alias, simply declare the original function names as private the same way you would variables/constants:
module InterfacingExample
implicit none
private :: addIntegers, addReals, addComplexNumbers
! Our interface
interface add
! The `addIntegers`, `addReals` and `addComplexNumbers`
! functions should all be aliased number the name `add`
module procedure addIntegers, addReals, addComplexNumbers
end interface add
contains
pure function addIntegers(a, b) result(c)
integer, intent(in) :: a, b
integer :: c
c = a + b
end function addIntegers
pure function addReals(a, b) result(c)
real, intent(in) :: a, b
real :: c
c = a + b
end function addReals
pure function addComplexNumbers(a, b) result(c)
complex, intent(in) :: a, b
complex :: c
c = a + b
end function addComplexNumbers
end module InterfacingExample
module InterfacingExample
implicit none
private :: addIntegers, addReals, addComplexNumbers
! Our interface
interface add
! The `addIntegers`, `addReals` and `addComplexNumbers`
! functions should all be aliased number the name `add`
module procedure addIntegers, addReals, addComplexNumbers
end interface add
contains
pure function addIntegers(a, b) result(c)
integer, intent(in) :: a, b
integer :: c
c = a + b
end function addIntegers
pure function addReals(a, b) result(c)
real, intent(in) :: a, b
real :: c
c = a + b
end function addReals
pure function addComplexNumbers(a, b) result(c)
complex, intent(in) :: a, b
complex :: c
c = a + b
end function addComplexNumbers
end module InterfacingExampleprogram Main
use CW2
use InterfacingExample
implicit none
call describe("add")
call it("adds integers")
call assertEquals(2, add(1, 1))
call assertEquals(8, add(3, 5))
call assertEquals(108689, add(19392, 89297))
call endContext()
call it("adds reals")
call assertWithinTolerance(3.5, add(1.3, 2.2), 1e-3)
call assertWithinTolerance(17.4, add(6.1, 11.3), 1e-3)
call assertWithinTolerance(-3.7, add(4.9, -8.6), 1e-3)
call endContext()
call it("adds complex numbers")
call assertWithinTolerance(cmplx(5, -3), add(cmplx(3, -4), cmplx(2, 1)), 1e-3)
call assertWithinTolerance(cmplx(-2.1, -7.7), add(cmplx(7.7, 2.1), cmplx(-9.8, -9.8)), 1e-3)
call assertWithinTolerance(cmplx(0, 0), add(cmplx(-3, 4), cmplx(3, -4)), 1e-3)
call endContext()
call endContext()
! Try these - they won't work ;)
! print *, addIntegers(1, 2)
! print *, addReals(3.3, 4.4)
! print *, addComplexNumbers(cmplx(1, 2), cmplx(3, 4))
end program MainFunctions
Control Flow
Basic Language Features
Fundamentals
Recursion
Algorithms
Computability Theory
Theoretical Computer Science
Fortran Procedures - Subroutines
In a previous Kumite, I mentioned that there are two types of procedures in Fortran:
- Functions - These evaluate to a given value which is returned to the caller (for further computation by other parts of the program, for example)
- Subroutines - These only perform a set of actions and do not evaluate to any value
This Kumite aims to demonstrate how to define and invoke a Fortran subroutine.
A Fortran subroutine is in fact declared/defined in the same way as a function except the function keyword (in both the first and last lines) are replaced with subroutine. Pretty much everything else that holds for functions also holds for subroutines, with the exception of a lack of return value (and therefore result(<res_var>) annotation is not permitted). You can even declare a subroutine as recursive (and/or even pure)!
module Solution
implicit none
contains
recursive subroutine print1ToN(n)
integer :: n
if (n > 0) then
call print1ToN(n - 1) ! NOTE: See explanation below code example
print "(I0)", n
end if
end subroutine print1ToN
end module Solution
When invoking a subroutine, the syntax is slightly different - you have to add the call keyword in front of the subroutine name, like such:
program TestCases
use Solution
implicit none
call print1ToN(10)
! > 1
! > 2
! > ... (you get the idea ;) )
! > 10
end program TestCases
module Solution
implicit none
contains
recursive subroutine print1ToN(n)
integer :: n
if (n > 0) then
call print1ToN(n - 1) ! NOTE: See explanation below code example
print "(I0)", n
end if
end subroutine print1ToN
end module Solutionprogram TestCases
use CW2
use Solution
implicit none
print "(A21)", "Printing 1 to 10 ... "
call print1ToN(10)
print "(A22)", "Printing 1 to 100 ... "
call print1ToN(100)
! I could probably somehow test the output to STDOUT by messing with file handles and such
! but for simplicity, let's just give my recursive subroutine a free pass ;)
call assertEquals(.true., .true.)
end program TestCasesFunctions
Control Flow
Basic Language Features
Fundamentals
Recursion
Algorithms
Computability Theory
Theoretical Computer Science
Fortran Procedures - Recursive Functions
In my last Kumite you learned how to declare and define a function in Fortran. If you were interested in it, you may have done some experimentation on defining a few of your own. Some of you might even have attempted to define a recursive function in Fortran using the syntax shown in the last Kumite. For example, you might have tried to find the sum of the first n positive integers recursively:
module Solution
implicit none
contains
function sum1ToN(n) result(sum)
integer :: n, sum
if (n <= 0) then
sum = 0
else
sum = n + sum1ToN(n - 1)
end if
end function sum1ToN
end module Solution
However, if you attempted to compile and execute this module (with an accompanying program), you would've seen an error message similar to the following: Error: Function 'sum1ton' at (1) cannot be called recursively, as it is not RECURSIVE. In fact, you can define a recursive function in Fortran, but you need to add the recursive modifier to the beginning of your function declaration in order to do so:
module Solution
implicit none
contains
recursive function sum1ToN(n) result(sum)
integer :: n, sum
if (n <= 0) then
sum = 0
else
sum = n + sum1ToN(n - 1)
end if
end function sum1ToN
end module Solution
Now, when we define our program using this module and test our sum1ToN function, everything works as expected:
program TestCases
use Solution
implicit none
print "(I0)", sum1ToN(10) ! > 55
end program TestCases
The recursive keyword can also be used in conjunction with the pure keyword to specify a pure function that has the capacity to invoke itself recursively.
