6.1

PartialWeight and partialValue for continuous case
Make continuous packing optional
2022-06-28 21:19:13 +02:00 · 2022-06-26 15:44:14 +02:00 · 2022-06-26 15:37:52 +02:00 · 2022-06-26 15:32:16 +02:00 · 2022-06-26 15:29:55 +02:00
12 changed files with 514 additions and 0 deletions
--- a/5/Uebung5_3/Makefile
+++ b/5/Uebung5_3/Makefile
@ -0,0 +1,52 @@
 # Name of the binary for Development
 BINARY = main
 # Name of the binary for Release
 FINAL = prototyp
 # Object files
 OBJS   = backpack.o item.o main.o
 # Compiler flags
 CFLAGS = -Werror -Wall -std=c++17 -fsanitize=address,undefined -g
 # Linker flags
 LFLAGS = -fsanitize=address,undefined
 #Which Compiler to use
 COMPILER = c++
 # all target: builds all important targets
 all: binary
 final : ${OBJS}
 	${COMPILER} ${LFLAGS} -o ${FINAL} ${OBJS}
 	rm ${OBJS}
 binary : ${OBJS}
 	${COMPILER} ${LFLAGS} -o ${BINARY} ${OBJS}
 # Links the binary
 ${BINARY} : ${OBJS}
 	${COMPILER} ${LFLAGS} -o ${BINARY} ${OBJS}
 # Compiles a source-file (any file with file extension .c) into an object-file
 #
 # "%" is a wildcard which matches every file-name (similar to * in regular expressions)
 # Such a rule is called a pattern rule (because it matches a pattern, see https://www.gnu.org/software/make/manual/html_node/Pattern-Rules.html),
 # which are a form of so called implicit rules (see https://www.gnu.org/software/make/manual/html_node/Implicit-Rules.html)
 # "$@" and "$<" are so called automatic variables (see https://www.gnu.org/software/make/manual/html_node/Automatic-Variables.html)
 %.o : %.cpp
 	${COMPILER} -c ${CFLAGS} -o $@ $<
 # Rules can not only be used for compiling a program but also for executing a program
 run: ${BINARY}
 	./${BINARY}
 # Delete all build artifacts
 clean :
 	rm -rf ${BINARY} ${OBJS}
 # all  and clean are a "phony" targets, meaning they are no files
 .PHONY : all clean
--- a/5/Uebung5_3/backpack.cpp
+++ b/5/Uebung5_3/backpack.cpp
@ -0,0 +1,91 @@
 #include "backpack.h"
 #include <algorithm>
 #include <cmath>
 /*  Optimized insertion sort algorithm utilizing the Item's getRatio() function
 */
 void Backpack::sortAvailableItems() {
  int i = 0;
  while (i < (int)this->availableItems.size()) {
    Item x = this->availableItems[i];
    int j = i - 1;
    while (j >= 0 && this->availableItems[j].getRatio() < x.getRatio()) {
      this->availableItems[j + 1] = this->availableItems[j];
      j--;
    }
    this->availableItems[j + 1] = x;
    i++;
  }
 }
 /*  Iterates through all packed items and returns the total value   */
 int Backpack::getValuePacked() {
  int total = 0;
  for (int i = 0; i < (int)this->packedItems.size(); i++) {
    total += this->packedItems[i].value;
  }
  return total;
 }
 /*  the algorithm to pack the backpack  */
 void Backpack::greedyPack(bool continuous) {
  this->packedItems
      .clear(); /*  resets the packedItems -> removes all elements! */
  this->currentWeight = 0; /*  ...and also sets the current weight to 0.0  */
  this->sortAvailableItems(); //  sort the available items first!
