src/share/vm/adlc/dict2.cpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 1998, 2013, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code 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 General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 // Dictionaries - An Abstract Data Type

 #include "adlc.hpp"

 // #include "dict.hpp"


 //------------------------------data-----------------------------------------
 // String hash tables
 #define MAXID 20
 static char initflag = 0;       // True after 1st initialization
 static char shft[MAXID + 1] = {1,2,3,4,5,6,7,1,2,3,4,5,6,7,1,2,3,4,5,6,7};
 static short xsum[MAXID];

 //------------------------------bucket---------------------------------------
 class bucket {
 public:
   int          _cnt, _max;      // Size of bucket
   const void **_keyvals;        // Array of keys and values
 };

 //------------------------------Dict-----------------------------------------
 // The dictionary is kept has a hash table.  The hash table is a even power
 // of two, for nice modulo operations.  Each bucket in the hash table points
 // to a linear list of key-value pairs; each key & value is just a (void *).
 // The list starts with a count.  A hash lookup finds the list head, then a
 // simple linear scan finds the key.  If the table gets too full, it's
 // doubled in size; the total amount of EXTRA times all hash functions are
 // computed for the doubling is no more than the current size - thus the
 // doubling in size costs no more than a constant factor in speed.
 Dict::Dict(CmpKey initcmp, Hash inithash) : _hash(inithash), _cmp(initcmp), _arena(NULL) {
   init();
 }

 Dict::Dict(CmpKey initcmp, Hash inithash, Arena *arena) : _hash(inithash), _cmp(initcmp), _arena(arena) {
   init();
 }

 void Dict::init() {
   int i;

   // Precompute table of null character hashes
   if (!initflag) {              // Not initializated yet?
     xsum[0] = (short) ((1 << shft[0]) + 1);  // Initialize
     for( i = 1; i < MAXID; i++) {
       xsum[i] = (short) ((1 << shft[i]) + 1 + xsum[i-1]);
     }
     initflag = 1;               // Never again
   }

   _size = 16;                   // Size is a power of 2
   _cnt = 0;                     // Dictionary is empty
   _bin = (bucket*)_arena->Amalloc_4(sizeof(bucket) * _size);
   memset(_bin, 0, sizeof(bucket) * _size);
 }

 //------------------------------~Dict------------------------------------------
 // Delete an existing dictionary.
 Dict::~Dict() {
 }

 //------------------------------Clear----------------------------------------
 // Zap to empty; ready for re-use
 void Dict::Clear() {
   _cnt = 0;                     // Empty contents
   for( int i=0; i<_size; i++ )
     _bin[i]._cnt = 0;           // Empty buckets, but leave allocated
   // Leave _size & _bin alone, under the assumption that dictionary will
   // grow to this size again.
 }

 //------------------------------doubhash---------------------------------------
 // Double hash table size.  If can't do so, just suffer.  If can, then run
 // thru old hash table, moving things to new table.  Note that since hash
 // table doubled, exactly 1 new bit is exposed in the mask - so everything
 // in the old table ends up on 1 of two lists in the new table; a hi and a
 // lo list depending on the value of the bit.
 void Dict::doubhash(void) {
   int oldsize = _size;
   _size <<= 1;                  // Double in size
   _bin = (bucket*)_arena->Arealloc( _bin, sizeof(bucket)*oldsize, sizeof(bucket)*_size );
   memset( &_bin[oldsize], 0, oldsize*sizeof(bucket) );
   // Rehash things to spread into new table
   for( int i=0; i < oldsize; i++) { // For complete OLD table do
     bucket *b = &_bin[i];       // Handy shortcut for _bin[i]
     if( !b->_keyvals ) continue;        // Skip empties fast

     bucket *nb = &_bin[i+oldsize];  // New bucket shortcut
     int j = b->_max;                // Trim new bucket to nearest power of 2
     while( j > b->_cnt ) j >>= 1;   // above old bucket _cnt
     if( !j ) j = 1;             // Handle zero-sized buckets
     nb->_max = j<<1;
     // Allocate worst case space for key-value pairs
     nb->_keyvals = (const void**)_arena->Amalloc_4( sizeof(void *)*nb->_max*2 );
     int nbcnt = 0;

