/********************************************************************** * File: elst.cpp (Formerly elist.c) * Description: Embedded list handling code which is not in the include file. * Author: Phil Cheatle * Created: Fri Jan 04 13:55:49 GMT 1991 * * (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. * **********************************************************************/ #include #include "elst.h" /*********************************************************************** * MEMBER FUNCTIONS OF CLASS: ELIST * ================================ **********************************************************************/ /*********************************************************************** * ELIST::internal_clear * * Used by the destructor and the "clear" member function of derived list * classes to destroy all the elements on the list. * The calling function passes a "zapper" function which can be called to * delete each element of the list, regardless of its derived type. This * technique permits a generic clear function to destroy elements of * different derived types correctly, without requiring virtual functions and * the consequential memory overhead. **********************************************************************/ void ELIST::internal_clear ( //destroy all links void (*zapper) (ELIST_LINK *)) { //ptr to zapper functn ELIST_LINK *ptr; ELIST_LINK *next; if (!empty ()) { ptr = last->next; //set to first last->next = NULL; //break circle last = NULL; //set list empty while (ptr) { next = ptr->next; zapper(ptr); ptr = next; } } } /*********************************************************************** * ELIST::assign_to_sublist * * The list is set to a sublist of another list. "This" list must be empty * before this function is invoked. The two iterators passed must refer to * the same list, different from "this" one. The sublist removed is the * inclusive list from start_it's current position to end_it's current * position. If this range passes over the end of the source list then the * source list has its end set to the previous element of start_it. The * extracted sublist is unaffected by the end point of the source list, its * end point is always the end_it position. **********************************************************************/ void ELIST::assign_to_sublist( //to this list ELIST_ITERATOR *start_it, //from list start ELIST_ITERATOR *end_it) { //from list end const ERRCODE LIST_NOT_EMPTY = "Destination list must be empty before extracting a sublist"; if (!empty ()) LIST_NOT_EMPTY.error ("ELIST.assign_to_sublist", ABORT, NULL); last = start_it->extract_sublist (end_it); } /*********************************************************************** * ELIST::length * * Return count of elements on list **********************************************************************/ inT32 ELIST::length() const { // count elements ELIST_ITERATOR it(const_cast(this)); inT32 count = 0; for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) count++; return count; } /*********************************************************************** * ELIST::sort * * Sort elements on list * NB If you don't like the const declarations in the comparator, coerce yours: * ( int (*)(const void *, const void *) **********************************************************************/ void ELIST::sort ( //sort elements int comparator ( //comparison routine const void *, const void *)) { ELIST_ITERATOR it(this); inT32 count; ELIST_LINK **base; //ptr array to sort ELIST_LINK **current; inT32 i; /* Allocate an array of pointers, one per list element */ count = length (); base = (ELIST_LINK **) malloc (count * sizeof (ELIST_LINK *)); /* Extract all elements, putting the pointers in the array */ current = base; for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { *current = it.extract (); current++; } /* Sort the pointer array */ qsort ((char *) base, count, sizeof (*base), comparator); /* Rebuild the list from the sorted pointers */ current = base; for (i = 0; i < count; i++) { it.add_to_end (*current); current++; } free(base); } // Assuming list has been sorted already, insert new_link 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 is set to true and comparator() returns 0 (an entry with the // same information as the one contained in new_link is already in the // list) - new_link is not added to the list and the function