  const char *text = "";
  float partialValue = 0.0f;
  float partialWeight = 0.0f;
  if (!continuous) {
    text = "non-";
  }
  std::cout << "Backpack has been packed " << text
            << "continuously:\n";                                 //  output
  std::cout << "\t\tWeight\tValue\n";                             //  output
  std::cout << "---------------------------------------------\n"; //  output
  for (int i = 0; i < (int)this->availableItems.size();
       i++) { //  iterate through all available items
    if (this->currentWeight + (float)this->availableItems[i].weight <=
        this->maxWeight) { //  check if the item still fits in the backpack
      this->packedItems.push_back(
          this->availableItems[i]); //  and if so, put it in there (by adding it
                                    //  to this->packedItems)
      currentWeight +=
          this->availableItems[i].weight; //  adjust currentWeight accordingly
      std::cout << "\t" << this->availableItems[i].name << ":\t"
                << this->availableItems[i].weight << "\t"
                << this->availableItems[i].value
                << "\t Factor: 1.00\n"; //  output
    } else if (continuous) {
      float factor = (float)(this->maxWeight - this->currentWeight) /
                     this->availableItems[i].weight;
      factor = std::round(factor * 100) / 100;
      std::cout << "\t" << this->availableItems[i].name << ":\t"
                << this->availableItems[i].weight << "\t"
                << this->availableItems[i].value << "\t Factor: " << factor
                << std::endl;
      partialWeight = this->availableItems[i].weight * factor;
      partialValue = this->availableItems[i].value * factor;
      break;
    }
    if ((this->currentWeight - this->maxWeight) ==
        0) { //  if the backpack is completely full, the loop can be exited -
             //  small optimization
      break;
    }
  }
  std::cout << "---------------------------------------------\n"; //  output
  std::cout << "\tTotal:\t" << this->currentWeight + partialWeight << "\t"
            << this->getValuePacked() + partialValue << "\n"; //  output
 }
 void Backpack::printItems() {
  for (int i = 0; i < (int)this->availableItems.size(); i++) {
    std::cout << this->availableItems[i].name << "\t"
              << this->availableItems[i].weight << "\t"
              << this->availableItems[i].value << "\t"
              << this->availableItems[i].getRatio() << "\n";
  }
 }
--- a/5/Uebung5_3/backpack.h
+++ b/5/Uebung5_3/backpack.h
@ -0,0 +1,31 @@
 #include <iostream>
 #include <string>
 #include <vector>
 #include "item.h"
 #pragma once
 /*  Class for Backpack, consisting of a maxWeight that can be put into a
   backpack, one that shows the weight that is currently in the backpack, a
   vector representing all available items and a vector for the items that have
   been placed in the backpack. There is also a constructor to increase the
   ease/convenience of use, as well as functions to:
        * sort the available Items based on their getRatio()
        * greedily pack the backpack
        * get the value of all packed items
 */
 struct Backpack {
  int maxWeight;
  std::vector<Item> availableItems;
  int currentWeight;
  std::vector<Item> packedItems;
  Backpack(float maxWeight, std::vector<Item> availableItems)
      : maxWeight(maxWeight), availableItems(availableItems),
        currentWeight(0){};
  void sortAvailableItems();
  void greedyPack(bool continuous);
  int getValuePacked();
  void printItems();
 };
--- a/5/Uebung5_3/item.cpp
+++ b/5/Uebung5_3/item.cpp
@ -0,0 +1,5 @@
 #include "item.h"
 /*  function that returns the value/weight ratio of an item as float; used to
 * sort items    */
 float Item::getRatio() { return ((float)this->value / (float)this->weight); };
--- a/5/Uebung5_3/item.h
+++ b/5/Uebung5_3/item.h
@ -0,0 +1,17 @@
 #include <string>
 #pragma once
 /*  Class for Item, containing name (string), value (int) and weight (int).