     for( j=0; j<b->_cnt; j++ ) {  // Rehash all keys in this bucket
       const void *key = b->_keyvals[j+j];
       if( (_hash( key ) & (_size-1)) != i ) { // Moving to hi bucket?
         nb->_keyvals[nbcnt+nbcnt] = key;
         nb->_keyvals[nbcnt+nbcnt+1] = b->_keyvals[j+j+1];
         nb->_cnt = nbcnt = nbcnt+1;
         b->_cnt--;              // Remove key/value from lo bucket
         b->_keyvals[j+j  ] = b->_keyvals[b->_cnt+b->_cnt  ];
         b->_keyvals[j+j+1] = b->_keyvals[b->_cnt+b->_cnt+1];
         j--;                    // Hash compacted element also
       }
     } // End of for all key-value pairs in bucket
   } // End of for all buckets


 }

 //------------------------------Dict-----------------------------------------
 // Deep copy a dictionary.
 Dict::Dict( const Dict &d ) : _size(d._size), _cnt(d._cnt), _hash(d._hash),_cmp(d._cmp), _arena(d._arena) {
   _bin = (bucket*)_arena->Amalloc_4(sizeof(bucket)*_size);
   memcpy( _bin, d._bin, sizeof(bucket)*_size );
   for( int i=0; i<_size; i++ ) {
     if( !_bin[i]._keyvals ) continue;
     _bin[i]._keyvals=(const void**)_arena->Amalloc_4( sizeof(void *)*_bin[i]._max*2);
     memcpy( _bin[i]._keyvals, d._bin[i]._keyvals,_bin[i]._cnt*2*sizeof(void*));
   }
 }

 //------------------------------Dict-----------------------------------------
 // Deep copy a dictionary.
 Dict &Dict::operator =( const Dict &d ) {
   if( _size < d._size ) {       // If must have more buckets
     _arena = d._arena;
     _bin = (bucket*)_arena->Arealloc( _bin, sizeof(bucket)*_size, sizeof(bucket)*d._size );
     memset( &_bin[_size], 0, (d._size-_size)*sizeof(bucket) );
     _size = d._size;
   }
   for( int i=0; i<_size; i++ ) // All buckets are empty
     _bin[i]._cnt = 0;           // But leave bucket allocations alone
   _cnt = d._cnt;
   *(Hash*)(&_hash) = d._hash;
   *(CmpKey*)(&_cmp) = d._cmp;
   for(int k=0; k<_size; k++ ) {
     bucket *b = &d._bin[k];     // Shortcut to source bucket
     for( int j=0; j<b->_cnt; j++ )
       Insert( b->_keyvals[j+j], b->_keyvals[j+j+1] );
   }
   return *this;
 }

 //------------------------------Insert---------------------------------------
 // Insert or replace a key/value pair in the given dictionary.  If the
 // dictionary is too full, it's size is doubled.  The prior value being
 // replaced is returned (NULL if this is a 1st insertion of that key).  If
 // an old value is found, it's swapped with the prior key-value pair on the
 // list.  This moves a commonly searched-for value towards the list head.
 const void *Dict::Insert(const void *key, const void *val) {
   int hash = _hash( key );      // Get hash key
   int i = hash & (_size-1);     // Get hash key, corrected for size
   bucket *b = &_bin[i];         // Handy shortcut
   for( int j=0; j<b->_cnt; j++ )
     if( !_cmp(key,b->_keyvals[j+j]) ) {
       const void *prior = b->_keyvals[j+j+1];
       b->_keyvals[j+j  ] = key; // Insert current key-value
       b->_keyvals[j+j+1] = val;
       return prior;             // Return prior
     }

   if( ++_cnt > _size ) {        // Hash table is full
     doubhash();                 // Grow whole table if too full
     i = hash & (_size-1);       // Rehash
     b = &_bin[i];               // Handy shortcut
   }
   if( b->_cnt == b->_max ) {    // Must grow bucket?
     if( !b->_keyvals ) {
       b->_max = 2;              // Initial bucket size
       b->_keyvals = (const void**)_arena->Amalloc_4( sizeof(void *)*b->_max*2 );
     } else {
       b->_keyvals = (const void**)_arena->Arealloc( b->_keyvals, sizeof(void *)*b->_max*2, sizeof(void *)*b->_max*4 );
       b->_max <<= 1;            // Double bucket
     }
   }
   b->_keyvals[b->_cnt+b->_cnt  ] = key;
   b->_keyvals[b->_cnt+b->_cnt+1] = val;
   b->_cnt++;
   return NULL;                  // Nothing found prior
 }

