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這篇文章給大家介紹在c++于java項目中自定義Troop<T>泛型類達到方法,內容非常詳細,感興趣的小伙伴們可以參考借鑒,希望對大家能有所幫助。
Troop<T>是一個泛型列表操作類,適用于非高性能和非大數據量的要求。包括了:取值get,賦值set,追加append,插入insert,清除remove,進隊enqueue,出隊dequeue,交換swap,滾動roll,進棧push,出棧pop等日常操作。
//for more information, please access http://www.one-lab.net using System; using System.Collections.Generic; using System.Text; namespace onelab { public interface ISortable { void sort(bool decending); } public interface IStringable { int fromString(String input); String toString(); } public class Troop<T> : ICloneable { public override int GetHashCode() { return base.GetHashCode(); } public override bool Equals(object obj) { return this == (Troop<T>)obj; } public object Clone() { Troop<T> oValue = new Troop<T>(); oValue.cloneFrom(this); return oValue; } protected bool equalsTo(Troop<T> aValue) { int len = aValue.length(); if (len == this.length()) { for (int n = 0; n < len; n++) { if (!aValue.data[n].Equals(data[n])) return false; } return true; } return false; } protected void cloneFrom(Troop<T> aValue) { data.Clear(); data.AddRange(aValue.data); } public static bool operator ==(Troop<T> a0, Troop<T> a1) { object o1 = (object)a0; object o2 = (object)a1; if (o1 == null && o2 == null) return true; return (o1 == null || o2 == null) ? false : a0.equalsTo(a1); } public static bool operator !=(Troop<T> a0, Troop<T> a1) { object o1 = (object)a0; object o2 = (object)a1; if (o1 == null && o2 == null) return false; return (o1 == null || o2 == null) ? true : !a0.equalsTo(a1); } private bool mHasError = false; public bool hasError() { return mHasError; } public List<T> data = new List<T>(); public T get(int index) { mHasError = false; if (index >= 0 && index < data.Count) return data[index]; mHasError = true; return default(T); } public bool set(int index, T value) { if (index >= 0 && index < data.Count) { data[index] = value; return true; } return false; } public void append(T value) { data.Add(value); } public bool insert(int index, T value) { if (index >= 0 && index < data.Count) { data.Insert(index, value); return true; } return false; } public void appendRange(ref List<T> range) { data.AddRange(range); } public bool insertRange(int index, ref List<T> range) { if (index >= 0 && index < data.Count) { data.InsertRange(index, range); return true; } return false; } public void clear() { data.Clear(); } public bool remove(int index) { if (index >= 0 && index < data.Count) { data.RemoveAt(index); return true; } return false; } public bool removeRange(int index, int count) { if (count > 0 && index >= 0 && ((index + count) <= data.Count)) { data.RemoveRange(index, count); return true; } return false; } public int length() { return data.Count; } public void enqueue(T value) { data.Insert(0, value); } public T dequeue() { mHasError = false; int length = data.Count; if (length > 0) { T b = data[length - 1]; data.RemoveAt(length - 1); return b; } mHasError = true; return default(T); } public void push(T value) { data.Add(value); } public T pop() { return dequeue(); } public Troop<T> getRange(int index, int count) { Troop<T> output = new Troop<T>(); mHasError = true; if (count > 0 && index >= 0 && ((index + count) <= data.Count)) { output.data = data.GetRange(index, count); mHasError = false; } return output; } public void reverse() { data.Reverse(); } public bool swap(int index0, int index1) { int length = data.Count; if (index0 >= 0 && index0 < length && index1 >= 0 && index1 < length) { T v = data[index0]; data[index0] = data[index1]; data[index1] = v; return true; } return false; } public T take(int index) { mHasError = false; if (index >= 0 && index < data.Count) { T v = data[index]; data.RemoveAt(index); return v; } mHasError = true; return default(T); } public void rollForward(int offset) { if (offset >= data.Count) return; List<T> left = data.GetRange(offset - 1, data.Count - offset + 1); List<T> right = data.GetRange(0, offset - 1); data.Clear(); data.AddRange(left); data.AddRange(right); } public void rollBackward(int offset) { if (offset >= data.Count) return; List<T> left = data.GetRange(offset, data.Count - offset); List<T> right = data.GetRange(0, offset); data.Clear(); data.AddRange(left); data.AddRange(right); } } }