module Solution
implicit none
contains
pure recursive function sum1ToN(n) result(sum)
integer, intent(in) :: n
integer :: sum
if (n <= 0) then
sum = 0
else
sum = n + sum1ToN(n - 1)
end if
end function sum1ToN
end module Solution
module Solution
implicit none
contains
pure recursive function sum1ToN(n) result(sum)
integer, intent(in) :: n
integer :: sum
if (n <= 0) then
sum = 0
else
sum = n + sum1ToN(n - 1)
end if
end function sum1ToN
end module Solutionprogram TestCases
use CW2
use Solution
implicit none
integer :: n, size, i
integer, dimension(8) :: values
integer, dimension(:), allocatable :: seed
real :: x
call describe("sum1ToN")
call it("should add the first n natural numbers correctly")
call assertEquals(55, sum1ToN(10))
call assertEquals(5050, sum1ToN(100))
call assertEquals(195001626, sum1ToN(19748))
call endContext()
call it("should be pure")
n = 10
call assertEquals(55, sum1ToN(n))
call assertNotEquals(55, n)
call assertEquals(10, n)
call endContext()
call it("should work for random tests as well")
call date_and_time(values = values)
call random_seed(size = size)
allocate(seed(size))
seed(:) = values(8)
call random_seed(put = seed)
do i = 1, 100
call random_number(x)
n = 1 + 1e3 * x
print "(A12, I0)", "Testing n = ", n
call assertEquals(sol(n), sum1ToN(n))
end do
call endContext()
call endContext()
contains
! Reference solution for random tests
pure recursive function sol(n) result(s)
integer, intent(in) :: n
integer :: s
if (n <= 0) then
s = 0
else
s = n + sol(n - 1)
end if
end function sol
end programFunctions
Control Flow
Basic Language Features
Fundamentals
Fortran Procedures - Functions, Pass By Reference and Purity
In Fortran it is possible to define reusable sets of instructions that either perform a given action / actions or evaluate to a certain value (or do both) which are called procedures. There are two main types of procedures:
- Functions - These eventually evaluate to a certain value which can then be used by the caller. They can be pure (i.e. do not cause any side effects, more on that later) or impure (causing side effects and/or modifying the state of the program in the process).
- Subroutines - These only perform a given set of actions and do not evaluate to any value. Subroutines may also be pure/impure.
This Kumite demonstrates how to define and use a function.
A function (and in fact any procedure) can be defined in any module/program (it does not matter which, the declaration syntax is identical in both cases) by placing them at the bottom half of the module/procedure. To do that, the given program/module has to be split into exactly two sections using the contains statement/keyword in between. The top section contains all of the variable declarations and statements of the program/module, while the bottom section contains all of the procedure definitions:
module FunctionExample
implicit none
! Top section - contains all variable declarations/definitions
contains
! Bottom section - contains all function and subroutine
! (i.e. procedure) definitions
end module FunctionExample
Then, under the contains statement, we declare and define our function using a function declaration of the form function <fn_name>(<var_1>, <var_2>, ..., <var_n>). We end our function definition using end function <fn_name> and our function body goes between these two lines. For example, if we want to declare and define an add function that adds two integers, our module would look like this:
module FunctionExample
implicit none
! Variable declarations
contains
function add(a, b)
! TODO
end function add
end module FunctionExample
If you've paid any amount of attention to my previous Kumite then it should've occurred to you by now that Fortran is a statically typed language, i.e. each variable has a fixed type that cannot be changed at runtime. However, our function declaration shown above didn't assign any types to the parameters a and b (which we want to be integers). So, how to declare their types? Fortunately, it's very simple and straightforward - just declare them at the top of the function body like you would global variables at the start of a program/module!
module FunctionExample
implicit none
! Variable declarations
contains
function add(a, b)
integer :: a, b
end function add
end module FunctionExample
In our add function, we would like to compute the sum of the integers a and b and return the corresponding integer value to the caller. Unfortunately, there is no return keyword in Fortran so how is it done? In Fortran we must store the result we want to return to the caller in a variable with an identical name to the function name which is add in this case. Our result is anticipated to be an integer so we need to declare the type of add as well:
module FunctionExample
implicit none
! Variable declarations
contains
function add(a, b)
integer :: a, b
integer :: add
end function add
end module FunctionExample
Then, we simply assign the result of adding a and b to add:
module FunctionExample
implicit none
! Variable declarations
contains
function add(a, b)
integer :: a, b
integer :: add
add = a + b
end function add
end module FunctionExample
Now our function declaration/definition is complete and we can use it in our program as desired.
program MyProgram
use FunctionExample
implicit none
print "(I0)", add(3, 5) ! > 8
end program MyProgram
Using a custom variable name for the returned result
What if you don't want to use the function name to store the returned result? For example, instead of add = a + b, you want to do c = a + b and have c store the result to be returned. All you have to do is modify the function declaration to function <fn_name>(<var_1>, <var_2>, ..., <var_n>) result(<result_var>) and subsequently the affected variable declarations:
module FunctionExample
implicit none
! Variable declarations
contains
function add(a, b) result(c)
integer :: a, b
integer :: c
c = a + b
end function add
end module FunctionExample
Procedure arguments in Fortran are passed by variable reference, not by value or object reference
Unlike many modern programming languages such as C, Java or Python, procedure (and hence function) arguments in Fortran are passed by variable reference. This means that if you reassign the values of arguments within your function, the passed in variable itself will be affected.
module FunctionExample
implicit none
contains
function add(a, b) result(c)
integer :: a, b
integer :: c
a = a + b ! Argument `a` is assigned the value of the result
c = a ! Result variable `c` assigned the new value of `a`
end function add
end module FunctionExample
program MyProgram
use FunctionExample
implicit none
integer :: m = 3, n = 5
! > m = 3, n = 5
print "(A4, I0, A6, I0)", "m = ", m, ", n = ", n
! > add(m, n) = 8
print "(A12, I0)", "add(m, n) = ", add(m, n)
! This segfaults
! print "(I0)", add(3, 5)
! > m = 8, n = 5
print "(A4, I0, A6, I0)", "m = ", m, ", n = ", n
end program MyProgram
Therefore, in Fortran, one must be careful not to assign any new values to existing parameters (unless there is a good reason to do so deliberately).
