--- parser3/src/include/pa_array.h	2001/01/29 15:56:03	1.7
+++ parser3/src/include/pa_array.h	2024/10/26 15:46:52	1.98
@@ -1,97 +1,357 @@
-/*
-  $Id: pa_array.h,v 1.7 2001/01/29 15:56:03 paf Exp $
-*/
-
-/*
-
-	Array               Chunk0
-	======              ========
-	head--------------->[ptr]
-	append_here-------->[ptr]
-	link_row            ........
-			.			.
-			.			[ptr]
-			...........>[link to the next chunk]
+/** @file
+	Parser: Array & Array_iterator classes decls.
 
+	Copyright (c) 2001-2023 Art. Lebedev Studio (http://www.artlebedev.com)
+	Authors: Konstantin Morshnev <moko@design.ru>, Alexandr Petrosian <paf@design.ru>
 */
 
 #ifndef PA_ARRAY_H
 #define PA_ARRAY_H
 
-#include <stddef.h>
+#define IDENT_PA_ARRAY_H "$Id: pa_array.h,v 1.98 2024/10/26 15:46:52 moko Exp $"
+
+// includes
 
+#include "pa_memory.h"
 #include "pa_types.h"
+#include "pa_exception.h"
+
+// forwards
+
+template<typename T> class Array_iterator;
+template<typename T> class Array_reverse_iterator;
+
+// defines
+
+#define ARRAY_OPTION_LIMIT_ALL ((size_t)-1)
+
+/// Simple Array
+template<typename T> class Array: public PA_Object {
+
+	friend class Array_iterator<T>;
+	friend class Array_reverse_iterator<T>;
+
+protected:
+
+	/// elements[growing size] here
+	T *felements;
 
-class Pool;
+	// allocated size
+	size_t fallocated;
+
+	// array size
+	size_t fsize;
 
-class Array {
 public:
+	typedef Array_iterator<T> Iterator;
+	typedef Array_reverse_iterator<T> ReverseIterator;
 
-	typedef void *Item;
+	struct Action_options {
+		size_t offset;
+		size_t limit; //< ARRAY_OPTION_LIMIT_ALL means 'all'. zero limit means 'nothing'
+		bool reverse;
+		bool defined;
+		
+		Action_options(
+			size_t aoffset=0,
+			size_t alimit=ARRAY_OPTION_LIMIT_ALL,
+			bool areverse=false):
+			offset(aoffset), limit(alimit), reverse(areverse), 
+			defined(false) {}
+
+		bool adjust(size_t count) {
+			if(!count || !limit)
+				return false;
+			if(offset>=count)
+				return false;
+			// max(limit)
+			size_t m=reverse?
+				offset+1
+				:count-offset;
+			if(!m)
+				return false;
+			// fix limit
+			if(limit>m)
+				limit=m;
 
-	enum {
-		CR_INITIAL_ROWS_DEFAULT=10,
-		CR_GROW_PERCENT=60
+			return true;
+		}
 	};
 
-public:
+	typedef T element_type;
 
-	void *operator new(size_t size, Pool *apool);
-	Array(Pool *apool, int initial_rows=CR_INITIAL_ROWS_DEFAULT);
+	inline Array(size_t initial=0):
+		fallocated(initial),
+		fsize(0)
+	{
+		felements=fallocated?(T *)pa_malloc(fallocated*sizeof(T)):0;
+	}
 
-	int size() { return fused_rows; }
-	Array& operator += (Item src);
-	Array& operator += (Array& src);
-	Item& operator [] (int index);
+#ifdef USE_DESTRUCTORS
+	inline ~Array(){
+		if(felements)
+			pa_free(felements);
+	}
+#endif
 
-protected:
+	/// how many items are in Array
+	inline size_t count() const { return fsize; }
 
-	// the pool I'm allocated on
-	Pool *pool;
+	/// append to array
+	inline Array& operator+=(T src) {
+		if(is_full())
+			expand();
 
-private:
+		felements[fsize++]=src;
 
-	struct Chunk {
-		// the number of rows in chunk
-		int count;
-		union Row {
-			Item item;
-			Chunk *link;  // link to the next chunk in chain
-		} rows[1];
-		// next rows are here
-	}
-		*head;  // the head chunk of the chunk chain
-
-	// last allocated chunk
-	// helps appending Arrays
-	Chunk *tail;
-
-	// next append would write to this record
-	Chunk::Row *append_here;
-	
-	// the address of place where lies address 
-	// of the link to the next chunk to allocate
-	Chunk::Row *link_row;
+		return *this;
+	}
 
-private:
+	/// append other Array portion to this one. starting from offset
+	void append(const Array& src, size_t offset=0, size_t limit=ARRAY_OPTION_LIMIT_ALL) { //< zero limit means 'nothing'
+		size_t src_count=src.count();
+		// skip tivials
+		if(!src_count || !limit || offset>=src_count)
+			return;
+		// max(limit)
+		size_t m=src_count-offset;
+		// fix limit
+		if(limit>m)
+			limit=m;
+
+		fit(fsize-1+limit);
+		memcpy(felements+fsize, src.felements+offset, limit * sizeof(T));
+		fsize+=limit;
+	}
 
-	// array size
-	int fused_rows;
+	/// get index-element
+	inline T get(size_t index) const {
+		assert(index<count());
+		return felements[index];
+	}
 
-	int cache_chunk_base;
-	Chunk *cache_chunk;
-	
-private:
+	/// ref version of get
+	inline T& get_ref(size_t index) const {
+		assert(index<count());
+		return felements[index];
+	}
 
