// // Copyright 2020 Electronic Arts Inc. // // TiberianDawn.DLL and RedAlert.dll and corresponding source code is free // software: you can redistribute it and/or modify it under the terms of // the GNU General Public License as published by the Free Software Foundation, // either version 3 of the License, or (at your option) any later version. // TiberianDawn.DLL and RedAlert.dll and corresponding source code is distributed // in the hope that it will be useful, but with permitted additional restrictions // under Section 7 of the GPL. See the GNU General Public License in LICENSE.TXT // distributed with this program. You should have received a copy of the // GNU General Public License along with permitted additional restrictions // with this program. If not, see https://github.com/electronicarts/CnC_Remastered_Collection /* $Header: /CounterStrike/VECTOR.H 1 3/03/97 10:26a Joe_bostic $ */ /*********************************************************************************************** *** C O N F I D E N T I A L --- W E S T W O O D S T U D I O S *** *********************************************************************************************** * * * Project Name : Command & Conquer * * * * File Name : VECTOR.H * * * * Programmer : Joe L. Bostic * * * * Start Date : 02/19/95 * * * * Last Update : March 13, 1995 [JLB] * * * *---------------------------------------------------------------------------------------------* * Functions: * * VectorClass::VectorClass -- Constructor for vector class. * * VectorClass::~VectorClass -- Default destructor for vector class. * * VectorClass::VectorClass -- Copy constructor for vector object. * * VectorClass::operator = -- The assignment operator. * * VectorClass::operator == -- Equality operator for vector objects. * * VectorClass::Clear -- Frees and clears the vector. * * VectorClass::Resize -- Changes the size of the vector. * * DynamicVectorClass::DynamicVectorClass -- Constructor for dynamic vector. * * DynamicVectorClass::Resize -- Changes the size of a dynamic vector. * * DynamicVectorClass::Add -- Add an element to the vector. * * DynamicVectorClass::Delete -- Remove the specified object from the vector. * * DynamicVectorClass::Delete -- Deletes the specified index from the vector. * * VectorClass::ID -- Pointer based conversion to index number. * * VectorClass::ID -- Finds object ID based on value. * * DynamicVectorClass::ID -- Find matching value in the dynamic vector. * * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ #ifndef VECTOR_H #define VECTOR_H #ifdef NEVER #ifndef false #define false 0 #endif #ifndef true #define true 1 #endif #endif #include #include // ST - 5/8/1029 //inline void * operator new(size_t , void * pointer) {return(pointer);} //inline void * operator new[](size_t , void * pointer) {return(pointer);} /************************************************************************** ** This is a general purpose vector class. A vector is defined by this ** class, as an array of arbitrary objects where the array can be dynamically ** sized. Because is deals with arbitrary object types, it can handle everything. ** As a result of this, it is not terribly efficient for integral objects (such ** as char or int). It will function correctly, but the copy constructor and ** equality operator could be highly optimized if the integral type were known. ** This efficiency can be implemented by deriving an integral vector template ** from this one in order to supply more efficient routines. */ template class VectorClass { public: VectorClass(NoInitClass const & ) {}; VectorClass(unsigned size=0, T const * array=0); VectorClass(VectorClass const &); // Copy constructor. virtual ~VectorClass(void); T & operator[](unsigned index) {return(Vector[index]);}; T const & operator[](unsigned index) const {return(Vector[index]);}; virtual VectorClass & operator =(VectorClass const &); // Assignment operator. virtual int operator == (VectorClass const &) const; // Equality operator. virtual int Resize(unsigned newsize, T const * array=0); virtual void Clear(void); unsigned Length(void) const {return VectorMax;}; virtual int ID(T const * ptr); // Pointer based identification. virtual int ID(T const & ptr); // Value based identification. protected: /* ** This is a pointer to the allocated vector array of elements. */ T * Vector; /* ** This is the maximum number of elements allowed in this vector. */ unsigned VectorMax; /* ** Does the vector data pointer refer to memory that this class has manually ** allocated? If so, then this class is responsible for deleting it. */ unsigned IsAllocated:1; }; /************************************************************************** ** This derivative vector class adds the concept of adding and deleting ** objects. The objects are packed to the beginning of the vector array. ** If this is instantiated for a class object, then the assignment operator ** and the equality operator must be supported. If the vector allocates its ** own memory, then the vector can grow if it runs out of room adding items. ** The growth rate is controlled by setting the growth step rate. A growth ** step rate of zero disallows growing. */ template class DynamicVectorClass : public VectorClass { public: DynamicVectorClass(unsigned size=0, T const * array=0); // Change maximum size of vector. virtual int Resize(unsigned newsize, T const * array=0); // Resets and frees the vector array. virtual void Clear(void) {ActiveCount = 0;VectorClass::Clear();}; // Fetch