Pure Functions
A pure function is one that does not mutate its input in any way and does not depend on and/or change the state of the program when it is executed/evaluated. Due to Fortran's pass-by-variable-reference, it is easy to make a mistake and mutate the value of argument variables passed in and therefore violate this rule. Fortunately, Fortran has native syntactical support for these types of functions - simply prepend the function declaration with the pure keyword: pure function <fn_name>(<v1>, <v2>, ..., <vn>) result(<rv>).
By explicitly declaring your function as pure, Fortran enforces compile-time restrictions on the type declarations of all the parameters to ensure that all parameters are declared in a way that their value cannot be reassigned. This means that we need to modify the parameter declarations by adding a comma, followed by intent(in) after the type name (and before the ::) - this tells the Fortran compiler that the values of the parameters are read-only:
module FunctionExample
implicit none
contains
pure function add(a, b) result(c)
integer, intent(in) :: a, b
integer :: c
c = a + b
end function add
end module FunctionExample
Now we can use the add function with the guarantee that it will never mutate its inputs:
program MyProgram
use FunctionExample
implicit none
integer :: m = 3, n = 5
print "(I0)", add(m, n) ! > 8
print "(I0)", add(3, 5) ! Works - no segfault :)
print "(I0)", m ! > 3
print "(I0)", n ! > 5
end program MyProgram
module FunctionExample
implicit none
contains
pure function add(a, b) result(c)
integer, intent(in) :: a, b
integer :: c
c = a + b
end function add
end module FunctionExampleprogram TestCases
use CW2
use FunctionExample
implicit none
integer :: m, n, i, k
integer, dimension(8) :: datetime
integer, dimension(:), allocatable :: seed
real :: x
call describe("add")
call it("adds integers")
call assertEquals(2, add(1, 1))
call endContext()
call it("adds more integers")
call assertEquals(8, add(3, 5))
call assertEquals(23, add(11, 12))
call assertEquals(1983, add(834, 1149))
call endContext()
call it("should be pure (i.e. doesn't mutate its input)")
m = 3
n = 5
call assertEquals(8, add(m, n))
call assertEquals(3, m)
call assertEquals(5, n)
call assertNotEquals(8, m)
call assertNotEquals(8, n)
call endContext()
call it("should work for random test cases")
! Seed intrinsic subroutine `random_number` with current time
! Source: https://www.linuxquestions.org/questions/programming-9
! /fortran-90-how-do-i-use-random_number-and-random_seed-913870/#post4525725
call date_and_time(values = datetime)
call random_seed(size = k)
allocate(seed(k))
seed(:) = datetime(8)
call random_seed(put = seed)
! Execute test loop
do i = 1, 100
call random_number(x)
m = 1 + 100 * x
call random_number(x)
n = 1 + 100 * x
print "(A16, I0, A9, I0)", "Testing for m = ", m, " and n = ", n
call assertEquals(solution(m, n), add(m, n))
end do
call endContext()
call endContext()
contains
pure function solution(a, b) result(c)
! Reference solution for random assertions
integer, intent(in) :: a, b
integer :: c
c = a + b
end function solution
end programJust a quick test to see how Preloaded works with GNU Fortran on Codewars ...
module Solution
use Preloaded
implicit none
integer :: n = answer - 42 ! n = 0
end module Solutionprogram TestCases
use CW2
! Using Preloaded here in the test cases is optional if the user solution also uses Preloaded
! not including this line doesn't cause errors as `use Solution` already implies `use Preloaded`
! (from solution module) but adding it in here too doesn't cause double import error
! use Preloaded
use Solution
implicit none
print "(A9, I0)", "answer = ", answer
print "(A4, I0)", "n = ", n
! Fails as expected:
! answer = 100
n = answer ! Succeeds as expected
print "(A4, I0)", "n = ", n
call assertEquals(.true., .true.) ! Just to prevent publishing with failed tests
end programModules
Fundamentals
Object-oriented Programming
Fortran Modules
Fortran modules allow us to split our code into logical chunks across files, each providing a specific functionality and/or set of functionalities and allows us to reuse certain code files in different projects/programs. To create a module, a separate file should first be created. Then, in that separate file, add a module <module_name> statement where <module_name> is a placeholder for the name of our module. In our case, let's name it MyFirstModule. After that, we end our module by adding end module <module_name> on the last line and put everything else in between.
Our module now looks like this:
module MyFirstModule
! TODO
end module MyFirstModule
Same as in a program, the first statement inside a module should almost always be implicit none which disables type inference in the case of a programmer error (e.g. forgetting to declare a variable before defining/using it).
module MyFirstModule
implicit none
! TODO
end module MyFirstModule
Apart from the fact that modules are not executed themselves (they are used in other programs which are then executed), they are almost identical to a program, with one major difference: No action can be performed in a module (at least at the top level). This means that you cannot use print statements among other things as you would in a program - you can only declare/define variables, constants and procedures (more on procedures in future Kumite). For example:
module MyFirstModule
implicit none
integer, parameter :: answer = 42
real :: x = 0.0, y = 1.0
character(len=12) :: hello = "Hello World!"
end module MyFirstModule
Then, to use a module in our program, we add the statement use <module_name> before implicit none:
program MyProgram
use MyFirstModule
implicit none
! TODO
end program MyProgram
Now our program will be able to see all of the variables, constants and procedures that our module has declared/defined. What if we want to hide the two reals x and y (because it is an implementation detail and not intended to be used directly in a program, for example) from the main program? To do that, we simply add a declaration private :: <variable_or_procedure_name_1>, <variable_or_procedure_name_2>, ..., <variable_or_procedure_name_n> to control its visiblity. Our module now looks like this:
module MyFirstModule
implicit none
integer, parameter :: answer = 42
real :: x = 0.0, y = 1.0
character(len=12) :: hello = "Hello World!"