 //------------------------------Delete---------------------------------------
 // Find & remove a value from dictionary. Return old value.
 const void *Dict::Delete(void *key) {
   int i = _hash( key ) & (_size-1);     // Get hash key, corrected for size
   bucket *b = &_bin[i];         // Handy shortcut
   for( int j=0; j<b->_cnt; j++ )
     if( !_cmp(key,b->_keyvals[j+j]) ) {
       const void *prior = b->_keyvals[j+j+1];
       b->_cnt--;                // Remove key/value from lo bucket
       b->_keyvals[j+j  ] = b->_keyvals[b->_cnt+b->_cnt  ];
       b->_keyvals[j+j+1] = b->_keyvals[b->_cnt+b->_cnt+1];
       _cnt--;                   // One less thing in table
       return prior;
     }
   return NULL;
 }

 //------------------------------FindDict-------------------------------------
 // Find a key-value pair in the given dictionary.  If not found, return NULL.
 // If found, move key-value pair towards head of list.
 const void *Dict::operator [](const void *key) const {
   int i = _hash( key ) & (_size-1);     // Get hash key, corrected for size
   bucket *b = &_bin[i];         // Handy shortcut
   for( int j=0; j<b->_cnt; j++ )
     if( !_cmp(key,b->_keyvals[j+j]) )
       return b->_keyvals[j+j+1];
   return NULL;
 }

 //------------------------------CmpDict--------------------------------------
 // CmpDict compares two dictionaries; they must have the same keys (their
 // keys must match using CmpKey) and they must have the same values (pointer
 // comparison).  If so 1 is returned, if not 0 is returned.
 int Dict::operator ==(const Dict &d2) const {
   if( _cnt != d2._cnt ) return 0;
   if( _hash != d2._hash ) return 0;
   if( _cmp != d2._cmp ) return 0;
   for( int i=0; i < _size; i++) {       // For complete hash table do
     bucket *b = &_bin[i];       // Handy shortcut
     if( b->_cnt != d2._bin[i]._cnt ) return 0;
     if( memcmp(b->_keyvals, d2._bin[i]._keyvals, b->_cnt*2*sizeof(void*) ) )
       return 0;                 // Key-value pairs must match
   }
   return 1;                     // All match, is OK
 }


 //------------------------------print----------------------------------------
 static void printvoid(const void* x) { printf("%p", x);  }
 void Dict::print() {
   print(printvoid, printvoid);
 }
 void Dict::print(PrintKeyOrValue print_key, PrintKeyOrValue print_value) {
   for( int i=0; i < _size; i++) {       // For complete hash table do
     bucket *b = &_bin[i];       // Handy shortcut
     for( int j=0; j<b->_cnt; j++ ) {
       print_key(  b->_keyvals[j+j  ]);
       printf(" -> ");
       print_value(b->_keyvals[j+j+1]);
       printf("\n");
     }
   }
 }

 //------------------------------Hashing Functions----------------------------
 // Convert string to hash key.  This algorithm implements a universal hash
 // function with the multipliers frozen (ok, so it's not universal).  The
 // multipliers (and allowable characters) are all odd, so the resultant sum
 // is odd - guaranteed not divisible by any power of two, so the hash tables
 // can be any power of two with good results.  Also, I choose multipliers
 // that have only 2 bits set (the low is always set to be odd) so
 // multiplication requires only shifts and adds.  Characters are required to
 // be in the range 0-127 (I double & add 1 to force oddness).  Keys are
 // limited to MAXID characters in length.  Experimental evidence on 150K of
 // C text shows excellent spreading of values for any size hash table.
 int hashstr(const void *t) {
   register char c, k = 0;
   register int sum = 0;
   register const char *s = (const char *)t;

   while (((c = s[k]) != '\0') && (k < MAXID-1)) { // Get characters till nul
     c = (char) ((c << 1) + 1);    // Characters are always odd!
     sum += c + (c << shft[k++]);  // Universal hash function
   }
   assert(k < (MAXID), "Exceeded maximum name length");
   return (int)((sum+xsum[k]) >> 1); // Hash key, un-modulo'd table size
 }