number of "allocated" vector objects. int Count(void) const {return(ActiveCount);}; // Add object to vector (growing as necessary). int Add(T const & object); int Add_Head(T const & object); // Delete object just like this from vector. int Delete(T const & object); // Delete object at this vector index. int Delete(int index); // Deletes all objects in the vector. void Delete_All(void) {ActiveCount = 0;}; // Set amount that vector grows by. int Set_Growth_Step(int step) {return(GrowthStep = step);}; // Fetch current growth step rate. int Growth_Step(void) {return GrowthStep;}; virtual int ID(T const * ptr) {return(VectorClass::ID(ptr));}; virtual int ID(T const & ptr); protected: /* ** This is a count of the number of active objects in this ** vector. The memory array often times is bigger than this ** value. */ int ActiveCount; /* ** If there is insufficient room in the vector array for a new ** object to be added, then the vector will grow by the number ** of objects specified by this value. This is controlled by ** the Set_Growth_Step() function. */ int GrowthStep; }; /************************************************************************** ** A fixed-size array of dynamic vectors. */ template class DynamicVectorArrayClass { public: static const int COUNT = COUNT; DynamicVectorArrayClass() : Active(DEFAULT) {} void Set_Active_Context(int active) { Active = active; } void Clear_All() { for (int i = FIRST; i < COUNT; ++i) { Clear(i); } } void Clear() { Clear(Active); } int Count() const { return Count(Active); } int Add(T const & object) { return Add(Active, object); } int Add_Head(T const & object) { return Add_Head(Active, object); } int Delete(T const & object) { return Delete(Active, object); } int Delete_All(T const & object) { int count = 0; for (int i = FIRST; i < COUNT; ++i) { count += Delete(i, object); } return count; } int Delete_All_Except(T const & object, int except) { int count = 0; for (int i = FIRST; i < COUNT; ++i) { if (except != i) { count += Delete(i, object); } } return count; } int Delete(int index) { return Delete(Active, index); } T & operator[](unsigned index) { return Collection[Active][index]; } T const & operator[](unsigned index) const { return Collection[Active][index]; } void Clear(int context) { Collection[context].Clear(); } int Count(int context) const { return Collection[context].Count(); } int Add(int context, T const & object) { return Collection[context].Add(object); } int Add_Head(int context, T const & object) { return Collection[context].Add(object); } int Delete(int context, T const & object) { return Collection[context].Delete(object); } int Delete(int context, int index) { return Collection[context].Delete(index); } DynamicVectorClass & Raw() { return Collection[Active]; } DynamicVectorClass & Raw(int context) { return Collection[context]; } private: DynamicVectorClass Collection[COUNT]; int Active; }; /************************************************************************** ** This is a derivative of a vector class that supports boolean flags. Since ** a boolean flag can be represented by a single bit, this class packs the ** array of boolean flags into an array of bytes containing 8 boolean values ** each. For large boolean arrays, this results in an 87.5% savings. Although ** the indexing "[]" operator is supported, DO NOT pass pointers to sub elements ** of this bit vector class. A pointer derived from the indexing operator is ** only valid until the next call. Because of this, only simple ** direct use of the "[]" operator is allowed. */ class BooleanVectorClass { public: BooleanVectorClass(unsigned size=0, unsigned char * array=0); BooleanVectorClass(BooleanVectorClass const & vector); // Assignment operator. BooleanVectorClass & operator =(BooleanVectorClass const & vector); // Equivalency operator. int operator == (BooleanVectorClass const & vector); // Fetch number of boolean objects in vector. int Length(void) {return BitCount;}; // Set all boolean values to false; void Reset(void); // Set all boolean values to true. void Set(void); // Resets vector to zero length (frees memory). void Clear(void); // Change size of this boolean vector. int Resize(unsigned size); // Fetch reference to specified index. bool const & operator[](int index) const { if (LastIndex != index) Fixup(index); return(Copy); }; bool & operator[](int index) { if (LastIndex != index) Fixup(index); return(Copy); }; // Quick check on boolean state. bool Is_True(int index) const { if (index == LastIndex) return(Copy); return(Get_Bit(&BitArray[0], index)); }; // Find first index that is false. int First_False(void) const { if (LastIndex != -1) Fixup(-1); int retval = First_False_Bit(&BitArray[0]); if (retval < BitCount) return(retval); /* ** Failure to find a false boolean value in the vector. Return this ** fact in the form of an invalid index number. */ return(-1); } // Find first index that is true. int First_True(void) const { if (LastIndex != -1) Fixup(-1); int retval = First_True_Bit(&BitArray[0]); if (retval < BitCount) return(retval); /* ** Failure to find a true boolean value in the vector. Return this ** fact in the form of an invalid index number. */ return(-1); } private: void Fixup(int index=-1) const; /* ** This is the number of boolean values in the vector. This value is ** not necessarily a multiple of 8, even though the underlying character ** vector contains a multiple of 8 bits. */ int BitCount; /* ** This is a referential copy of an element in the bit vector. The ** purpose of this copy is to allow normal reference access to this ** object (for speed reasons). This hides the bit packing scheme from ** the user of this class. */ bool Copy; /* ** This records the index of the value last fetched into the reference ** boolean variable. This index is used to properly restore the value ** when the reference copy needs updating. */ int LastIndex; /* ** This points to the allocated bitfield array. */ VectorClass BitArray; }; /*********************************************************************************************** * DynamicVectorClass::DynamicVectorClass -- Constructor for dynamic vector. * * * * This is the normal constructor for the dynamic vector class. It is similar to the normal * * vector class constructor. The vector is initialized to contain the number of elements * * specified in the "size" parameter. The memory is allocated from free store unless the * * optional array parameter is provided. In this case it will place the vector at the * * memory location specified. * * * * INPUT: size -- The maximum number of objects allowed in this vector. * * * * array -- Optional pointer to the memory area to place the vector at. * * * * OUTPUT: none * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template DynamicVectorClass::DynamicVectorClass(unsigned size, T const * array) : VectorClass(size, array) { GrowthStep = 10; ActiveCount = 0; } /*********************************************************************************************** * DynamicVectorClass::Resize -- Changes the size of a dynamic vector. * * * * Use this routine to change the size of the vector. The size changed is the maximum * * number of allocated objects within this vector. If a memory buffer is provided, then * * the vector will be located there. Otherwise, the memory will be allocated out of free * * store. * * * * INPUT: newsize -- The desired maximum size of this vector. * * * * array -- Optional pointer to a previously allocated memory array. * * * * OUTPUT: bool; Was vector successfully resized according to specifications? * * * * WARNINGS: Failure to resize the vector could be the result of lack of free store. * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template int DynamicVectorClass::Resize(unsigned newsize, T const * array) { if (VectorClass::Resize(newsize, array)) { if (Length() < (unsigned)ActiveCount) ActiveCount = Length(); return(true); } return(false); } /*********************************************************************************************** * DynamicVectorClass::ID -- Find matching value in the dynamic vector. * * * * Use this routine to find a matching object (by value) in the vector. Unlike the base * * class ID function of similar name, this one restricts the scan to the current number * * of valid objects. * * * * INPUT: object -- A reference to the object that a match is to be found in the * * vector. * * * * OUTPUT: Returns with the index number of the object that is equivalent to the one * * specified. If no equivalent object could be found then -1 is returned. * * * * WARNINGS: none * * * * HISTORY: * * 03/13/1995 JLB : Created. * *=============================================================================================*/ template int DynamicVectorClass::ID(T const & object) { for (int index = 0; index < Count(); index++) { if ((*this)[index] == object) return(index); } return(-1); } /*********************************************************************************************** * DynamicVectorClass::Add -- Add an element to the vector. * * * * Use this routine to add an element to the vector. The vector will automatically be * * resized to accomodate the new element IF the vector was allocated previously and the * * growth rate is not zero. * * * * INPUT: object -- Reference to the object that will be added to the vector. * * * * OUTPUT: bool; Was the object added successfully? If so, the object is added to the end * * of the vector. * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template int DynamicVectorClass::Add(T const & object) { if (ActiveCount >= (int)Length()) { if ((IsAllocated || !VectorMax) && GrowthStep > 0) { if (!Resize(Length() + GrowthStep)) { /* ** Failure to increase the size of the vector is an error condition. ** Return with the error flag. */ return(false); } } else { /* ** Increasing the size of this vector is not allowed! Bail this ** routine with the error code. */ return(false); } } /* ** There is room for the new object now. Add it to the end of the object vector. */ (*this)[ActiveCount++] = object; return(true); } /*********************************************************************************************** * DynamicVectorClass::Add_Head -- Adds element to head of the list. * * * * This routine will add the specified element to the head of the vector. If necessary, * * the vector will be expanded accordingly. * * * * INPUT: object -- Reference to the object to add to the head of this vector. * * * * OUTPUT: bool; Was the object added without error? * * * * WARNINGS: none * * * * HISTORY: * * 09/21/1995 JLB : Created. * *=============================================================================================*/ template int DynamicVectorClass::Add_Head(T const & object) { if (ActiveCount >= (int)Length()) { if ((IsAllocated || !VectorMax) && GrowthStep > 0) { if (!Resize(Length() + GrowthStep)) { /* ** Failure to increase the size of the vector is an error condition. ** Return with the error flag. */ return(false); } } else { /* ** Increasing the size of this vector is not allowed! Bail this ** routine with the error code. */ return(false); } } /* ** There is room for the new object now. Add it to the end of the object vector. */ if (ActiveCount) { memmove(&(*this)[1], &(*this)[0], ActiveCount * sizeof(T)); } (*this)[0] = object; ActiveCount++; // (*this)[ActiveCount++] = object; return(true); } /*********************************************************************************************** * DynamicVectorClass::Delete -- Remove the specified object from the vector. * * * * This routine will delete the object referenced from the vector. All objects in the * * vector that follow the one deleted will be moved "down" to fill the hole. * * * * INPUT: object -- Reference to the object in this vector that is to be deleted. * * * * OUTPUT: bool; Was the object deleted successfully? This should always be true. * * * * WARNINGS: Do no pass a reference to an object that is NOT part of this vector. The * * results of this are undefined and probably catastrophic. * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template int DynamicVectorClass::Delete(T const & object) { return(Delete(ID(object))); } /*********************************************************************************************** * DynamicVectorClass::Delete -- Deletes the specified index from the vector. * * * * Use this routine to delete the object at the specified index from the objects in the * * vector. This routine will move all the remaining objects "down" in order to fill the * * hole. * * * * INPUT: index -- The index number of the object in the vector that is to be deleted. * * * * OUTPUT: bool; Was the object index deleted successfully? Failure might mean that the index * * specified was out of bounds. * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template int DynamicVectorClass::Delete(int index) { if (index >= 0 && index < ActiveCount) { ActiveCount--; /* ** If there are any objects past the index that was deleted, copy those ** objects down in order to fill the hole. A simple memory copy is ** not sufficient since the vector could contain class objects that ** need to use the assignment operator for movement. */ for (int i = index; i < ActiveCount; i++) { (*this)[i] = (*this)[i + 1]; } return(true); } return(false); } /*********************************************************************************************** * VectorClass::VectorClass -- Constructor for vector class. * * * * This constructor for the vector class is passed the initial size of the vector and an * * optional pointer to a preallocated block of memory that the vector will be placed in. * * If this optional pointer is NULL (or not provided), then the vector is allocated out * * of free store (with the "new" operator). * * * * INPUT: size -- The number of elements to initialize this vector to. * * * * array -- Optional pointer to a previously allocated memory block to hold the * * vector. * * * * OUTPUT: none * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template VectorClass::VectorClass(unsigned size, T const * array) : Vector(0), VectorMax(size), IsAllocated(false) { /* ** Allocate the vector. The default constructor will be called for every ** object in this vector. */ if (size) { if (array) { Vector = new((void*)array) T[size]; } else { Vector = new T[size]; IsAllocated = true; } } } /*********************************************************************************************** * VectorClass::~VectorClass -- Default destructor for vector class. * * * * This is the default destructor for the vector class. It will deallocate any memory * * that it may have allocated. * * * * INPUT: none * * * * OUTPUT: none * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template VectorClass::~VectorClass(void) { VectorClass::Clear(); } /*********************************************************************************************** * VectorClass::VectorClass -- Copy constructor for vector object. * * * * This is the copy constructor for the vector class. It will duplicate the provided * * vector into the new vector being created. * * * * INPUT: vector -- Reference to the vector to use as a copy. * * * * OUTPUT: none * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template VectorClass::VectorClass(VectorClass const & vector) : Vector(0), VectorMax(0), IsAllocated(false) { *this = vector; } /*********************************************************************************************** * VectorClass::operator = -- The assignment operator. * * * * This the the assignment operator for vector objects. It will alter the existing lvalue * * vector to duplicate the rvalue one. * * * * INPUT: vector -- The rvalue vector to copy into the lvalue one. * * * * OUTPUT: Returns with reference to the newly copied vector. * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template VectorClass & VectorClass::operator =(VectorClass const & vector) { if (this != &vector) { Clear(); VectorMax = vector.Length(); if (VectorMax) { Vector = new T[VectorMax]; if (Vector) { IsAllocated = true; for (int index = 0; index < (int)VectorMax; index++) { Vector[index] = vector[index]; } } } else { Vector = 0; IsAllocated = false; } } return(*this); } /*********************************************************************************************** * VectorClass::operator == -- Equality operator for vector objects. * * * * This operator compares two vectors for equality. It does this by performing