returns the // pointer to the identical entry that already exists in the list // (otherwise the function returns new_link). ELIST_LINK *ELIST::add_sorted_and_find( int comparator(const void*, const void*), bool unique, ELIST_LINK* new_link) { // Check for adding at the end. if (last == NULL || comparator(&last, &new_link) < 0) { if (last == NULL) { new_link->next = new_link; } else { new_link->next = last->next; last->next = new_link; } last = new_link; } else { // Need to use an iterator. ELIST_ITERATOR it(this); for (it.mark_cycle_pt(); !it.cycled_list(); it.forward()) { ELIST_LINK* link = it.data(); int compare = comparator(&link, &new_link); if (compare > 0) { break; } else if (unique && compare == 0) { return link; } } if (it.cycled_list()) it.add_to_end(new_link); else it.add_before_then_move(new_link); } return new_link; } /*********************************************************************** * MEMBER FUNCTIONS OF CLASS: ELIST_ITERATOR * ========================================= **********************************************************************/ /*********************************************************************** * ELIST_ITERATOR::forward * * Move the iterator to the next element of the list. * REMEMBER: ALL LISTS ARE CIRCULAR. **********************************************************************/ ELIST_LINK *ELIST_ITERATOR::forward() { #ifndef NDEBUG if (!list) NO_LIST.error ("ELIST_ITERATOR::forward", ABORT, NULL); #endif if (list->empty ()) return NULL; if (current) { //not removed so //set previous prev = current; started_cycling = TRUE; // In case next is deleted by another iterator, get next from current. current = current->next; } else { if (ex_current_was_cycle_pt) cycle_pt = next; current = next; } next = current->next; #ifndef NDEBUG if (!current) NULL_DATA.error ("ELIST_ITERATOR::forward", ABORT, NULL); if (!next) NULL_NEXT.error ("ELIST_ITERATOR::forward", ABORT, "This is: %p Current is: %p", this, current); #endif return current; } /*********************************************************************** * ELIST_ITERATOR::data_relative * * Return the data pointer to the element "offset" elements from current. * "offset" must not be less than -1. * (This function can't be INLINEd because it contains a loop) **********************************************************************/ ELIST_LINK *ELIST_ITERATOR::data_relative( //get data + or - ... inT8 offset) { //offset from current ELIST_LINK *ptr; #ifndef NDEBUG if (!list) NO_LIST.error ("ELIST_ITERATOR::data_relative", ABORT, NULL); if (list->empty ()) EMPTY_LIST.error ("ELIST_ITERATOR::data_relative", ABORT, NULL); if (offset < -1) BAD_PARAMETER.error ("ELIST_ITERATOR::data_relative", ABORT, "offset < -l"); #endif if (offset == -1) ptr = prev; else for (ptr = current ? current : prev; offset-- > 0; ptr = ptr->next); #ifndef NDEBUG if (!ptr) NULL_DATA.error ("ELIST_ITERATOR::data_relative", ABORT, NULL); #endif return ptr; } /*********************************************************************** * ELIST_ITERATOR::move_to_last() * * Move current so that it is set to the end of the list. * Return data just in case anyone wants it. * (This function can't be INLINEd because it contains a loop) **********************************************************************/ ELIST_LINK *ELIST_ITERATOR::move_to_last() { #ifndef NDEBUG if (!list) NO_LIST.error ("ELIST_ITERATOR::move_to_last", ABORT, NULL); #endif while (current != list->last) forward(); return current; } /*********************************************************************** * ELIST_ITERATOR::exchange() * * Given another iterator, whose current element is a different element on * the same list list OR an element of another list, exchange the two current * elements. On return, each iterator points to the element which was the * other iterators current on entry. * (This function hasn't been in-lined because its a bit big!) **********************************************************************/ void ELIST_ITERATOR::exchange( //positions of 2 links ELIST_ITERATOR *other_it) { //other iterator const ERRCODE DONT_EXCHANGE_DELETED = "Can't exchange deleted elements of lists"; ELIST_LINK *old_current; #ifndef NDEBUG if (!list) NO_LIST.error ("ELIST_ITERATOR::exchange", ABORT, NULL); if (!other_it) BAD_PARAMETER.error ("ELIST_ITERATOR::exchange", ABORT, "other_it NULL"); if (!