    There is also a constructor that can be called with all member variables to
    increase convenience. The getRatio() function returns the value/weight ratio
 */
 class Item {
 public:
  std::string name;
  int weight;
  int value;
  Item(std::string name, int weight, int value)
      : name(name), weight(weight), value(value){};
  float getRatio();
 };
--- a/5/Uebung5_3/main.cpp
+++ b/5/Uebung5_3/main.cpp
@ -0,0 +1,15 @@
 #include "backpack.h"
 #include "item.h"
 #include <vector>
 int main() {
  std::vector<Item> items = {//  creation of the availableItems
                             {"1", 5, 8},   {"2", 5, 8},   {"3", 6, 6},
                             {"4", 8, 5},   {"5", 10, 10}, {"6", 11, 5},
                             {"7", 12, 10}, {"8", 15, 17}, {"9", 15, 20},
                             {"10", 30, 20}};
  Backpack bp((float)24,
              items);   //  creation of the backpack, utilizing the constructor
  bp.greedyPack(false); //  greedily pack Backpack non-continuously
  bp.greedyPack(true);  // greedily pack Backpack continuously
 }
--- a/6/Uebung6_1/Makefile
+++ b/6/Uebung6_1/Makefile
@ -0,0 +1,52 @@
 # Name of the binary for Development
 BINARY = main
 # Name of the binary for Release
 FINAL = prototyp
 # Object files
 OBJS   = mergeSortRand.o helperFunctions.o main.o
 # Compiler flags
 CFLAGS = -Werror -Wall -std=c++17 -g#-fsanitize=address,undefined -g
 # Linker flags
 LFLAGS = #-fsanitize=address,undefined
 #Which Compiler to use
 COMPILER = g++
 # all target: builds all important targets
 all: binary
 final : ${OBJS}
 	${COMPILER} ${LFLAGS} -o ${FINAL} ${OBJS}
 	rm ${OBJS}
 binary : ${OBJS}
 	${COMPILER} ${LFLAGS} -o ${BINARY} ${OBJS}
 # Links the binary
 ${BINARY} : ${OBJS}
 	${COMPILER} ${LFLAGS} -o ${BINARY} ${OBJS}
 # Compiles a source-file (any file with file extension .c) into an object-file
 #
 # "%" is a wildcard which matches every file-name (similar to * in regular expressions)
 # Such a rule is called a pattern rule (because it matches a pattern, see https://www.gnu.org/software/make/manual/html_node/Pattern-Rules.html),
 # which are a form of so called implicit rules (see https://www.gnu.org/software/make/manual/html_node/Implicit-Rules.html)
 # "$@" and "$<" are so called automatic variables (see https://www.gnu.org/software/make/manual/html_node/Automatic-Variables.html)
 %.o : %.cpp
 	${COMPILER} -c ${CFLAGS} -o $@ $<
 # Rules can not only be used for compiling a program but also for executing a program
 run: ${BINARY}
 	./${BINARY}
 # Delete all build artifacts
 clean :
 	rm -rf ${BINARY} ${OBJS}
 # all  and clean are a "phony" targets, meaning they are no files
 .PHONY : all clean
--- a/6/Uebung6_1/helperFunctions.cpp
+++ b/6/Uebung6_1/helperFunctions.cpp
@ -0,0 +1,20 @@
 #include "helperFunctions.h"
 #include <ctime>
 void printArray(int* array, int arrayLength, std::string heading) {
    std::cout << "========== " << heading << " ==========" << std::endl;
    for(int i = 0; i < arrayLength; i++) {
        if(i > 0) {
            std::cout << " - ";
        }
        std::cout << array[i];
    }
    std::cout << std::endl << "==============================================" << std::endl;
 }
 void generateRandomIntArray(int* array, int arrayLength) {
    std::srand(std::time(NULL));
    for(int i = 0; i < arrayLength; i++) {
        array[i] = rand() % 100000 + 1;
    }
 }
--- a/6/Uebung6_1/helperFunctions.h
+++ b/6/Uebung6_1/helperFunctions.h
@ -0,0 +1,7 @@
 #include <string>
 #include <iostream>
 #pragma once
 void generateRandomIntArray(int* array, int arrayLength);
 void printArray(int* array, int arrayLength, std::string heading);
--- a/6/Uebung6_1/main.cpp