private :: x, y ! x and y are now private to the module itself
! and no longer exposed to the program using it
end module MyFirstModule
Finally, we can use the (exposed) variables/constants/procedures from our module in our main program as if they were defined in our program in the first place:
program MyProgram
use MyFirstModule
implicit none
print "(I0)", answer
print "(A12)", hello
end program MyProgram
See both Kumite "Code" and "Fixture" for the full code example.
module MyFirstModule
implicit none
integer, parameter :: answer = 42
real :: x = 0.0, y = 1.0
character(len=12) :: hello = "Hello World!"
private :: x, y ! x and y are now private to the module itself
! and no longer exposed to the program using it
end module MyFirstModuleprogram MyProgram
use MyFirstModule
implicit none
print "(I0)", answer
print "(A12)", hello
! This fails because `answer` is a parameter
! answer = 100
! These fail because the main program can't see private `x` and `y`; therefore
! failing with a "no IMPLICIT type" error
! print *, x
! print *, y
end program MyProgramFundamentals
Variables
Basic Language Features
Constants, Variables and Datatypes in Fortran
In Fortran, there are a few intrinsic datatypes (known as primitive datatypes in other programming languages):
-
integer- An integral value such as23or-133. By default, an integer is 4 bytes (32 bits) long. Integers of custom size can be specified using theinteger(kind=n)syntax wherenis the number of bytes that the integer occupies in memory an can be either of1,2,4,8and16. -
real- A floating point value such as2.0or3.14. By default,realis single precision (i.e. only 4 bytes long) butreal(kind=8)is double precision (since it occupies8bytes in memory) -
complex- A set of (two) floating point values representing a complex number. By default, both floats are single precision butcomplex(kind=8)holds two double-precision floats instead. Complex numbers are defined using the intrinsic functioncmplxwith two or three arguments, e.g.cmplx(3, 4)defines a default complex number (components are single precision floating point values) representing the value3 + 4i -
logical- A special type of value that can only ever take two values:.true.or.false.. Equivalent to a boolean in most modern programming languages. -
character- A character (i.e. string with length 1) or character string. By default, it specifies a character such as'C'or"0"butcharacter(len=n)specifies a character string of lengthninstead.
Declaration of a variable must be done after implicit none and before any other statements. It takes the following form: <type_name> :: <variable_1>, <variable_2>, ... , <variable_n>. For example, if we want to declare a variable answer with type integer, our program would look like this:
program ConstantsVariablesAndDatatypes
implicit none
integer :: answer
end program ConstantsVariablesAndDatatypes
We can also define our variable on the same line as the declaration, like such:
program ConstantsVariablesAndDatatypes
implicit none
integer :: answer = 42 ! `=` is the assignment operator
end program ConstantsVariablesAndDatatypes
After we declare a variable, we can assign/reassign to it, use it in our computations and/or print it out as desired. For example:
program ConstantsVariablesAndDatatypes
implicit none
integer :: answer = 42
print "(I0)", answer ! > 42
answer = 100 ! Reassignment
print "(I0)", answer ! > 100
end program ConstantsVariablesAndDatatypes
What if we don't want to change the value of a "variable" after initialization? We can do that by adding a comma followed by the parameter keyword to mark a "variable" as a constant. For example:
program ConstantsVariablesAndDatatypes
implicit none
real(kind=8), parameter :: PI = 3.141592653589793
end program ConstantsVariablesAndDatatypes
We can then use it in our computations and/or print it out but not reassign to it:
program ConstantsVariablesAndDatatypes
implicit none
real(kind=8), parameter :: PI = 3.141592653589793 ! Our PI constant
print *, PI ! Prints something like "3.141592653589793", perhaps with leading/trailing whitespace
! The line below causes compilation to fail with an error
! PI = 2.718281828459045
end program ConstantsVariablesAndDatatypes
See "Fixture" of this Kumite for more examples.
module Solution
! Please refer to "Fixture" for examples, we will learn about modules in future Kumite ;)
end module Solutionprogram ConstantsVariablesAndDatatypes
implicit none
integer :: answer = 42 ! A integer of default size with value 42
! A 16 byte (128-bit) integer. Note that integer literals exceeding 4 bytes
! must be immediately followed by `_n` where `n` is the integer byte size and
! can be either of 1, 2, 4, 8, and 16
integer(kind=16) :: largeN = 170141183460469231731687303715884105727_16
! A double precision floating point constant. The `_8` specifies that the floating
! point literal is 8 bytes in size, preserving precision instead of creating a 4 byte
! (imprecise) literal and then typecasting to double precision
real(kind=8), parameter :: PI = 3.141592653589793_8
complex :: z = cmplx(3, 4) ! z = 3 + 4i
logical :: l1, l2 ! l1 and l2 are declared as logical values but not defined
character :: cProgrammingLanguage = 'C' ! Character string of length 1
character(len=12) :: hello = "Hello World!" ! Character string of length 12
l1 = .true. ! Now we define our first logical value to be true
print "(I0)", answer ! > 42
print "(I0)", largeN ! > 170141183460469231731687303715884105727
answer = 100
print "(I0)", answer ! > 100
answer = answer + 1 ! increment `answer` (note that `+=` and the like don't exist in Fortran)
print "(I0)", answer ! > 101
print *, PI ! prints something to the effect of 3.1415 ... (with or without leading/trailing whitespace)
! Cannot reassign to a `parameter` type (i.e. constant value)
! PI = 2.718281828459045_8
print *, z ! Prints the complex value `z` in coordinate form
print "(L1)", l1
l1 = .false. ! Reassign l1 to be false
l2 = .false. ! Assign l2 to be false
print "(L1)", l1
print "(L1)", l2
end program ConstantsVariablesAndDatatypesFundamentals
In my previous Kumite, we learned how to print out Hello World! to the console in Fortran. However, you may have noticed it wasn't perfect - the output has an unnecessary leading whitespace! So, the question is, how to remove it?