(other_it->list)) NO_LIST.error ("ELIST_ITERATOR::exchange", ABORT, "other_it"); #endif /* Do nothing if either list is empty or if both iterators reference the same link */ if ((list->empty ()) || (other_it->list->empty ()) || (current == other_it->current)) return; /* Error if either current element is deleted */ if (!current || !other_it->current) DONT_EXCHANGE_DELETED.error ("ELIST_ITERATOR.exchange", ABORT, NULL); /* Now handle the 4 cases: doubleton list; non-doubleton adjacent elements (other before this); non-doubleton adjacent elements (this before other); non-adjacent elements. */ //adjacent links if ((next == other_it->current) || (other_it->next == current)) { //doubleton list if ((next == other_it->current) && (other_it->next == current)) { prev = next = current; other_it->prev = other_it->next = other_it->current; } else { //non-doubleton with //adjacent links //other before this if (other_it->next == current) { other_it->prev->next = current; other_it->current->next = next; current->next = other_it->current; other_it->next = other_it->current; prev = current; } else { //this before other prev->next = other_it->current; current->next = other_it->next; other_it->current->next = current; next = current; other_it->prev = other_it->current; } } } else { //no overlap prev->next = other_it->current; current->next = other_it->next; other_it->prev->next = current; other_it->current->next = next; } /* update end of list pointer when necessary (remember that the 2 iterators may iterate over different lists!) */ if (list->last == current) list->last = other_it->current; if (other_it->list->last == other_it->current) other_it->list->last = current; if (current == cycle_pt) cycle_pt = other_it->cycle_pt; if (other_it->current == other_it->cycle_pt) other_it->cycle_pt = cycle_pt; /* The actual exchange - in all cases*/ old_current = current; current = other_it->current; other_it->current = old_current; } /*********************************************************************** * ELIST_ITERATOR::extract_sublist() * * This is a private member, used only by ELIST::assign_to_sublist. * Given another iterator for the same list, extract the links from THIS to * OTHER inclusive, link them into a new circular list, and return a * pointer to the last element. * (Can't inline this function because it contains a loop) **********************************************************************/ ELIST_LINK *ELIST_ITERATOR::extract_sublist( //from this current ELIST_ITERATOR *other_it) { //to other current #ifndef NDEBUG const ERRCODE BAD_EXTRACTION_PTS = "Can't extract sublist from points on different lists"; const ERRCODE DONT_EXTRACT_DELETED = "Can't extract a sublist marked by deleted points"; #endif const ERRCODE BAD_SUBLIST = "Can't find sublist end point in original list"; ELIST_ITERATOR temp_it = *this; ELIST_LINK *end_of_new_list; #ifndef NDEBUG if (!other_it) BAD_PARAMETER.error ("ELIST_ITERATOR::extract_sublist", ABORT, "other_it NULL"); if (!list) NO_LIST.error ("ELIST_ITERATOR::extract_sublist", ABORT, NULL); if (list != other_it->list) BAD_EXTRACTION_PTS.error ("ELIST_ITERATOR.extract_sublist", ABORT, NULL); if (list->empty ()) EMPTY_LIST.error ("ELIST_ITERATOR::extract_sublist", ABORT, NULL); if (!current || !other_it->current) DONT_EXTRACT_DELETED.error ("ELIST_ITERATOR.extract_sublist", ABORT, NULL); #endif ex_current_was_last = other_it->ex_current_was_last = FALSE; ex_current_was_cycle_pt = FALSE; other_it->ex_current_was_cycle_pt = FALSE; temp_it.mark_cycle_pt (); do { //walk sublist if (temp_it.cycled_list()) // can't find end pt BAD_SUBLIST.error ("ELIST_ITERATOR.extract_sublist", ABORT, NULL); if (temp_it.at_last ()) { list->last = prev; ex_current_was_last = other_it->ex_current_was_last = TRUE; } if (temp_it.current == cycle_pt) ex_current_was_cycle_pt = TRUE; if (temp_it.current == other_it->cycle_pt) other_it->ex_current_was_cycle_pt = TRUE; temp_it.forward (); } while (temp_it.prev != other_it->current); //circularise sublist other_it->current->next = current; end_of_new_list = other_it->current; //sublist = whole list if (prev == other_it->current) { list->last = NULL; prev = current = next = NULL; other_it->prev = other_it->current = other_it->next = NULL; } else { prev->next = other_it->next; current = other_it->current = NULL; next = other_it->next; other_it->prev = prev; } return end_of_new_list; }