//for more information, please access http://www.one-lab.net #ifndef VALUES_H #define VALUES_H #include <QList> #include <QDebug> namespace onelab { class ISortable { public: virtual void sort(bool decending) = 0; }; template <typename T> class Troop { private: bool mHasError; static bool equals(const Troop<T> &from, const Troop<T> &to); public: QList<T> data; Troop(); T get(int index); bool set(int index, T value); void append(T value); bool insert(int index, T value); void appendRange(const QList<T>& range); bool insertRange(int index, const QList<T>& range); void clear(); bool remove(int index); bool removeRange(int index, int count); int length() const; void enqueue(T value); T dequeue(); void push(T value); T pop(); bool getRange(int index, int count, Troop<T>& output); void reverse(); bool swap(int index0, int index1); T take(int index); void rollForward(int offset); void rollBackward(int offset); bool operator==(const Troop& input) const; bool operator!=(const Troop& input) const; bool hasError() const; virtual QString toString(); virtual int fromString(const QString& input); }; } #endif // VALUES_H
//for more information, please access http://www.one-lab.net #include "values.h" #include <QStringList> #include <QDateTime> namespace onelab { template <typename T> bool Troop<T>::equals(const Troop<T> &from, const Troop<T> &to) { int len = from.length(); if (len == to.length()) { for (int n = 0; n < len; n++) { if (from.data[n] != to.data[n]) return false; } return true; } return false; } template <typename T> Troop<T>::Troop() { mHasError = false; } template <typename T> T Troop<T>::get(int index) { mHasError = false; if (index >= 0 && index < data.length()) return data[index]; mHasError = true; return (T)0; } template <typename T> bool Troop<T>::set(int index, T value) { if (index >= 0 && index < data.length()) { data[index] = value; return true; } return false; } template <typename T> void Troop<T>::append(T value) { data.append(value); } template <typename T> bool Troop<T>::insert(int index, T value) { if (index >= 0 && index < data.length()) { data.insert(index, value); return true; } return false; } template <typename T> void Troop<T>::appendRange(const QList<T> &range) { data.append(range); } template <typename T> bool Troop<T>::insertRange(int index, const QList<T> &range) { int length = data.length(); if (index >= 0 && index < length) { QList<T> left = data.mid(0, index); QList<T> right = data.mid(index, -1); left.append(range); data.clear(); data.append(left); data.append(right); return true; } return false; } template <typename T> void Troop<T>::clear() { data.clear(); } template <typename T> bool Troop<T>::remove(int index) { if (index >= 0 && index < data.length()) { data.removeAt(index); return true; } return false; } template <typename T> bool Troop<T>::removeRange(int index, int count) { if (count > 0 && index >= 0 && ((index + count) <= data.length())) { for (int n = 0; n < count; n++) data.removeAt(index); return true; } return false; } template <typename T> int Troop<T>::length() const { return data.length(); } template <typename T> void Troop<T>::enqueue(T value) { data.insert(0, value); } template <typename T> T Troop<T>::dequeue() { mHasError = false; int length = data.length(); if (length > 0) { T b = data[length - 1]; data.removeAt(length - 1); return b; } mHasError = true; return (T)0; } template <typename T> void Troop<T>::push(T value) { data.append(value); } template <typename T> T Troop<T>::pop() { return dequeue(); } template <typename T> bool Troop<T>::getRange(int index, int count, Troop<T>& output) { mHasError = true; if (count > 0 && index >= 0 && ((index + count) <= data.length())) { output.data = data.mid(index, count); mHasError = false; } return mHasError; } template <typename T> void Troop<T>::reverse() { int length = data.length(); QList<T> newData; for (int n = length - 1; n >= 0; n--) newData.append(data[n]); data.clear(); data = newData; } template <typename T> bool Troop<T>::swap(int index0, int index1) { int length = data.length(); if (index0 >= 0 && index0 < length && index1 >= 0 && index1 < length) { T v = data[index0]; data[index0] = data[index1]; data[index1] = v; return true; } return false; } template <typename T> T Troop<T>::take(int index) { mHasError = false; if (index >= 0 && index < data.length()) { T v = data[index]; data.removeAt(index); return v; } mHasError = true; return (T)0; } template <typename T> void Troop<T>::rollForward(int offset) { if (offset >= data.length()) return; QList<T> left = data.mid(offset - 1, -1); QList<T> right = data.mid(0, offset - 1); data.clear(); data.append(left); data.append(right); } template <typename T> void Troop<T>::rollBackward(int offset) { if (offset >= data.length()) return; QList<T> left = data.mid(offset, -1); QList<T> right = data.mid(0, offset); data.clear(); data.append(left); data.append(right); } template <typename T> bool Troop<T>::operator!