When the default settings (denoted by *) is used for the format specifier for print in Fortran, Fortran has to guess how much space it should reserve for the output which it usually overestimates, resulting in undesired padding of the output. To rectify this issue, we can provide our customized format specifier for print.
A customized format specifier for print is passed as a string and is always enclosed in parentheses (). Inside the parentheses, one or more individual format specifiers are separated by a comma , which may or may not be prepended/appended with one or more whitespace characters as desired. The individual format specifiers are as follows:
-
An(nis a positive integer) - a string of lengthn. For example,A10specifies that the output contains a string of length10. -
I0- an integer (of any size) containing any number of digits -
In- an integer containing exactlyndigits
There are also many other format specifiers for floating point values, logical values (known as booleans in most modern programming languages) and so on but we won't cover them in this Kumite.
Since we know that the string "Hello World!" contains exactly 12 characters, our format specifier for this string when printing it to STDOUT is A12. Hence, the full format specifier for the entire line of output should be (A12):
program HelloWorld
implicit none
print "(A12)", "Hello World!"
end program HelloWorld
This should print the output text Hello World! to the console without any leading or trailing whitespace as the length of the string (which is 12) fits the format specifier perfectly (A12). In the case where the value of n specified in the format specifier exceeds the length of the string, the output is padded with leading/trailing whitespace as required to make up to the given length n. Conversely, if the n in the format specifier is smaller than the size of the output then the output is truncated one way or another. This also applies to integers (and other data types).
module Solution
! See "Fixture" for actual Kumite content; we will explore modules in future Kumite ;)
end module Solutionprogram HelloWorld
implicit none
print "(A12)", "Hello World!"
! Exercise: try replacing the statement above with the commented statement shown below ;)
! print "(A6, A6)", "Hello ", "World!"
! Then try replacing it with this instead:
! print "(A4, A4, A4)", "Hell", "o Wo", "rld!"
end program HelloWorldFundamentals
[GNU Fortran] Free-format Hello World Program
Background
https://en.wikipedia.org/wiki/Fortran
Initially conceived in late 1953 and realized in 1957, Fortran (formerly known as FORTRAN, short for "Formula Transformation") is considered to be the oldest high-level programming language in existence. In its early days, FORTRAN was limited to scientific computing (such as calculating trajectories of missiles) and wasn't even Turing-complete due to lack of support for dynamic memory allocation which is a requirement for initializing arrays of varying size during runtime. Nevertheless, FORTRAN gained widespread acceptance in both the science and engineering communities and became the main programming language used in academia for decades. Most notably, the formulation of the first FORTRAN compiler paved the way for modern compiler theory and influenced one of the most successful and widespread programming languages of all time, C.
Modern Fortran standards and implementations (e.g. F90, F95, F2003, F2008, GNU Fortran) are believed to be Turing-complete. In particular, I have successfully demonstrated that GNU Fortran (an extension of the F95 standard) is indeed Turing-complete by implementing a full-fledged BF interpreter (which itself has been proven to be Turing-complete).
This Kumite
In this Kumite I will show you how to print out the text Hello World! (perhaps with a few leading/trailing whitespace) in GNU Fortran. In Fortran, a program is defined by using the program keyword, then giving the program a name (such as HelloWorld). At the end of the program, one should type end program followed by the program name (which is HelloWorld in this case). The contents of the program are placed between these two statements:
program HelloWorld
! Program code here. Fortran comments start with an exclamation mark
end program HelloWorld
Note that Fortran is case-insensitve, i.e. HelloWorld is the same as helloWorld or helloworld. In fact, we can start with pROGRAM HelloWorld and end with END Program hELLOwORLD and the code will compile/execute just fine.
After we define our program, the first statement inside that program should (almost) always be implicit none. This tells the compiler that any and all variables declared by the programmer should be done so explicitly with a specified type instead of attempting to type-infer when no such type is provided. It is not an absolute necessity to add this statement but is added to 99% of programs as a best practice.
program HelloWorld
implicit none
end program HelloWorld
Then, we use the print command to print out our text Hello World!. The print statement accepts a format specifier as its first "argument" (double-quoted here because print is not a Fortran procedure) which we'll learn about later but we'll set it to * in this Kumite which means "use the default settings". Any subsequent "arguments" passed to the print command are comma-separated. In our case, our only other "argument" is the string "Hello World!" so our program would appear as follows:
program HelloWorld
implicit none
print *, "Hello World!" ! Print the text "Hello World!" to the screen
! with the default formatting settings
end program HelloWorld
Note that:
- When the default settings
*are used for the format specifier in theprintcommand, Fortran is likely to pad the displayed output with one or more leading and/or trailing whitespace. We will learn how to get rid of them in the next Kumite. - Fortran does not make a distinction between characters and strings - in fact, a string is declared as
charactertype and an actual character is just a string with length 1. Due to this, both characters and strings can be wrapped in single quotes''or double quotes"", e.g.'Hello World!'is equally valid as"Hello World!"and"H"is considered equal to'H'.
module Solution
! Please refer to the "Test Cases" for the actual Kumite code example - we'll learn
! about modules in future Kumite ;)
end module Solutionprogram HelloWorld
implicit none
print *, "Hello World!" ! Print the text "Hello World!" to the screen
! with the default formatting settings
end program HelloWorldTesting
Frameworks
Basic idea for the new cw-2.py's timeout function to have an extra argument that prevents running the function right away.
