// This may look like C code, but it is really -*- C++ -*- /* Copyright (C) 1988 Free Software Foundation written by Doug Lea (dl@rocky.oswego.edu) based on code by Marc Shapiro (shapiro@sor.inria.fr) This file is part of the GNU C++ Library. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with this library; if not, write to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #ifndef _unsignedPlex_h #ifdef __GNUG__ #pragma interface #endif #define _unsignedPlex_h 1 #include "std.h" #include "Pix.h" #include "unsigned.defs.h" // Plexes are made out of unsignedIChunks #include class unsignedIChunk { //public: // kludge until C++ `protected' policies settled protected: unsigned* data; // data, from client int base; // lowest possible index int low; // lowest valid index int fence; // highest valid index + 1 int top; // highest possible index + 1 unsignedIChunk* nxt; // circular links unsignedIChunk* prv; public: // constructors unsignedIChunk(unsigned* d, // ptr to array of elements int base_idx, // initial indices int low_idx, int fence_idx, int top_idx); virtual ~unsignedIChunk(); // status reports int size() const; // number of slots inline virtual int empty() const ; inline virtual int full() const ; int can_grow_high () const ; // there is space to add data int can_grow_low () const; int base_index() const; // lowest possible index; int low_index() const; // lowest actual index; inline virtual int first_index() const; // lowest valid index or fence if none inline virtual int last_index() const; // highest valid index or low-1 if none int fence_index() const; // highest actual index + 1 int top_index() const; // highest possible index + 1 // indexing conversion int possible_index(int i) const; // i between base and top int actual_index(int i) const; // i between low and fence inline virtual int valid_index(int i) const; // i not deleted (mainly for mchunks) int possible_pointer(const unsigned* p) const; // same for ptr int actual_pointer(const unsigned* p) const; inline virtual int valid_pointer(const unsigned* p) const; unsigned* pointer_to(int i) const ; // pointer to data indexed by i // caution: i is not checked for validity int index_of(const unsigned* p) const; // index of data pointed to by p // caution: p is not checked for validity inline virtual int succ(int idx) const; // next valid index or fence if none inline virtual int pred(int idx) const; // previous index or low - 1 if none inline virtual unsigned* first_pointer() const; // pointer to first valid pos or 0 inline virtual unsigned* last_pointer() const; // pointer to first valid pos or 0 inline virtual unsigned* succ(unsigned* p) const; // next pointer or 0 inline virtual unsigned* pred(unsigned* p) const; // previous pointer or 0 // modification inline virtual unsigned* grow_high (); // return spot to add an element inline virtual unsigned* grow_low (); inline virtual void shrink_high (); // logically delete top index inline virtual void shrink_low (); virtual void clear(int lo); // reset to empty ch with base = lo virtual void cleardown(int hi); // reset to empty ch with top = hi void re_index(int lo); // re-index so lo is new low // chunk traversal unsignedIChunk* next() const; unsignedIChunk* prev() const; void link_to_prev(unsignedIChunk* prev); void link_to_next(unsignedIChunk* next); void unlink(); // state checks unsigned* invalidate(); // mark self as invalid; return data // for possible deletion virtual int OK() const; // representation invariant void error(const char*) const; void empty_error() const; void full_error() const; void index_error() const; }; // unsignedPlex is a partly `abstract' class: few of the virtuals // are implemented at the Plex level, only in the subclasses class unsignedPlex { protected: unsignedIChunk* hd; // a chunk holding the data int lo; // lowest index int fnc; // highest index + 1 int csize; // size of the chunk void invalidate(); // mark so OK() is false void del_chunk(unsignedIChunk*); // delete a chunk unsignedIChunk* tl() const; // last chunk; int one_chunk() const; // true if hd == tl() public: // constructors, etc. unsignedPlex(); // no-op virtual ~unsignedPlex(); // Access functions virtual unsigned& operator [] (int idx) = 0; // access by index; virtual unsigned& operator () (Pix p) = 0; // access by Pix; virtual unsigned& high_element () = 0; // access high element virtual unsigned& low_element () = 0; // access low element // read-only versions for const Plexes virtual const unsigned& operator [] (int idx) const = 0; // access by index; virtual const unsigned& operator () (Pix p) const = 0; // access by Pix; virtual const unsigned& high_element () const = 0; // access high element virtual const unsigned& low_element () const = 0; // access low element // Index functions virtual int valid (int idx) const = 0; // idx is an OK index virtual int low() const = 0; // lowest index or fence if none virtual int high() const = 0; // highest index or low-1 if none int ecnef() const; // low limit index (low-1) int fence() const; // high limit index (high+1) virtual void prev(int& idx) const= 0; // set idx to preceding index // caution: pred may be out of bounds virtual void next(int& idx) const = 0; // set to next index // caution: succ may be out of bounds virtual Pix first() const = 0; // Pix to low element or 0 virtual Pix last() const = 0; // Pix to high element or 0 virtual void prev(Pix& pix) const = 0; // preceding