/********************************************************************** * File: clst.h (Formerly clist.h) * Description: CONS cell list module include file. * Author: Phil Cheatle * * (C) Copyright 1991, Hewlett-Packard Ltd. ** Licensed under the Apache License, Version 2.0 (the "License"); ** you may not use this file except in compliance with the License. ** You may obtain a copy of the License at ** http://www.apache.org/licenses/LICENSE-2.0 ** Unless required by applicable law or agreed to in writing, software ** distributed under the License is distributed on an "AS IS" BASIS, ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. ** See the License for the specific language governing permissions and ** limitations under the License. * **********************************************************************/ #ifndef CLST_H #define CLST_H #include #include "serialis.h" #include "lsterr.h" class CLIST_ITERATOR; /********************************************************************** * CLASS - CLIST_LINK * * Generic link class for singly linked CONS cell lists * * Note: No destructor - elements are assumed to be destroyed EITHER after * they have been extracted from a list OR by the CLIST destructor which * walks the list. **********************************************************************/ class DLLSYM CLIST_LINK { friend class CLIST_ITERATOR; friend class CLIST; CLIST_LINK *next; void *data; public: CLIST_LINK() { //constructor data = next = nullptr; } CLIST_LINK( // copy constructor const CLIST_LINK &) { // don't copy link data = next = nullptr; } void operator=( // don't copy links const CLIST_LINK &) { data = next = nullptr; } }; /********************************************************************** * CLASS - CLIST * * Generic list class for singly linked CONS cell lists **********************************************************************/ class DLLSYM CLIST { friend class CLIST_ITERATOR; CLIST_LINK *last; //End of list //(Points to head) CLIST_LINK *First() { // return first return last != nullptr ? last->next : nullptr; } public: CLIST() { //constructor last = nullptr; } ~CLIST () { //destructor shallow_clear(); } void internal_deep_clear ( //destroy all links void (*zapper) (void *)); //ptr to zapper functn void shallow_clear(); // clear list but don't // delete data elements bool empty() const { //is list empty? return !last; } bool singleton() const { return last != nullptr ? (last == last->next) : false; } void shallow_copy( //dangerous!! CLIST *from_list) { //beware destructors!! last = from_list->last; } void assign_to_sublist( //to this list CLIST_ITERATOR *start_it, //from list start CLIST_ITERATOR *end_it); //from list end int32_t length() const; //# elements in list void sort ( //sort elements int comparator ( //comparison routine const void *, const void *)); // Assuming list has been sorted already, insert new_data to // keep the list sorted according to the same comparison function. // Comparison function is the same as used by sort, i.e. uses double // indirection. Time is O(1) to add to beginning or end. // Time is linear to add pre-sorted items to an empty list. // If unique, then don't add duplicate entries. // Returns true if the element was added to the list. bool add_sorted(int comparator(const void*, const void*), bool unique, void* new_data); // Assuming that the minuend and subtrahend are already sorted with // the same comparison function, shallow clears this and then copies // the set difference minuend - subtrahend to this, being the elements // of minuend that do not compare equal to anything in subtrahend. // If unique is true, any duplicates in minuend are also eliminated. void set_subtract(int comparator(const void*, const void*), bool unique, CLIST* minuend, CLIST* subtrahend); }; /*********************************************************************** * CLASS - CLIST_ITERATOR * * Generic iterator class for singly linked lists with embedded *links **********************************************************************/ class DLLSYM CLIST_ITERATOR { friend void CLIST::assign_to_sublist(CLIST_ITERATOR *, CLIST_ITERATOR *); CLIST *list; //List being iterated CLIST_LINK *prev; //prev element CLIST_LINK *current; //current element CLIST_LINK *next; //next element CLIST_LINK *cycle_pt; //point we are cycling the list to. bool ex_current_was_last; //current extracted was end of list bool ex_current_was_cycle_pt; //current extracted was cycle point bool started_cycling; //Have we moved off the start? CLIST_LINK *extract_sublist( //from this current... CLIST_ITERATOR *other_it); //to other current public: CLIST_ITERATOR() { //constructor list = nullptr; } //unassigned list CLIST_ITERATOR( //constructor CLIST *list_to_iterate); void set_to_list( //change list CLIST *list_to_iterate); void add_after_then_move( //add after current & void *new_data); //move to new void add_after_stay_put( //add after current & void *new_data); //stay at