 //------------------------------hashptr--------------------------------------
 // Slimey cheap hash function; no guaranteed performance.  Better than the
 // default for pointers, especially on MS-DOS machines.
 int hashptr(const void *key) {
 #ifdef __TURBOC__
     return (int)((intptr_t)key >> 16);
 #else  // __TURBOC__
     return (int)((intptr_t)key >> 2);
 #endif
 }

 // Slimey cheap hash function; no guaranteed performance.
 int hashkey(const void *key) {
   return (int)((intptr_t)key);
 }

 //------------------------------Key Comparator Functions---------------------
 int cmpstr(const void *k1, const void *k2) {
   return strcmp((const char *)k1,(const char *)k2);
 }

 // Cheap key comparator.
 int cmpkey(const void *key1, const void *key2) {
   if (key1 == key2) return 0;
   intptr_t delta = (intptr_t)key1 - (intptr_t)key2;
   if (delta > 0) return 1;
   return -1;
 }

 //=============================================================================
 //------------------------------reset------------------------------------------
 // Create an iterator and initialize the first variables.
 void DictI::reset( const Dict *dict ) {
   _d = dict;                    // The dictionary
   _i = (int)-1;         // Before the first bin
   _j = 0;                       // Nothing left in the current bin
   ++(*this);                    // Step to first real value
 }

 //------------------------------next-------------------------------------------
 // Find the next key-value pair in the dictionary, or return a NULL key and
 // value.
 void DictI::operator ++(void) {
   if( _j-- ) {                  // Still working in current bin?
     _key   = _d->_bin[_i]._keyvals[_j+_j];
     _value = _d->_bin[_i]._keyvals[_j+_j+1];
     return;
   }

   while( ++_i < _d->_size ) {   // Else scan for non-zero bucket
     _j = _d->_bin[_i]._cnt;
     if( !_j ) continue;
     _j--;
     _key   = _d->_bin[_i]._keyvals[_j+_j];
     _value = _d->_bin[_i]._keyvals[_j+_j+1];
     return;
   }
   _key = _value = NULL;
 }
	/*
	* Copyright (c) 1998, 2013, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code 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 General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	// Dictionaries - An Abstract Data Type

	#include "adlc.hpp"

	// #include "dict.hpp"


	//------------------------------data-----------------------------------------
	// String hash tables
	#define MAXID 20
	static char initflag = 0; // True after 1st initialization
	static char shft[MAXID + 1] = {1,2,3,4,5,6,7,1,2,3,4,5,6,7,1,2,3,4,5,6,7};
	static short xsum[MAXID];

	//------------------------------bucket---------------------------------------
	class bucket {
	public:
	int _cnt, _max; // Size of bucket
	const void **_keyvals; // Array of keys and values
	};

	//------------------------------Dict-----------------------------------------
	// The dictionary is kept has a hash table. The hash table is a even power
	// of two, for nice modulo operations. Each bucket in the hash table points
	// to a linear list of key-value pairs; each key & value is just a (void *).
	// The list starts with a count. A hash lookup finds the list head, then a
	// simple linear scan finds the key. If the table gets too full, it's
	// doubled in size; the total amount of EXTRA times all hash functions are
	// computed for the doubling is no more than the current size - thus the
	// doubling in size costs no more than a constant factor in speed.
	Dict::Dict(CmpKey initcmp, Hash inithash) : _hash(inithash), _cmp(initcmp), _arena(NULL) {
	init();
	}

	Dict::Dict(CmpKey initcmp, Hash inithash, Arena *arena) : _hash(inithash), _cmp(initcmp), _arena(arena) {
	init();
	}

	void Dict::init() {
	int i;

	// Precompute table of null character hashes
	if (!initflag) { // Not initializated yet?
	xsum[0] = (short) ((1 << shft[0]) + 1); // Initialize
	for( i = 1; i < MAXID; i++) {
	xsum[i] = (short) ((1 << shft[i]) + 1 + xsum[i-1]);
	}
	initflag = 1; // Never again
	}