-	bool chunk_is_full() {
-		return append_here == link_row;
+	/// put index-element
+	inline void put(size_t index, T element) {
+		assert(index<count());
+		felements[index]=element;
+	}
+
+	/// insert index-element
+	inline void insert(size_t index, T element) {
+		assert(index<=count());
+
+		if(is_full())
+			expand();
+
+		memmove(felements+index+1, felements+index, (fsize-index) * sizeof(T));
+
+		felements[index]=element;
+		fsize++;
+	}
+
+	/// remove index-element
+	inline void remove(size_t index) {
+		assert(index<count());
+		if (index<--fsize)
+			memmove(felements+index, felements+index+1, (fsize-index) * sizeof(T));
+	}
+
+	inline T operator [](size_t index) const { return get(index); }
+
+	inline void clear() {
+		if(fsize)
+			memset(felements, 0, fsize * sizeof(T));
+		fsize=0;
+	}
+
+	/// iterate over all elements
+	template<typename I> void for_each(void (*callback)(T, I), I info) const {
+		T *last=felements+fsize;
+		for(T *current=felements; current<last; current++)
+			callback(*current, info);
+	}
+
+	/// iterate over all elements
+	template<typename I> void for_each(bool (*callback)(T, I), I info) const {
+		T *last=felements+fsize;
+		for(T *current=felements; current<last; current++)
+			if(callback(*current, info))
+				return;
+	}
+
+	/// iterate over all elements
+	template<typename I> void for_each_ref(void (*callback)(T&, I), I info) {
+		T *last=felements+fsize;
+		for(T *current=felements; current<last; current++)
+			callback(*current, info);
+	}
+
+	/// iterate over all elements until condition becomes true, return that element
+	template<typename I> T first_that(bool (*callback)(T, I), I info) const {
+		T *last=felements+fsize;
+		for(T *current=felements; current<last; current++)
+			if(callback(*current, info))
+				return *current;
+
+		return T(0);
+	}
+
+	inline T* ptr(size_t index){
+		return felements + index;
+	}
+
+protected:
+
+	inline bool is_full() {
+		return fsize == fallocated;
+	}
+
+	inline void expand() {
+		resize(fallocated>0 ? fallocated+fallocated/2+2 : 3); // 3 is PAF default, confirmed by tests
+	}
+
+	inline void fit(size_t index){
+		if(index >= fallocated)
+			resize(max(this->fallocated + this->fallocated/4, index+1));
+	}
+
+	void resize(size_t asize) {
+		if(fallocated){
+			felements=(T *)pa_realloc(felements, asize*sizeof(T));
+			fallocated=asize;
+		} else {
+			fallocated=asize;
+			felements=(T *)pa_malloc(asize*sizeof(T));
+		}
 	}
-	void expand(int chunk_rows);
 
 private: //disabled
 
-	Array(Array&) {}
-	Array& operator = (Array&) { return *this; }
+	Array(const Array&) {}
+	Array& operator = (const Array&) { return *this; }
+};
+
+
+/// Commonly used, templated to work with any integer type
+
+template<typename T> char* pa_itoa(T n, T base=10){
+	char buf[MAX_NUMBER + 1];
+	char* pos=buf + MAX_NUMBER;
+	*pos='\0';
+
+	bool negative=n < 0;
+	if (n < 0){
+		n=-n;
+	}
+
+	do {
+		*(--pos)=(char)(n % base) + '0';
+		n/=base;
+	} while (n > 0);
+
+	if (negative) {
+		*(--pos) = '-';
+	}
+	return pa_strdup(pos, buf + MAX_NUMBER - pos);
+}
+
+template<typename T> char* pa_uitoa(T n, T base=10){
+	char buf[MAX_NUMBER + 1];
+	char* pos=buf + MAX_NUMBER;
+	*pos='\0';
+
+	do {
+		*(--pos)=(char)(n % base) + '0';
+		n/=base;
+	} while (n > 0);
+
+	return pa_strdup(pos, buf + MAX_NUMBER - pos);
+}
+
+
+/** Array iterator, usage:
+	@code
+	// Array<T> a;
+	for(Array_iterator<T> i(a); i; ) {
+		T& element=i.next();
+		...
+	}	
+	@endcode
+*/
+template<typename T> class Array_iterator {
+
+	const Array<T>& farray;
+	T *fcurrent;
+	T *flast;
+
+public:
+
+	Array_iterator(const Array<T>& aarray): farray(aarray) {
+		fcurrent=farray.felements;
+		flast=farray.felements + farray.fsize;
+	}
+
+	/// there are still elements
+	inline operator bool () {
+		return fcurrent < flast;
+	}
+
+	/// returns the current element and advances the iterator
+	inline T next() {
+		return *(fcurrent++);
+	}
+
+	/// returns the current element
+	inline T value() {
+		return *(fcurrent);
+	}
+
+	// returns the current index of the iterator
+	inline size_t index() {
+		return fcurrent - farray.felements;
+	}
+
+	inline char *key(){
+		return pa_uitoa(index());
+	}
+
 };
 
+template<typename T> class Array_reverse_iterator {
+
+	const Array<T>& farray;
+	T *fcurrent;
+
+public:
+
+	Array_reverse_iterator(const Array<T>& aarray): farray(aarray) {
+		fcurrent=farray.felements + farray.fsize;
+	}
+
+	/// there are still elements
+	inline operator bool () {
+		return fcurrent > farray.felements;
+	}
+
+	/// returns the current element and advances the iterator
+	inline T prev() {
+		return *(--fcurrent);
+	}
+
+	// returns the current index of the iterator
+	inline size_t index() {
+		return fcurrent - farray.felements;
+	}
+
+	inline char *key(){
+		return pa_uitoa(index());
+	}
+
+};
 #endif