current void add_before_then_move( //add before current & void *new_data); //move to new void add_before_stay_put( //add before current & void *new_data); //stay at current void add_list_after( //add a list & CLIST *list_to_add); //stay at current void add_list_before( //add a list & CLIST *list_to_add); //move to it 1st item void *data() { //get current data #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::data", ABORT, nullptr); if (!current) NULL_DATA.error ("CLIST_ITERATOR::data", ABORT, nullptr); #endif return current->data; } void *data_relative( //get data + or - ... int8_t offset); //offset from current void *forward(); //move to next element void *extract(); //remove from list void *move_to_first(); //go to start of list void *move_to_last(); //go to end of list void mark_cycle_pt(); //remember current bool empty() { //is list empty? #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::empty", ABORT, nullptr); #endif return list->empty (); } bool current_extracted() { //current extracted? return !current; } bool at_first(); //Current is first? bool at_last(); //Current is last? bool cycled_list(); //Completed a cycle? void add_to_end( // add at end & void *new_data); // don't move void exchange( //positions of 2 links CLIST_ITERATOR *other_it); //other iterator int32_t length(); //# elements in list void sort ( //sort elements int comparator ( //comparison routine const void *, const void *)); }; /*********************************************************************** * CLIST_ITERATOR::set_to_list * * (Re-)initialise the iterator to point to the start of the list_to_iterate * over. **********************************************************************/ inline void CLIST_ITERATOR::set_to_list( //change list CLIST *list_to_iterate) { #ifndef NDEBUG if (!list_to_iterate) BAD_PARAMETER.error ("CLIST_ITERATOR::set_to_list", ABORT, "list_to_iterate is nullptr"); #endif list = list_to_iterate; prev = list->last; current = list->First (); next = current != nullptr ? current->next : nullptr; cycle_pt = nullptr; //await explicit set started_cycling = false; ex_current_was_last = false; ex_current_was_cycle_pt = false; } /*********************************************************************** * CLIST_ITERATOR::CLIST_ITERATOR * * CONSTRUCTOR - set iterator to specified list; **********************************************************************/ inline CLIST_ITERATOR::CLIST_ITERATOR(CLIST *list_to_iterate) { set_to_list(list_to_iterate); } /*********************************************************************** * CLIST_ITERATOR::add_after_then_move * * Add a new element to the list after the current element and move the * iterator to the new element. **********************************************************************/ inline void CLIST_ITERATOR::add_after_then_move( // element to add void *new_data) { CLIST_LINK *new_element; #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::add_after_then_move", ABORT, nullptr); if (!new_data) BAD_PARAMETER.error ("CLIST_ITERATOR::add_after_then_move", ABORT, "new_data is nullptr"); #endif new_element = new CLIST_LINK; new_element->data = new_data; if (list->empty ()) { new_element->next = new_element; list->last = new_element; prev = next = new_element; } else { new_element->next = next; if (current) { //not extracted current->next = new_element; prev = current; if (current == list->last) list->last = new_element; } else { //current extracted prev->next = new_element; if (ex_current_was_last) list->last = new_element; if (ex_current_was_cycle_pt) cycle_pt = new_element; } } current = new_element; } /*********************************************************************** * CLIST_ITERATOR::add_after_stay_put * * Add a new element to the list after the current element but do not move * the iterator to the new element. **********************************************************************/ inline void CLIST_ITERATOR::add_after_stay_put( // element to add void *new_data) { CLIST_LINK *new_element; #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::add_after_stay_put", ABORT, nullptr); if (!new_data) BAD_PARAMETER.error ("CLIST_ITERATOR::add_after_stay_put", ABORT, "new_data is nullptr"); #endif new_element = new CLIST_LINK; new_element->data = new_data; if (list->empty ()) { new_element->next = new_element; list->last = new_element; prev = next = new_element; ex_current_was_last = false; current = nullptr; } else { new_element->next = next; if (current) { //not extracted current->next = new_element; if (prev == current) prev = new_element; if (current == list->last) list->last = new_element; } else { //current extracted prev->next = new_element; if (ex_current_was_last) { list->last = new_element; ex_current_was_last = false; } } next = new_element; } } /*********************************************************************** * CLIST_ITERATOR::add_before_then_move * * Add a new element to the list before the current element