	_size = 16; // Size is a power of 2
	_cnt = 0; // Dictionary is empty
	_bin = (bucket)_arena->Amalloc_4(sizeof(bucket) _size);
	memset(_bin, 0, sizeof(bucket) * _size);
	}

	//------------------------------~Dict------------------------------------------
	// Delete an existing dictionary.
	Dict::~Dict() {
	}

	//------------------------------Clear----------------------------------------
	// Zap to empty; ready for re-use
	void Dict::Clear() {
	_cnt = 0; // Empty contents
	for( int i=0; i<_size; i++ )
	_bin[i]._cnt = 0; // Empty buckets, but leave allocated
	// Leave _size & _bin alone, under the assumption that dictionary will
	// grow to this size again.
	}

	//------------------------------doubhash---------------------------------------
	// Double hash table size. If can't do so, just suffer. If can, then run
	// thru old hash table, moving things to new table. Note that since hash
	// table doubled, exactly 1 new bit is exposed in the mask - so everything
	// in the old table ends up on 1 of two lists in the new table; a hi and a
	// lo list depending on the value of the bit.
	void Dict::doubhash(void) {
	int oldsize = _size;
	_size <<= 1; // Double in size
	_bin = (bucket)_arena->Arealloc( _bin, sizeof(bucket)oldsize, sizeof(bucket)*_size );
	memset( &_bin[oldsize], 0, oldsize*sizeof(bucket) );
	// Rehash things to spread into new table
	for( int i=0; i < oldsize; i++) { // For complete OLD table do
	bucket *b = &_bin[i]; // Handy shortcut for _bin[i]
	if( !b->_keyvals ) continue; // Skip empties fast

	bucket *nb = &_bin[i+oldsize]; // New bucket shortcut
	int j = b->_max; // Trim new bucket to nearest power of 2
	while( j > b->_cnt ) j >>= 1; // above old bucket _cnt
	if( !j ) j = 1; // Handle zero-sized buckets
	nb->_max = j<<1;
	// Allocate worst case space for key-value pairs
	nb->_keyvals = (const void*)_arena->Amalloc_4( sizeof(void )nb->_max2 );
	int nbcnt = 0;

	for( j=0; j<b->_cnt; j++ ) { // Rehash all keys in this bucket
	const void *key = b->_keyvals[j+j];
	if( (_hash( key ) & (_size-1)) != i ) { // Moving to hi bucket?
	nb->_keyvals[nbcnt+nbcnt] = key;
	nb->_keyvals[nbcnt+nbcnt+1] = b->_keyvals[j+j+1];
	nb->_cnt = nbcnt = nbcnt+1;
	b->_cnt--; // Remove key/value from lo bucket
	b->_keyvals[j+j ] = b->_keyvals[b->_cnt+b->_cnt ];
	b->_keyvals[j+j+1] = b->_keyvals[b->_cnt+b->_cnt+1];
	j--; // Hash compacted element also
	}
	} // End of for all key-value pairs in bucket
	} // End of for all buckets


	}

	//------------------------------Dict-----------------------------------------
	// Deep copy a dictionary.
	Dict::Dict( const Dict &d ) : _size(d._size), _cnt(d._cnt), _hash(d._hash),_cmp(d._cmp), _arena(d._arena) {
	_bin = (bucket)_arena->Amalloc_4(sizeof(bucket)_size);
	memcpy( _bin, d._bin, sizeof(bucket)*_size );
	for( int i=0; i<_size; i++ ) {
	if( !_bin[i]._keyvals ) continue;
	_bin[i]._keyvals=(const void*)_arena->Amalloc_4( sizeof(void )_bin[i]._max2);
	memcpy( _bin[i]._keyvals, d._bin[i]._keyvals,_bin[i]._cnt2sizeof(void*));
	}
	}