+++ b/6/Uebung6_1/main.cpp
@ -0,0 +1,157 @@
 #include <iostream>
 #include <string>
 #include "helperFunctions.h"
 #include "mergeSortRand.h"
 #include <vector>
 #define ARRAY_LENGTH 10
 class PerformanceTest {
 private:
  double minExecutionTime;
  double maxExecutionTime;
  double totalExecutionTime;
  std::string algorithmName;
 public:
  PerformanceTest() {
    this->minExecutionTime = 1000;
    this->maxExecutionTime = 0;
    this->totalExecutionTime = 0;
    this->algorithmName = "";
  };
  double getMinExecutionTime() { return this->minExecutionTime; }
  double getMaxExecutionTime() { return this->maxExecutionTime; }
  double getTotalExecutionTime() { return this->totalExecutionTime; }
  const std::string &getAlgorithmName() { return this->algorithmName; }
  void setAlgorithmName(std::string name) { this->algorithmName = name; }
  void processResult(std::chrono::high_resolution_clock::time_point startTime,
                     std::chrono::high_resolution_clock::time_point endTime) {
    std::chrono::duration<double, std::milli> duration = (endTime - startTime);
    double execTime = duration.count();
    this->totalExecutionTime += execTime;
    if (execTime < this->minExecutionTime) {
      this->minExecutionTime = execTime;
      return;
    } else if (execTime > this->maxExecutionTime) {
      this->maxExecutionTime = execTime;
      return;
    }
  }
 };
 class PerformanceComparison {
 private:
  int *baseArray;
  int arrayLength;
  int testsetSize;
  std::vector<PerformanceTest *> testResults;
 public:
  PerformanceComparison(int arrayLength, int testsetSize) {
    this->arrayLength = arrayLength;
    this->testsetSize = testsetSize;
    this->baseArray =
        (int *)malloc(sizeof(int) * this->arrayLength * this->testsetSize);
    generateRandomIntArray(this->baseArray,
                           this->arrayLength * this->testsetSize);
  }
  ~PerformanceComparison() {
    free(this->baseArray);
    for (int i = 0; i < this->testResults.size(); i++) {
      free(testResults[i]);
    }
  }
  void runTest(int algorithm) {
    PerformanceTest *pt = new PerformanceTest();
    if (algorithm == 1) {
      pt->setAlgorithmName("MergeSort");
      for (int i = 0; i < this->testsetSize; i++) {
        int testArray[this->arrayLength];
        std::memcpy(testArray, this->baseArray + (this->arrayLength * i),
                    this->arrayLength * sizeof(int));
        auto startTime = std::chrono::high_resolution_clock::now();
        mergeSort(testArray, 0, arrayLength - 1);
        auto endTime = std::chrono::high_resolution_clock::now();
        pt->processResult(startTime, endTime);
      }
    } else if (algorithm == 2) {
      pt->setAlgorithmName("MergeSortRand");
      for (int i = 0; i < this->testsetSize; i++) {
        int testArray[this->arrayLength];
        std::memcpy(testArray, this->baseArray + (this->arrayLength * i),
                    this->arrayLength * sizeof(int));
        auto startTime = std::chrono::high_resolution_clock::now();
        mergeSortRand(testArray, 0, arrayLength - 1);
        auto endTime = std::chrono::high_resolution_clock::now();
        pt->processResult(startTime, endTime);
      }
    } else {
      std::cerr << "Algorithm not recognized!" << std::endl;
      exit(1);
    }
    this->testResults.push_back(pt);
  };
  void printComparison(int mode) {
    if (mode == 1) {
      std::cout << "Algorithm\t\tMIN\t\t\tMAX\t\t\tAVG\t\t\tTOTAL" << std::endl;
      for (int i = 0; i < this->testResults.size(); i++) {
        std::cout << this->testResults[i]->getAlgorithmName() << "\t\t"
                  << this->testResults[i]->getMinExecutionTime() << "\t\t"