=(const Troop& input) const { return !equals(input, *this); } template<typename T> bool Troop<T>::hasError() const { return mHasError; } template<typename T> QString Troop<T>::toString() { return QString(); } template<typename T> int Troop<T>::fromString(const QString&) { return 0; } template <typename T> bool Troop<T>::operator==(const Troop& input) const { return equals(input, *this); } } //for more information, please access http://www.one-lab.net package net.onelab; import java.util.ArrayList; public class Troop<T> implements Cloneable { public Object clone() { Troop<T> obj = new Troop<T>(); obj.data.addAll(data); return obj; } private boolean mHasError = false; public boolean hasError() { return mHasError; } public ArrayList<T> data = new ArrayList<T>(); public T get(int index) { mHasError = false; if (index >= 0 && index < data.size()) return data.get(index); mHasError = true; return null; } public boolean set(int index, T value) { if (index >= 0 && index < data.size()) { data.set(index, value); return true; } return false; } public void append(T value) { data.add(value); } public boolean insert(int index, T value) { if (index >= 0 && index < data.size()) { data.add(index, value); return true; } return false; } public void appendRange(ArrayList<T> range) { data.addAll(range); } public boolean insertRange(int index, ArrayList<T> range) { if (index >= 0 && index < data.size()) { data.addAll(index, range); return true; } return false; } public void clear() { data.clear(); } public boolean remove(int index) { if (index >= 0 && index < data.size()) { data.remove(index); return true; } return false; } public boolean removeRange(int index, int count) { if (count > 0 && index >= 0 && ((index + count) <= data.size())) { for (int n = 0; n < count; n++) data.remove(index); return true; } return false; } public int length() { return data.size(); } public void enqueue(T value) { data.add(0, value); } public T dequeue() { mHasError = false; int length = data.size(); if (length > 0) { T b = data.get(length - 1); data.remove(length - 1); return b; } mHasError = true; return null; } public void push(T value) { data.add(value); } public T pop() { return dequeue(); } public Troop<T> getRange(int index, int count) { mHasError = true; Troop<T> output = new Troop<T>(); if (count > 0 && index >= 0 && ((index + count) <= data.size())) { output.data.addAll(data.subList(index, index + count)); mHasError = false; } return output; } public void reverse() { int length = data.size(); ArrayList<T> newData = new ArrayList<T>(); for (int n = length - 1; n >= 0; n--) newData.add(data.get(n)); data.clear(); data = newData; } boolean swap(int index0, int index1) { int length = data.size(); if (index0 >= 0 && index0 < length && index1 >= 0 && index1 < length) { T v = data.get(index0); data.set(index0, data.get(index1)); data.set(index1, v); return true; } return false; } T take(int index) { mHasError = false; if (index >= 0 && index < data.size()) { T v = data.get(index); data.remove(index); return v; } mHasError = true; return null; } void rollForward(int offset) { if (offset >= data.size()) return; ArrayList<T> left = new ArrayList<T>(); left.addAll(data.subList(offset - 1, data.size())); ArrayList<T> right = new ArrayList<T>(); right.addAll(data.subList(0, offset - 1)); data.clear(); data.addAll(left); data.addAll(right); } void rollBackward(int offset) { if (offset >= data.size()) return; ArrayList<T> left = new ArrayList<T>(); left.addAll(data.subList(offset, data.size())); ArrayList<T> right = new ArrayList<T>(); right.addAll(data.subList(0, offset)); data.clear(); data.addAll(left); data.addAll(right); } }
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