pix or 0 virtual void next(Pix& pix) const = 0; // next pix or 0 virtual int owns(Pix p) const = 0; // p is an OK Pix // index<->Pix virtual int Pix_to_index(Pix p) const = 0; // get index via Pix virtual Pix index_to_Pix(int idx) const = 0; // Pix via index // Growth virtual int add_high(const unsigned elem) =0;// add new element at high end // return new high virtual int add_low(const unsigned elem) = 0; // add new low element, // return new low // Shrinkage virtual int del_high() = 0; // remove the element at high end // return new high virtual int del_low() = 0; // delete low element, return new lo // caution: del_low/high // does not necessarily // immediately call unsigned::~unsigned // operations on multiple elements virtual void fill(const unsigned x); // set all elements = x virtual void fill(const unsigned x, int from, int to); // fill from to to virtual void clear() = 0; // reset to zero-sized Plex virtual int reset_low(int newlow); // change low index,return old virtual void reverse(); // reverse in-place virtual void append(const unsignedPlex& a); // concatenate a copy virtual void prepend(const unsignedPlex& a); // prepend a copy // status virtual int can_add_high() const = 0; virtual int can_add_low() const = 0; int length () const; // number of slots int empty () const; // is the plex empty? virtual int full() const = 0; // it it full? int chunk_size() const; // report chunk size; virtual int OK() const = 0; // representation invariant void error(const char* msg) const; void index_error() const; void empty_error() const; void full_error() const; }; // unsignedIChunk ops inline int unsignedIChunk:: size() const { return top - base; } inline int unsignedIChunk:: base_index() const { return base; } inline int unsignedIChunk:: low_index() const { return low; } inline int unsignedIChunk:: fence_index() const { return fence; } inline int unsignedIChunk:: top_index() const { return top; } inline unsigned* unsignedIChunk:: pointer_to(int i) const { return &(data[i-base]); } inline int unsignedIChunk:: index_of(const unsigned* p) const { return (p - data) + base; } inline int unsignedIChunk:: possible_index(int i) const { return i >= base && i < top; } inline int unsignedIChunk:: possible_pointer(const unsigned* p) const { return p >= data && p < &(data[top-base]); } inline int unsignedIChunk:: actual_index(int i) const { return i >= low && i < fence; } inline int unsignedIChunk:: actual_pointer(const unsigned* p) const { return p >= data && p < &(data[fence-base]); } inline int unsignedIChunk:: can_grow_high () const { return fence < top; } inline int unsignedIChunk:: can_grow_low () const { return base < low; } inline unsigned* unsignedIChunk:: invalidate() { unsigned* p = data; data = 0; return p; } inline unsignedIChunk* unsignedIChunk::prev() const { return prv; } inline unsignedIChunk* unsignedIChunk::next() const { return nxt; } inline void unsignedIChunk::link_to_prev(unsignedIChunk* prev) { nxt = prev->nxt; prv = prev; nxt->prv = this; prv->nxt = this; } inline void unsignedIChunk::link_to_next(unsignedIChunk* next) { prv = next->prv; nxt = next; nxt->prv = this; prv->nxt = this; } inline void unsignedIChunk::unlink() { unsignedIChunk* n = nxt; unsignedIChunk* p = prv; n->prv = p; p->nxt = n; prv = nxt = this; } inline int unsignedIChunk:: empty() const { return low == fence; } inline int unsignedIChunk:: full() const { return top - base == fence - low; } inline int unsignedIChunk:: first_index() const { return (low == fence)? fence : low; } inline int unsignedIChunk:: last_index() const { return (low == fence)? low - 1 : fence - 1; } inline int unsignedIChunk:: succ(int i) const { return (i < low) ? low : i + 1; } inline int unsignedIChunk:: pred(int i) const { return (i > fence) ? (fence - 1) : i - 1; } inline int unsignedIChunk:: valid_index(int i) const { return i >= low && i < fence; } inline int unsignedIChunk:: valid_pointer(const unsigned* p) const { return p >= &(data[low - base]) && p < &(data[fence - base]); } inline unsigned* unsignedIChunk:: grow_high () { if (!can_grow_high()) full_error(); return &(data[fence++ - base]); } inline unsigned* unsignedIChunk:: grow_low () { if (!can_grow_low()) full_error(); return &(data[--low - base]); } inline void unsignedIChunk:: shrink_high () { if (empty()) empty_error(); --fence; } inline void unsignedIChunk:: shrink_low () { if (empty()) empty_error(); ++low; } inline unsigned* unsignedIChunk::first_pointer() const { return (low == fence)? 0 : &(data[low - base]); } inline unsigned* unsignedIChunk::last_pointer() const { return (low == fence)? 0 : &(data[fence - base - 1]); } inline unsigned* unsignedIChunk::succ(unsigned* p) const { return ((p+1) < &(data[low - base]) || (p+1) >= &(data[fence - base])) ? 0 : (p+1); } inline unsigned* unsignedIChunk::pred(unsigned* p) const { return ((p-1) < &(data[low - base]) || (p-1) >= &(data[fence - base])) ? 0 : (p-1); } // generic Plex operations inline unsignedPlex::unsignedPlex() {} inline int unsignedPlex::chunk_size() const { return csize; } inline int unsignedPlex::ecnef () const { return lo - 1; } inline int unsignedPlex::fence () const { return fnc; } inline int unsignedPlex::length () const { return fnc - lo; } inline int unsignedPlex::empty () const { return fnc == lo; } inline unsignedIChunk* unsignedPlex::tl() const { return hd->prev(); } inline int unsignedPlex::one_chunk() const { return hd == hd->prev(); } #endif