and move the * iterator to the new element. **********************************************************************/ inline void CLIST_ITERATOR::add_before_then_move( // element to add void *new_data) { CLIST_LINK *new_element; #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::add_before_then_move", ABORT, nullptr); if (!new_data) BAD_PARAMETER.error ("CLIST_ITERATOR::add_before_then_move", ABORT, "new_data is nullptr"); #endif new_element = new CLIST_LINK; new_element->data = new_data; if (list->empty ()) { new_element->next = new_element; list->last = new_element; prev = next = new_element; } else { prev->next = new_element; if (current) { //not extracted new_element->next = current; next = current; } else { //current extracted new_element->next = next; if (ex_current_was_last) list->last = new_element; if (ex_current_was_cycle_pt) cycle_pt = new_element; } } current = new_element; } /*********************************************************************** * CLIST_ITERATOR::add_before_stay_put * * Add a new element to the list before the current element but don't move the * iterator to the new element. **********************************************************************/ inline void CLIST_ITERATOR::add_before_stay_put( // element to add void *new_data) { CLIST_LINK *new_element; #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::add_before_stay_put", ABORT, nullptr); if (!new_data) BAD_PARAMETER.error ("CLIST_ITERATOR::add_before_stay_put", ABORT, "new_data is nullptr"); #endif new_element = new CLIST_LINK; new_element->data = new_data; if (list->empty ()) { new_element->next = new_element; list->last = new_element; prev = next = new_element; ex_current_was_last = true; current = nullptr; } else { prev->next = new_element; if (current) { //not extracted new_element->next = current; if (next == current) next = new_element; } else { //current extracted new_element->next = next; if (ex_current_was_last) list->last = new_element; } prev = new_element; } } /*********************************************************************** * CLIST_ITERATOR::add_list_after * * Insert another list to this list after the current element but don't move *the * iterator. **********************************************************************/ inline void CLIST_ITERATOR::add_list_after(CLIST *list_to_add) { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::add_list_after", ABORT, nullptr); if (!list_to_add) BAD_PARAMETER.error ("CLIST_ITERATOR::add_list_after", ABORT, "list_to_add is nullptr"); #endif if (!list_to_add->empty ()) { if (list->empty ()) { list->last = list_to_add->last; prev = list->last; next = list->First (); ex_current_was_last = true; current = nullptr; } else { if (current) { //not extracted current->next = list_to_add->First (); if (current == list->last) list->last = list_to_add->last; list_to_add->last->next = next; next = current->next; } else { //current extracted prev->next = list_to_add->First (); if (ex_current_was_last) { list->last = list_to_add->last; ex_current_was_last = false; } list_to_add->last->next = next; next = prev->next; } } list_to_add->last = nullptr; } } /*********************************************************************** * CLIST_ITERATOR::add_list_before * * Insert another list to this list before the current element. Move the * iterator to the start of the inserted elements * iterator. **********************************************************************/ inline void CLIST_ITERATOR::add_list_before(CLIST *list_to_add) { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::add_list_before", ABORT, nullptr); if (!list_to_add) BAD_PARAMETER.error ("CLIST_ITERATOR::add_list_before", ABORT, "list_to_add is nullptr"); #endif if (!list_to_add->empty ()) { if (list->empty ()) { list->last = list_to_add->last; prev = list->last; current = list->First (); next = current->next; ex_current_was_last = false; } else { prev->next = list_to_add->First (); if (current) { //not extracted list_to_add->last->next = current; } else { //current extracted list_to_add->last->next = next; if (ex_current_was_last) list->last = list_to_add->last; if (ex_current_was_cycle_pt) cycle_pt = prev->next; } current = prev->next; next = current->next; } list_to_add->last = nullptr; } } /*********************************************************************** * CLIST_ITERATOR::extract * * Do extraction by removing current from the list, deleting the cons cell * and returning the data to the caller, but NOT updating the iterator. (So * that any calling loop can do this.) The iterator's current points to * nullptr. If the data is to be deleted, this is the callers responsibility. **********************************************************************/ inline void *CLIST_ITERATOR::extract() { void *extracted_data; #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::extract", ABORT, nullptr); if (!current) //list empty or //element extracted NULL_CURRENT.error ("CLIST_ITERATOR::extract", ABORT, nullptr); #endif if (list->singleton()) { // Special case where we do need to change the iterator. prev = next = list->last = nullptr; } else { prev->next = next; //remove from list if (current == list->last) { list->last = prev; ex_current_was_last = true; } else { ex_current_was_last = false; } } // Always set ex_current_was_cycle_pt so an add/forward will work in a loop. ex_current_was_cycle_pt = (current == cycle_pt); extracted_data = current->data; delete(current); //destroy CONS cell current = nullptr; return extracted_data; } /*********************************************************************** * CLIST_ITERATOR::move_to_first() * * Move current so that it is set to the start of the list. * Return data just in case anyone wants it. **********************************************************************/ inline void *CLIST_ITERATOR::move_to_first() { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::move_to_first", ABORT, nullptr); #endif current = list->First (); prev = list->last; next = current != nullptr ? current->next : nullptr; return current != nullptr ? current->data : nullptr; } /*********************************************************************** * CLIST_ITERATOR::mark_cycle_pt() * * Remember the current location so that we can tell whether we've returned * to this point later. * * If the current point is deleted either now, or in the future, the cycle * point will be set to the next item which is set to current. This could be * by a forward, add_after_then_move or add_after_then_move. **********************************************************************/ inline void CLIST_ITERATOR::mark_cycle_pt() { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::mark_cycle_pt", ABORT, nullptr); #endif if (current) cycle_pt = current; else ex_current_was_cycle_pt = true; started_cycling = false; } /*********************************************************************** * CLIST_ITERATOR::at_first() * * Are we at the start of the list? * **********************************************************************/ inline bool CLIST_ITERATOR::at_first() { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::at_first", ABORT, nullptr); #endif //we're at a deleted return ((list->empty ()) || (current == list->First ()) || ((current == nullptr) && (prev == list->last) && //NON-last pt between !ex_current_was_last)); //first and last } /*********************************************************************** * CLIST_ITERATOR::at_last() * * Are we at the end of the list? * **********************************************************************/ inline bool CLIST_ITERATOR::at_last() { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::at_last", ABORT, nullptr); #endif //we're at a deleted return ((list->empty ()) || (current == list->last) || ((current == nullptr) && (prev == list->last) && //last point between ex_current_was_last)); //first and last } /*********************************************************************** * CLIST_ITERATOR::cycled_list() * * Have we returned to the cycle_pt since it was set? * **********************************************************************/ inline bool CLIST_ITERATOR::cycled_list() { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::cycled_list", ABORT, nullptr); #endif return ((list->empty ()) || ((current == cycle_pt) && started_cycling)); } /*********************************************************************** * CLIST_ITERATOR::length() * * Return the length of the list * **********************************************************************/ inline int32_t CLIST_ITERATOR::length() { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::length", ABORT, nullptr); #endif return list->length (); } /*********************************************************************** * CLIST_ITERATOR::sort() * * Sort the elements of the list, then reposition at the start. * **********************************************************************/ inline void CLIST_ITERATOR::sort ( //sort elements int comparator ( //comparison routine const void *, const void *)) { #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::sort", ABORT, nullptr); #endif list->sort (comparator); move_to_first(); } /*********************************************************************** * CLIST_ITERATOR::add_to_end * * Add a new element to the end of the list without moving the iterator. * This is provided because a single linked list cannot move to the last as * the iterator couldn't set its prev pointer. Adding to the end is * essential for implementing queues. **********************************************************************/ inline void CLIST_ITERATOR::add_to_end( // element to add void *new_data) { CLIST_LINK *new_element; #ifndef NDEBUG if (!list) NO_LIST.error ("CLIST_ITERATOR::add_to_end", ABORT, nullptr); if (!new_data) BAD_PARAMETER.error ("CLIST_ITERATOR::add_to_end", ABORT, "new_data is nullptr"); #endif if (this->at_last ()) { this->add_after_stay_put (new_data); } else { if (this->at_first ()) { this->add_before_stay_put (new_data); list->last = prev; } else { //Iteratr is elsewhere new_element = new CLIST_LINK; new_element->data = new_data; new_element->next = list->last->next; list->last->next = new_element; list->last = new_element; } } } /*********************************************************************** QUOTE_IT MACRO DEFINITION =========================== Replace with "". may be an arbitrary number of tokens ***********************************************************************/ #define QUOTE_IT(parm) #parm /*********************************************************************** CLISTIZE(CLASSNAME) MACRO DEFINITION ====================================== CLASSNAME is assumed to be the name of a class to be used in a CONS list NOTE: Because we don't use virtual functions in the list code, the list code will NOT work correctly for classes derived from this. The macro generates: - An element deletion function: CLASSNAME##_c1_zapper - An element copier function: CLASSNAME##_c1_copier - A CLIST subclass: CLASSNAME##_CLIST - A CLIST_ITERATOR subclass: CLASSNAME##_C_IT NOTE: Generated names do NOT clash with those generated by ELISTIZE and ELIST2ISE. Two macros are provided: CLISTIZE and CLISTIZEH The ...IZEH macros just define the class names for use in .h files The ...IZE macros define the code use in .c files ***********************************************************************/ /*********************************************************************** CLISTIZEH(CLASSNAME) MACRO CLISTIZEH is a concatenation of 3 fragments CLISTIZEH_A, CLISTIZEH_B and CLISTIZEH_C. ***********************************************************************/ #define CLISTIZEH_A(CLASSNAME) \ \ extern DLLSYM void CLASSNAME##_c1_zapper( /*delete a link*/ \ void *link); /*link to delete*/ \ \ extern DLLSYM void \ *CLASSNAME##_c1_copier( /*deep copy a link*/ \ void *old_element); /*source link */ #define CLISTIZEH_B(CLASSNAME) \ \ /*********************************************************************** \ * CLASS - \ *CLASSNAME##_CLIST \ * \ * List class for class \ *CLASSNAME \ * \ **********************************************************************/ \ \ class DLLSYM CLASSNAME##_CLIST : public CLIST { \ public: \ CLASSNAME##_CLIST() : CLIST() {} \ /* constructor */ \ \ CLASSNAME##_CLIST( /* don't construct */ \ const CLASSNAME##_CLIST &) /*by initial assign*/ \ { \ DONT_CONSTRUCT_LIST_BY_COPY.error(QUOTE_IT(CLASSNAME##_CLIST), ABORT, \ nullptr); \ } \ \ void deep_clear() /* delete elements */ \ { \ CLIST::internal_deep_clear(&CLASSNAME##_c1_zapper); \ } \ \ void operator=(/* prevent assign */ \ const CLASSNAME##_CLIST &) { \ DONT_ASSIGN_LISTS.error(QUOTE_IT(CLASSNAME##_CLIST), ABORT, nullptr); \ } #define CLISTIZEH_C(CLASSNAME) \ } \ ; \ \ /*********************************************************************** \ * CLASS - CLASSNAME##_C_IT \ * \ * Iterator class for class CLASSNAME##_CLIST \ * \ * Note: We don't need to coerce pointers to member functions input \ * parameters as these are automatically converted to the type of the base \ * type. ("A ptr to a class may be converted to a pointer to a public base \ * class of that class") \ **********************************************************************/ \ \ class DLLSYM CLASSNAME##_C_IT : public CLIST_ITERATOR { \ public: \ CLASSNAME##_C_IT() : CLIST_ITERATOR() {} \ \ CLASSNAME##_C_IT(CLASSNAME##_CLIST *list) : CLIST_ITERATOR(list) {} \ \ CLASSNAME *data() { return (CLASSNAME *)CLIST_ITERATOR::data(); } \ \ CLASSNAME *data_relative(int8_t offset) { \ return (CLASSNAME *)CLIST_ITERATOR::data_relative(offset); \ } \ \ CLASSNAME *forward() { return (CLASSNAME *)CLIST_ITERATOR::forward(); } \ \ CLASSNAME *extract() { return (CLASSNAME *)CLIST_ITERATOR::extract(); } \ \ CLASSNAME *move_to_first() { \ return (CLASSNAME *)CLIST_ITERATOR::move_to_first(); \ } \ \ CLASSNAME *move_to_last() { \ return (CLASSNAME *)CLIST_ITERATOR::move_to_last(); \ } \ }; #define CLISTIZEH(CLASSNAME) \ \ CLISTIZEH_A(CLASSNAME) \ \ CLISTIZEH_B(CLASSNAME) \ \ CLISTIZEH_C(CLASSNAME) /*********************************************************************** CLISTIZE(CLASSNAME) MACRO ***********************************************************************/ #define CLISTIZE(CLASSNAME) \ \ /*********************************************************************** \ * CLASSNAME##_c1_zapper \ * \ * A function which can delete a CLASSNAME element. This is passed to the \ * generic deep_clear list member function so that when a list is cleared \ *the \ * elements on the list are properly destroyed from the base class, even \ * though we don't use a virtual destructor function. \ **********************************************************************/ \ \ DLLSYM void CLASSNAME##_c1_zapper( /*delete a link*/ \ void *link) /*link to delete*/ \ { \ delete (CLASSNAME *)link; \ } #endif