	//------------------------------Dict-----------------------------------------
	// Deep copy a dictionary.
	Dict &Dict::operator =( const Dict &d ) {
	if( _size < d._size ) { // If must have more buckets
	_arena = d._arena;
	_bin = (bucket)_arena->Arealloc( _bin, sizeof(bucket)_size, sizeof(bucket)*d._size );
	memset( &_bin[_size], 0, (d._size-_size)*sizeof(bucket) );
	_size = d._size;
	}
	for( int i=0; i<_size; i++ ) // All buckets are empty
	_bin[i]._cnt = 0; // But leave bucket allocations alone
	_cnt = d._cnt;
	(Hash)(&_hash) = d._hash;
	(CmpKey)(&_cmp) = d._cmp;
	for(int k=0; k<_size; k++ ) {
	bucket *b = &d._bin[k]; // Shortcut to source bucket
	for( int j=0; j<b->_cnt; j++ )
	Insert( b->_keyvals[j+j], b->_keyvals[j+j+1] );
	}
	return *this;
	}

	//------------------------------Insert---------------------------------------
	// Insert or replace a key/value pair in the given dictionary. If the
	// dictionary is too full, it's size is doubled. The prior value being
	// replaced is returned (NULL if this is a 1st insertion of that key). If
	// an old value is found, it's swapped with the prior key-value pair on the
	// list. This moves a commonly searched-for value towards the list head.
	const void Dict::Insert(const void key, const void *val) {
	int hash = _hash( key ); // Get hash key
	int i = hash & (_size-1); // Get hash key, corrected for size
	bucket *b = &_bin[i]; // Handy shortcut
	for( int j=0; j<b->_cnt; j++ )
	if( !_cmp(key,b->_keyvals[j+j]) ) {
	const void *prior = b->_keyvals[j+j+1];
	b->_keyvals[j+j ] = key; // Insert current key-value
	b->_keyvals[j+j+1] = val;
	return prior; // Return prior
	}

	if( ++_cnt > _size ) { // Hash table is full
	doubhash(); // Grow whole table if too full
	i = hash & (_size-1); // Rehash
	b = &_bin[i]; // Handy shortcut
	}
	if( b->_cnt == b->_max ) { // Must grow bucket?
	if( !b->_keyvals ) {
	b->_max = 2; // Initial bucket size
	b->_keyvals = (const void*)_arena->Amalloc_4( sizeof(void )b->_max2 );
	} else {
	b->_keyvals = (const void*)_arena->Arealloc( b->_keyvals, sizeof(void )b->_max2, sizeof(void )b->_max*4 );
	b->_max <<= 1; // Double bucket
	}
	}
	b->_keyvals[b->_cnt+b->_cnt ] = key;
	b->_keyvals[b->_cnt+b->_cnt+1] = val;
	b->_cnt++;
	return NULL; // Nothing found prior
	}

	//------------------------------Delete---------------------------------------
	// Find & remove a value from dictionary. Return old value.
	const void Dict::Delete(void key) {
	int i = _hash( key ) & (_size-1); // Get hash key, corrected for size
	bucket *b = &_bin[i]; // Handy shortcut
	for( int j=0; j<b->_cnt; j++ )
	if( !_cmp(key,b->_keyvals[j+j]) ) {
	const void *prior = b->_keyvals[j+j+1];
	b->_cnt--; // Remove key/value from lo bucket
	b->_keyvals[j+j ] = b->_keyvals[b->_cnt+b->_cnt ];
	b->_keyvals[j+j+1] = b->_keyvals[b->_cnt+b->_cnt+1];
	_cnt--; // One less thing in table
	return prior;
	}
	return NULL;
	}

	//------------------------------FindDict-------------------------------------
	// Find a key-value pair in the given dictionary. If not found, return NULL.
	// If found, move key-value pair towards head of list.
	const void Dict::operator [](const void key) const {
	int i = _hash( key ) & (_size-1); // Get hash key, corrected for size
	bucket *b = &_bin[i]; // Handy shortcut
	for( int j=0; j<b->_cnt; j++ )
	if( !_cmp(key,b->_keyvals[j+j]) )
	return b->_keyvals[j+j+1];
	return NULL;
	}

	//------------------------------CmpDict--------------------------------------
	// CmpDict compares two dictionaries; they must have the same keys (their
	// keys must match using CmpKey) and they must have the same values (pointer
	// comparison). If so 1 is returned, if not 0 is returned.
	int Dict::operator ==(const Dict &d2) const {
	if( _cnt != d2._cnt ) return 0;
	if( _hash != d2._hash ) return 0;
	if( _cmp != d2._cmp ) return 0;
	for( int i=0; i < _size; i++) { // For complete hash table do
	bucket *b = &_bin[i]; // Handy shortcut
	if( b->_cnt != d2._bin[i]._cnt ) return 0;
	if( memcmp(b->_keyvals, d2._bin[i]._keyvals, b->_cnt2sizeof(void*) ) )
	return 0; // Key-value pairs must match
	}
	return 1; // All match, is OK
	}