                  << this->testResults[i]->getMaxExecutionTime() << "\t\t"
                  << this->testResults[i]->getTotalExecutionTime() /
                         this->testsetSize
                  << "\t\t" << this->testResults[i]->getTotalExecutionTime()
                  << std::endl;
      }
    } else if (mode == 2) {
      std::cout << "Algorithm\tTOTAL\t\tAVG" << std::endl;
      for (int i = 0; i < this->testResults.size(); i++) {
        std::cout << this->testResults[i]->getAlgorithmName() << "\t\t"
                  << this->testResults[i]->getTotalExecutionTime() << " \t\t"
                  << this->testResults[i]->getTotalExecutionTime() /
                         this->testsetSize
                  << std::endl;
      }
    } else {
      std::cerr << "Mode not recognized!" << std::endl;
      exit(1);
    }
  }
 };
 int main() {
  srand(time(0));
  int array[ARRAY_LENGTH];
  int array2[ARRAY_LENGTH];
  generateRandomIntArray(array, ARRAY_LENGTH);
  memcpy(array2, array, ARRAY_LENGTH * sizeof(int));
  printArray(array, ARRAY_LENGTH, "Unsortiertes Array");
  mergeSort(array, 0, ARRAY_LENGTH - 1);
  printArray(array, ARRAY_LENGTH, "Array nach MergeSort");
  mergeSortRand(array2, 0, ARRAY_LENGTH - 1);
  printArray(array2, ARRAY_LENGTH, "Array nach MergeSortRand");
  for (int i = 0; i < ARRAY_LENGTH; i++) {
    if (array[i] != array2[i]) {
      std::cout << "ERROR" << std::endl;
      exit(0);
    }
  }
  PerformanceComparison pc(10, 10000);
  pc.runTest(1);
  pc.runTest(2);
  pc.printComparison(1);
 }
--- a/6/Uebung6_1/mergeSortRand.cpp
+++ b/6/Uebung6_1/mergeSortRand.cpp
@ -0,0 +1,62 @@
 #include "mergeSortRand.h"
 //#include <cstdlib>
 #include <iostream>
 void merge(int array[], int left, int middle, int right) {
  int n1 = middle - left + 1;
  int n2 = right - middle;
  int leftArray[n1];
  int rightArray[n2];
  for (int i = 0; i < n1; i++) {
    leftArray[i] = array[left + i];
  }
  for (int j = 0; j < n2; j++) {
    rightArray[j] = array[middle + j + 1];
  }
  int k = 0, l = 0, m = left;
  while (k < n1 && l < n2) {
    if (leftArray[k] <= rightArray[l]) {
      array[m] = leftArray[k];
      k++;
    } else {
      array[m] = rightArray[l];
      l++;
    }
    m++;
  }
  while (k < n1) {
    array[m] = leftArray[k];
    k++;
    m++;
  }
  while (l < n2) {
    array[m] = rightArray[l];
    l++;
    m++;
  }
 }
 void mergeSortRand(int array[], int left, int right) {
  if (left < right) {
    int middle = (rand() % (right - left + 1)) + left;
    if (middle < left || middle > right) {
      std::cout << "ERROR2" << std::endl;
    }
    mergeSortRand(array, left, middle);
    mergeSortRand(array, middle + 1, right);
    merge(array, left, middle, right);
  }
 }
 void mergeSort(int array[], int left, int right) {
  if (left < right) {
    int middle = left + (right - left) / 2;
    mergeSort(array, left, middle);
    mergeSort(array, middle + 1, right);
    merge(array, left, middle, right);
  }
 }
--- a/6/Uebung6_1/mergeSortRand.h
+++ b/6/Uebung6_1/mergeSortRand.h
@ -0,0 +1,5 @@
 #pragma once
 void merge(int array[], int left, int middle, int right);
 void mergeSort(int array[], int left, int right);
 void mergeSortRand(int array[], int left, int right);
Author	SHA1	Message	Date
Samuel Oberhofer	a5563a4103	6.1	2022-06-28 21:19:13 +02:00
Samuel Oberhofer	cf6edcdff6	PartialWeight and partialValue for continuous case	2022-06-26 15:44:14 +02:00
Samuel Oberhofer	7dc503ca13	Make continuous packing optional	2022-06-26 15:37:52 +02:00
Samuel Oberhofer	8a95eb668b	Make Solution Continuous	2022-06-26 15:32:16 +02:00
Samuel Oberhofer	c9d5a7a84c	Initial 5_3	2022-06-26 15:29:55 +02:00