an object * * by object comparison between the two vectors. * * * * INPUT: vector -- The right vector expression. * * * * OUTPUT: bool; Are the two vectors essentially equal? (do they contain comparable elements * * in the same order?) * * * * WARNINGS: The equality operator must exist for the objects that this vector contains. * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template int VectorClass::operator == (VectorClass const & vector) const { if (VectorMax == vector.Length()) { for (int index = 0; index < (int)VectorMax; index++) { if (Vector[index] != vector[index]) { return(false); } } return(true); } return(false); } /*********************************************************************************************** * VectorClass::ID -- Pointer based conversion to index number. * * * * Use this routine to convert a pointer to an element in the vector back into the index * * number of that object. This routine ONLY works with actual pointers to object within * * the vector. For "equivalent" object index number (such as with similar integral values) * * then use the "by value" index number ID function. * * * * INPUT: pointer -- Pointer to an actual object in the vector. * * * * OUTPUT: Returns with the index number for the object pointed to by the parameter. * * * * WARNINGS: This routine is only valid for actual pointers to object that exist within * * the vector. All other object pointers will yield undefined results. * * * * HISTORY: * * 03/13/1995 JLB : Created. * *=============================================================================================*/ template inline int VectorClass::ID(T const * ptr) { return(((unsigned long)ptr - (unsigned long)&(*this)[0]) / sizeof(T)); } /*********************************************************************************************** * VectorClass::ID -- Finds object ID based on value. * * * * Use this routine to find the index value of an object with equivalent value in the * * vector. Typical use of this would be for integral types. * * * * INPUT: object -- Reference to the object that is to be looked up in the vector. * * * * OUTPUT: Returns with the index number of the object that is equivalent to the one * * specified. If no matching value could be found then -1 is returned. * * * * WARNINGS: none * * * * HISTORY: * * 03/13/1995 JLB : Created. * *=============================================================================================*/ template int VectorClass::ID(T const & object) { for (int index = 0; index < (int)VectorMax; index++) { if ((*this)[index] == object) { return(index); } } return(-1); } /*********************************************************************************************** * VectorClass::Clear -- Frees and clears the vector. * * * * Use this routine to reset the vector to an empty (non-allocated) state. A vector will * * free all allocated memory when this routine is called. In order for the vector to be * * useful after this point, the Resize function must be called to give it element space. * * * * INPUT: none * * * * OUTPUT: none * * * * WARNINGS: none * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template void VectorClass::Clear(void) { if (Vector && IsAllocated) { delete[] Vector; Vector = 0; } IsAllocated = false; VectorMax = 0; } /*********************************************************************************************** * VectorClass::Resize -- Changes the size of the vector. * * * * This routine is used to change the size (usually to increase) the size of a vector. This * * is the only way to increase the vector's working room (number of elements). * * * * INPUT: newsize -- The desired size of the vector. * * * * array -- Optional pointer to a previously allocated memory block that the * * array will be located in. If this parameter is not supplied, then * * the array will be allocated from free store. * * * * OUTPUT: bool; Was the array resized successfully? * * * * WARNINGS: Failure to succeed could be the result of running out of memory. * * * * HISTORY: * * 03/10/1995 JLB : Created. * *=============================================================================================*/ template int VectorClass::Resize(unsigned newsize, T const * array) { if (newsize) { /* ** Allocate a new vector of the size specified. The default constructor ** will be called for every object in this vector. */ T * newptr; if (!array) { newptr = new T[newsize]; } else { newptr = new((void*)array) T[newsize]; } if (!newptr) { return(false); } /* ** If there is an old vector, then it must be copied (as much as is feasible) ** to the new vector. */ if (Vector) { /* ** Copy as much of the old vector into the new vector as possible. This ** presumes that there is a functional assignment operator for each ** of the objects in the vector. */ int copycount = (newsize < VectorMax) ? newsize : VectorMax; for (int index = 0; index < copycount; index++) { newptr[index] = Vector[index]; } /* ** Delete the old vector. This might cause the destructors to be called ** for all of the old elements. This makes the implementation of suitable ** assignment operator very important. The default assignment operator will ** only work for the simplest of objects. */ if (IsAllocated) { delete[] Vector; Vector = 0; } } /* ** Assign the new vector data to this class. */ Vector = newptr; VectorMax = newsize; IsAllocated = (Vector && !array); } else { /* ** Resizing to zero is the same as clearing the vector. */ Clear(); } return(true); } #endif