	//------------------------------print----------------------------------------
	static void printvoid(const void* x) { printf("%p", x); }
	void Dict::print() {
	print(printvoid, printvoid);
	}
	void Dict::print(PrintKeyOrValue print_key, PrintKeyOrValue print_value) {
	for( int i=0; i < _size; i++) { // For complete hash table do
	bucket *b = &_bin[i]; // Handy shortcut
	for( int j=0; j<b->_cnt; j++ ) {
	print_key( b->_keyvals[j+j ]);
	printf(" -> ");
	print_value(b->_keyvals[j+j+1]);
	printf("\n");
	}
	}
	}

	//------------------------------Hashing Functions----------------------------
	// Convert string to hash key. This algorithm implements a universal hash
	// function with the multipliers frozen (ok, so it's not universal). The
	// multipliers (and allowable characters) are all odd, so the resultant sum
	// is odd - guaranteed not divisible by any power of two, so the hash tables
	// can be any power of two with good results. Also, I choose multipliers
	// that have only 2 bits set (the low is always set to be odd) so
	// multiplication requires only shifts and adds. Characters are required to
	// be in the range 0-127 (I double & add 1 to force oddness). Keys are
	// limited to MAXID characters in length. Experimental evidence on 150K of
	// C text shows excellent spreading of values for any size hash table.
	int hashstr(const void *t) {
	register char c, k = 0;
	register int sum = 0;
	register const char s = (const char )t;

	while (((c = s[k]) != '\0') && (k < MAXID-1)) { // Get characters till nul
	c = (char) ((c << 1) + 1); // Characters are always odd!
	sum += c + (c << shft[k++]); // Universal hash function
	}
	assert(k < (MAXID), "Exceeded maximum name length");
	return (int)((sum+xsum[k]) >> 1); // Hash key, un-modulo'd table size
	}

	//------------------------------hashptr--------------------------------------
	// Slimey cheap hash function; no guaranteed performance. Better than the
	// default for pointers, especially on MS-DOS machines.
	int hashptr(const void *key) {
	#ifdef __TURBOC__
	return (int)((intptr_t)key >> 16);
	#else // __TURBOC__
	return (int)((intptr_t)key >> 2);
	#endif
	}

	// Slimey cheap hash function; no guaranteed performance.
	int hashkey(const void *key) {
	return (int)((intptr_t)key);
	}

	//------------------------------Key Comparator Functions---------------------
	int cmpstr(const void k1, const void k2) {
	return strcmp((const char )k1,(const char )k2);
	}

	// Cheap key comparator.
	int cmpkey(const void key1, const void key2) {
	if (key1 == key2) return 0;
	intptr_t delta = (intptr_t)key1 - (intptr_t)key2;
	if (delta > 0) return 1;
	return -1;
	}

	//=============================================================================
	//------------------------------reset------------------------------------------
	// Create an iterator and initialize the first variables.
	void DictI::reset( const Dict *dict ) {
	_d = dict; // The dictionary
	_i = (int)-1; // Before the first bin
	_j = 0; // Nothing left in the current bin
	++(*this); // Step to first real value
	}

	//------------------------------next-------------------------------------------
	// Find the next key-value pair in the dictionary, or return a NULL key and
	// value.
	void DictI::operator ++(void) {
	if( _j-- ) { // Still working in current bin?
	_key = _d->_bin[_i]._keyvals[_j+_j];
	_value = _d->_bin[_i]._keyvals[_j+_j+1];
	return;
	}

	while( ++_i < _d->_size ) { // Else scan for non-zero bucket
	_j = _d->_bin[_i]._cnt;
	if( !_j ) continue;
	_j--;
	_key = _d->_bin[_i]._keyvals[_j+_j];
	_value = _d->_bin[_i]._keyvals[_j+_j+1];
	return;
	}
	_key = _value = NULL;
	}