passdef timeout(sec, autorun=True):
def wrapper(func):
from multiprocessing import Process
process = Process(target=func)
process.start()
process.join(sec)
if process.is_alive():
test.fail('Exceeded time limit of {:.3f} seconds'.format(sec))
process.terminate()
process.join()
def wrapper2(func):
def wrapped(*args, **kwargs):
from multiprocessing import Process
process = Process(target=lambda: func(*args, **kwargs))
process.start()
process.join(sec)
if process.is_alive():
test.fail('Exceeded time limit of {:.3f} seconds'.format(sec))
process.terminate()
process.join()
return wrapped
return wrapper if autorun else wrapper2
@timeout(0.1)
def f():
for r in range(10**9): pass
test.pass_()
@timeout(0.1, autorun=False)
def f2(n):
for r in range(n): pass
test.pass_()
f2(10**6)
f2(10**9)
@test.it('test')
@timeout(0.1, autorun=False)
def fx():
for r in range(10**9): pass
test.pass_()
def f3(testname, t, n):
@test.it(testname)
@timeout(t, autorun=False)
def sample_it():
for r in range(n): pass
test.pass_()
f3('test1', 0.01, 10**3)
f3('test2', 0.1, 10**9)import java.util.stream.IntStream; public class Area { public static long[] workOutArea(final long[] values){ return values.length % 2 != 0? null: IntStream.range(0, values.length).filter(x -> x % 2 == 0).mapToLong(x -> values[x] * values[x+1]).toArray(); } }1 + import java.util.stream.IntStream; 2 + 1 1 public class Area { 2 2 3 3 public static long[] workOutArea(final long[] values){ 4 - if (values.length % 2 != 0) { 5 - return null; // This is ugly! 6 - } else { 7 - final long[] areas = new long[values.length / 2]; 8 - for (int i = 0; i < values.length; i += 2) { 9 - areas[i / 2] = values[i] * values[i + 1]; 10 - } 11 - return areas; 12 - } 6 + return values.length % 2 != 0? null: IntStream.range(0, values.length).filter(x -> x % 2 == 0).mapToLong(x -> values[x] * values[x+1]).toArray(); 13 13 } 14 14 15 15 }
Show optimization of code. Instead 4 passs throught array (max,min,count double time), use only one pass durring sorting.
# Find stray number def find_stray(n) n.count(n.min) > n.count(n.max) ? n.max : n.min end # Find stray optimization def find_stray_o(n) n.sort! n[0] == n[1] ? n[-1] : n[0] end require "benchmark" array = (Array.new(1000_000,7) + [1]).shuffle Benchmark.bm(10) do |x| x.report("Find stray") { 10.times{ find_stray(array.clone.shuffle) }} x.report("Optimized") { 10.times{find_stray_o(array.clone.shuffle) }} end1 1 # Find stray number 2 2 def find_stray(n) 3 3 n.count(n.min) > n.count(n.max) ? n.max : n.min 4 4 end 5 + 6 + # Find stray optimization 7 + def find_stray_o(n) 8 + n.sort! 9 + n[0] == n[1] ? n[-1] : n[0] 10 + end 11 + 12 + require "benchmark" 13 + 14 + array = (Array.new(1000_000,7) + [1]).shuffle 15 + 16 + Benchmark.bm(10) do |x| 17 + x.report("Find stray") { 10.times{ find_stray(array.clone.shuffle) }} 18 + x.report("Optimized") { 10.times{find_stray_o(array.clone.shuffle) }} 19 + end
x = rand(1..100) y = rand(1..100) describe "Solution" do it "find stray" do Test.assert_equals(find_stray([x,y,y]), x, "[x,y,y] works") Test.assert_equals(find_stray([x,y,y,y]), x, "[x,y,y,y] DOSE NOT works") Test.assert_equals(find_stray([x,y,y,y,y]), x, "[x,y,y,y,y] works") end it "find stray optimized" do Test.assert_equals(find_stray_o([x,y,y]), x, "[x,y,y] works") Test.assert_equals(find_stray_o([x,y,y,y]), x, "[x,y,y,y] DOSE NOT works") Test.assert_equals(find_stray_o([x,y,y,y,y]), x, "[x,y,y,y,y] works") end end1 1 x = rand(1..100) 2 2 y = rand(1..100) 3 3 4 4 describe "Solution" do 5 - it "should test for something" do 5 + it "find stray" do 6 6 Test.assert_equals(find_stray([x,y,y]), x, "[x,y,y] works") 7 7 Test.assert_equals(find_stray([x,y,y,y]), x, "[x,y,y,y] DOSE NOT works") 8 8 Test.assert_equals(find_stray([x,y,y,y,y]), x, "[x,y,y,y,y] works") 9 + end 10 + it "find stray optimized" do 11 + Test.assert_equals(find_stray_o([x,y,y]), x, "[x,y,y] works") 12 + Test.assert_equals(find_stray_o([x,y,y,y]), x, "[x,y,y,y] DOSE NOT works") 13 + Test.assert_equals(find_stray_o([x,y,y,y,y]), x, "[x,y,y,y,y] works") 9 9 end 10 10 end
++++++[>++++++<-]>[->+>++>+++>+++<<<<]>>.>-------.>..+++.<<<----.>-.>----.+.>+++.<+++++++.----.>------.1 - -[------->+<]>-.-[->+++++<]>++.+++++++..+++.[--->+<]>-----.+++[->++<]>+.-[------>+<]>.+.[--->+<]>----.---------.----.+++++++. 1 + ++++++[>++++++<-]>[->+>++>+++>+++<<<<]>>.>-------.>..+++.<<<----.>-.>----.+.>+++.<+++++++.----.>------.
Missing what is it about. Just simplyfing things :)
COLORS = set("RGB") def blend(c1, c2): colors = {c1, c2} return c1 if len(colors) == 1 else (COLORS - colors).pop() def preprocess(row): check = "" for r in row: if r != check: yield r check = r def triangle(row): row = list(preprocess(row)) while len(row) > 1: for i,r in enumerate(row[:-1]): row[i] = blend(r, row[i+1]) row.pop() return row[0]1 - import re 2 - 1 + COLORS = set("RGB") 3 3 def blend(c1, c2): 4 - if c1 == c2: return c1 5 - colors = c1 + c2 6 - if colors == "RB" or colors == "BR": return "G" 7 - if colors == "RG" or colors == "GR": return "B" 8 - if colors == "GB" or colors == "BG": return "R" 3 + colors = {c1, c2} 4 + return c1 if len(colors) == 1 else (COLORS - colors).pop() 5 + 9 9 10 10 def preprocess(row): 11 - orig = row 12 - row,_ = re.subn('RR+', 'R', row) 13 - row,_ = re.subn('BB+', 'B', row) 14 - row,_ = re.subn('GG+', 'G', row) 15 - print(orig, row) 16 - return row 8 + check = "" 9 + for r in row: 10 + if r != check: 11 + yield r 12 + check = r 13 + 17 17 18 18 def triangle(row): 19 - if len(row) == 1: return row 20 - row = preprocess(row) 21 - row = list(row) 22 - for j in range(len(row)-1,0,-1): 23 - for i in range(j): 24 - row[i] = blend(row[i], row[i+1]) 16 + row = list(preprocess(row)) 17 + while len(row) > 1: 18 + for i,r in enumerate(row[:-1]): 19 + row[i] = blend(r, row[i+1]) 20 + row.pop() 25 25 return row[0]
Looks familiar?
Expected: equal to [unsupported type]
Actual: [unsupported type]
No more!
template <class... Args> bool alwaysTrue(Args&&...) { return true; } template <class T> T id(T&& x) { return x; }1 1 template <class... Args> 2 2 bool alwaysTrue(Args&&...) { 3 3 return true; 4 4 } 5 + 6 + template <class T> 7 + T id(T&& x) { 8 + return x; 9 + }
#include <list> #include <tuple> #include <utility> #include <vector> template <class... Args> void printInput(const char* name, const Args&... args); #define alwaysTrue(...) (printInput("alwaysTrue", __VA_ARGS__), alwaysTrue(__VA_ARGS__)) Describe(codewarriors) { It(do_print_arguments) { using vi = std::vector<int>; using li = std::list<int>; using vvi = std::vector<std::vector<int>>; using vs = std::vector<std::string>; using pii = std::pair<int, int>; Assert::That(alwaysTrue(vi{0, 1, 2}), Is().True()); Assert::That(alwaysTrue(li{0, 1, 2}), Is().True()); Assert::That(alwaysTrue((int[]){0, 1, 2}), Is().True()); Assert::That(alwaysTrue(vvi{{0, 1, 2}, {0, 1}, {1}}), Is().True()); Assert::That(alwaysTrue("012"), Is().True()); Assert::That(alwaysTrue((const char*)"012"), Is().True()); Assert::That(alwaysTrue(std::string{"012"}), Is().True()); Assert::That(alwaysTrue(vi{0, 1, 2}, "012", 123), Is().True()); Assert::That(alwaysTrue(vs{"a", "b", ""}, 'c'), Is().True()); Assert::That(alwaysTrue("pair", std::make_pair(1, "2")), Is().True()); Assert::That(alwaysTrue("tuple", std::make_tuple(1, "2", '3', vi{1})), Is().True()); Assert::That(id(pii{0, 1}), Equals(pii{0, 1})); } }; #include <cstddef> #include <algorithm> #include <iostream> #include <iterator> #include <ostream> #include <type_traits> #include <utility> #include <tuple> template <class... Ts> struct make_void { using type = void; }; template <class... Ts> using void_t = typename make_void<Ts...>::type; template <class, class = void> struct is_container : std::false_type { }; template <class T> struct is_container<T, void_t<decltype(std::cbegin(std::declval<T>()))>> : std::true_type { }; template <class, class = void> struct is_string : std::false_type { }; template <class T> struct is_string<T, std::enable_if_t<std::is_same<decltype(*std::cbegin(std::declval<T>())), const char&>::value>> : std::true_type { }; struct ArgumentPrinter { std::ostream& os; template <class Arg, std::enable_if_t<!is_container<Arg>::value && !is_string<Arg>::value>* = nullptr> void printArg(const Arg& arg) { os << arg; } void printArg(const char arg) { os << "'" << arg << "'"; } void printArg(const char* const arg) { os << '"' << arg << '"'; } template <class Arg, std::enable_if_t<is_string<Arg>::value>* = nullptr> void printArg(const Arg& arg) { os << '"'; std::copy(std::cbegin(arg), std::cend(arg), std::ostreambuf_iterator<char>(os)); os << '"'; } template <class T1, class T2> void printArg(const std::pair<T1, T2>& arg) { os << "{"; printArgs(arg.first); os << ", "; printArgs(arg.second); os << "}"; } #include <tuple> template <typename T, std::size_t... Is> void printArgsApplyImpl(const T& arg, std::index_sequence<Is...>) { printArgs(std::get<Is>(arg)...); } template <typename... Ts> void printArgsApply(const std::tuple<Ts...>& arg) { printArgsApplyImpl(arg, std::make_index_sequence<std::tuple_size<std::tuple<Ts...>>::value>()); } template <class... Ts> void printArg(const std::tuple<Ts...>& arg) { os << "{"; printArgsApply(arg); os << "}"; } template <class Arg, std::enable_if_t<is_container<Arg>::value && !is_string<Arg>::value>* = nullptr> void printArg(const Arg& arg) { const auto b = std::cbegin(arg), e = std::end(arg); os << "{"; for (auto i = b; i != e; ++i) { if (i != b) os << ", "; printArgs(*i); } os << "}"; } template <class Arg> void printArgs(const Arg& arg) { printArg(arg); } template <class Arg, class... Args> void printArgs(const Arg& arg, const Args&... args) { printArgs(arg); os << ", "; printArgs(args...); } }; template <class... Args> void printInput(const char* name, const Args&... args) { std::cout << name << "("; ArgumentPrinter{std::cout}.printArgs(args...); std::cout << ")\n"; } #define DEFINE_STRINGIZER(type) \ namespace snowhouse {\ template <> struct Stringizer<type> {\ static std::string ToString(const type& x) {\ std::ostringstream oss;\ ArgumentPrinter{oss}.printArg(x);\ return oss.str();\ }\ };\ } #define COMMA , DEFINE_STRINGIZER(std::pair<int COMMA int>)... lines 1 to 8 have been collapsed. expand 1 1 #include <list> 2 2 #include <tuple> 3 3 #include <utility> 4 4 #include <vector> 5 5 6 6 template <class... Args> void printInput(const char* name, const Args&... args); 7 7 #define alwaysTrue(...) (printInput("alwaysTrue", __VA_ARGS__), alwaysTrue(__VA_ARGS__)) 8 8 9 9 Describe(codewarriors) { 10 10 It(do_print_arguments) { 11 11 using vi = std::vector<int>; 12 12 using li = std::list<int>; 13 13 using vvi = std::vector<std::vector<int>>; 14 14 using vs = std::vector<std::string>; 15 + using pii = std::pair<int, int>; 15 15 Assert::That(alwaysTrue(vi{0, 1, 2}), Is().True()); 16 16 Assert::That(alwaysTrue(li{0, 1, 2}), Is().True()); 17 17 Assert::That(alwaysTrue((int[]){0, 1, 2}), Is().True()); 18 18 Assert::That(alwaysTrue(vvi{{0, 1, 2}, {0, 1}, {1}}), Is().True()); 19 19 Assert::That(alwaysTrue("012"), Is().True()); 20 20 Assert::That(alwaysTrue((const char*)"012"), Is().True()); 21 21 Assert::That(alwaysTrue(std::string{"012"}), Is().True()); 22 22 Assert::That(alwaysTrue(vi{0, 1, 2}, "012", 123), Is().True()); 23 23 Assert::That(alwaysTrue(vs{"a", "b", ""}, 'c'), Is().True()); 24 24 Assert::That(alwaysTrue("pair", std::make_pair(1, "2")), Is().True()); 25 25 Assert::That(alwaysTrue("tuple", std::make_tuple(1, "2", '3', vi{1})), Is().True()); 27 + Assert::That(id(pii{0, 1}), Equals(pii{0, 1})); 26 26 } 27 27 }; 28 28 29 29 30 30 31 31 #include <cstddef> 32 32 #include <algorithm> 33 33 #include <iostream> ... lines 34 to 126 have been collapsed. expand 34 34 #include <iterator> 35 35 #include <ostream> 36 36 #include <type_traits> 37 37 #include <utility> 38 38 39 39 #include <tuple> 40 40 41 41 template <class... Ts> struct make_void { using type = void; }; 42 42 template <class... Ts> using void_t = typename make_void<Ts...>::type; 43 43 44 44 template <class, class = void> struct is_container : std::false_type { }; 45 45 template <class T> struct is_container<T, void_t<decltype(std::cbegin(std::declval<T>()))>> : std::true_type { }; 46 46 47 47 template <class, class = void> struct is_string : std::false_type { }; 48 48 template <class T> struct is_string<T, std::enable_if_t<std::is_same<decltype(*std::cbegin(std::declval<T>())), const char&>::value>> : std::true_type { }; 49 49 50 50 struct ArgumentPrinter { 51 51 std::ostream& os; 52 52 53 53 template <class Arg, std::enable_if_t<!is_container<Arg>::value && !is_string<Arg>::value>* = nullptr> 54 54 void printArg(const Arg& arg) { 55 55 os << arg; 56 56 } 57 57 58 58 void printArg(const char arg) { 59 59 os << "'" << arg << "'"; 60 60 } 61 61 62 62 void printArg(const char* const arg) { 63 63 os << '"' << arg << '"'; 64 64 } 65 65 66 66 67 67 template <class Arg, std::enable_if_t<is_string<Arg>::value>* = nullptr> 68 68 void printArg(const Arg& arg) { 69 69 os << '"'; 70 70 std::copy(std::cbegin(arg), std::cend(arg), std::ostreambuf_iterator<char>(os)); 71 71 os << '"'; 72 72 } 73 73 74 74 template <class T1, class T2> 75 75 void printArg(const std::pair<T1, T2>& arg) { 76 76 os << "{"; 77 77 printArgs(arg.first); 78 78 os << ", "; 79 79 printArgs(arg.second); 80 80 os << "}"; 81 81 } 82 82 83 83 #include <tuple> 84 84 template <typename T, std::size_t... Is> 85 85 void printArgsApplyImpl(const T& arg, std::index_sequence<Is...>) { 86 86 printArgs(std::get<Is>(arg)...); 87 87 } 88 88 template <typename... Ts> 89 89 void printArgsApply(const std::tuple<Ts...>& arg) { 90 90 printArgsApplyImpl(arg, std::make_index_sequence<std::tuple_size<std::tuple<Ts...>>::value>()); 91 91 } 92 92 template <class... Ts> 93 93 void printArg(const std::tuple<Ts...>& arg) { 94 94 os << "{"; 95 95 printArgsApply(arg); 96 96 os << "}"; 97 97 } 98 98 99 99 template <class Arg, std::enable_if_t<is_container<Arg>::value && !is_string<Arg>::value>* = nullptr> 100 100 void printArg(const Arg& arg) { 101 101 const auto b = std::cbegin(arg), e = std::end(arg); 102 102 os << "{"; 103 103 for (auto i = b; i != e; ++i) { 104 104 if (i != b) 105 105 os << ", "; 106 106 printArgs(*i); 107 107 } 108 108 os << "}"; 109 109 } 110 110 111 111 template <class Arg> 112 112 void printArgs(const Arg& arg) { 113 113 printArg(arg); 114 114 } 115 115 116 116 template <class Arg, class... Args> 117 117 void printArgs(const Arg& arg, const Args&... args) { 118 118 printArgs(arg); 119 119 os << ", "; 120 120 printArgs(args...); 121 121 } 122 122 }; 123 123 124 124 template <class... Args> 125 125 void printInput(const char* name, const Args&... args) { 126 126 std::cout << name << "("; 127 127 ArgumentPrinter{std::cout}.printArgs(args...); 128 128 std::cout << ")\n"; 129 129 } 132 + 133 + 134 + #define DEFINE_STRINGIZER(type) \ 135 + namespace snowhouse {\ 136 + template <> struct Stringizer<type> {\ 137 + static std::string ToString(const type& x) {\ 138 + std::ostringstream oss;\ 139 + ArgumentPrinter{oss}.printArg(x);\ 140 + return oss.str();\ 141 + }\ 142 + };\ 143 + } 144 + 145 + #define COMMA , 146 + DEFINE_STRINGIZER(std::pair<int COMMA int>)