valgrind/coregrind/m_sparsewa.c - nest-cam/4320010/valgrind - Git at Google


 /*--------------------------------------------------------------------*/
 /*--- An sparse array (of words) implementation.                   ---*/
 /*---                                                 m_sparsewa.c ---*/
 /*--------------------------------------------------------------------*/

 /*
    This file is part of Valgrind, a dynamic binary instrumentation
    framework.

    Copyright (C) 2008-2015 OpenWorks Ltd
       info@open-works.co.uk

    This program is free software; you can redistribute it and/or
    modify it under the terms of the GNU General Public License as
    published by the Free Software Foundation; either version 2 of the
    License, or (at your option) any later version.

    This program 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 for more details.

    You should have received a copy of the GNU General Public License
    along with this program; if not, write to the Free Software
    Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
    02111-1307, USA.

    The GNU General Public License is contained in the file COPYING.
 */

 #include "pub_core_basics.h"
 #include "pub_core_libcassert.h"
 #include "pub_core_libcbase.h"
 #include "pub_core_sparsewa.h"      /* self */

 /////////////////////////////////////////////////////////
 //                                                     //
 // SparseWA: Implementation                            //
 //                                                     //
 /////////////////////////////////////////////////////////

 //////// SWA data structures

 // (UInt) `echo "Level Zero Byte Map" | md5sum`
 #define Level0_MAGIC 0x458ec222

 // (UInt) `echo "Level N Byte Map" | md5sum`
 #define LevelN_MAGIC 0x0a280a1a

 /* It's important that the .magic field appears at offset zero in both
    structs, so that we can reliably distinguish between them. */

 typedef
    struct {
       UWord magic;
       UWord words[256];
       Int   nInUse;
       UChar inUse[256/8];
    }
    Level0;

 typedef
    struct {
       UWord magic;
       void* child[256]; /* either LevelN* or Level0* */
       Int   nInUse;
       Int   level; /* 3 .. 1 on 32-bit, 7 .. 1 on 64-bit */
    }
    LevelN;

 typedef
    struct {
       UWord partial_key;
       Int   curr_ix;
       void* curr_nd; /* LevelN* or Level0* */
       Int   resume_point; /* 1, 2 or 3 */
    }
    SWAStackElem;

 struct _SparseWA {
    void*        (*alloc_nofail)(const HChar*,SizeT);
    const HChar* cc;
    void         (*dealloc)(void*);
    LevelN*      root;
    SWAStackElem iterStack[8];
    Int          isUsed;
 };

 //////// SWA helper functions (bitarray)

 static inline UWord swa_bitarray_read ( const UChar* arr, UWord ix ) {
    UWord bix = ix >> 3;
    UWord off = ix & 7;
    return (arr[bix] >> off) & 1;
 }

 static inline UWord swa_bitarray_read_then_set ( UChar* arr, UWord ix ) {
    UWord bix = ix >> 3;
    UWord off = ix & 7;
    UChar old = arr[bix];
    UChar nyu = old | (1 << off);
    arr[bix] = nyu;
    return (old >> off) & 1;
 }

 static inline UWord swa_bitarray_read_then_clear ( UChar* arr, UWord ix ) {
    UWord bix = ix >> 3;
    UWord off = ix & 7;
    UChar old = arr[bix];
    UChar nyu = old & ~(1 << off);
    arr[bix] = nyu;
    return (old >> off) & 1;
 }

 //////// SWA helper functions (iteration)

 static void swa_PUSH ( SparseWA* swa, UWord partial_key, Int curr_ix,
                                       void* curr_nd, Int resume_point )
 {
    Int sp = swa->isUsed;
    const Int _3_or_7 = sizeof(void*) - 1;
    // if (0) VG_(printf)("PUSH, old sp = %d\n", sp);
    vg_assert(sp >= 0 && sp <= _3_or_7);
    swa->iterStack[sp].partial_key  = partial_key;
    swa->iterStack[sp].curr_ix      = curr_ix;
    swa->iterStack[sp].curr_nd      = curr_nd;
    swa->iterStack[sp].resume_point = resume_point;
    swa->isUsed = sp+1;
 }

 static void swa_POP ( SparseWA* swa,
                       UWord* partial_key, Int* curr_ix,
                       void** curr_nd, Int* resume_point )
 {
    Int sp = swa->isUsed - 1;
    const Int _3_or_7 = sizeof(void*) - 1;
    // if (0) VG_(printf)("POP,  old sp = %d\n", sp+1);
    vg_assert(sp >= 0 && sp <= _3_or_7);
    *partial_key  = swa->iterStack[sp].partial_key;
    *curr_ix      = swa->iterStack[sp].curr_ix;
    *curr_nd      = swa->iterStack[sp].curr_nd;
    *resume_point = swa->iterStack[sp].resume_point;
    swa->isUsed = sp;
 }

 //////// SWA helper functions (allocation)

 static LevelN* swa_new_LevelN ( const SparseWA* swa, Int level )
 {
    LevelN* levelN = swa->alloc_nofail( swa->cc, sizeof(LevelN) );
    VG_(memset)(levelN, 0, sizeof(*levelN));
    levelN->magic = LevelN_MAGIC;
    levelN->level = level;
    return levelN;
 }

 static Level0* swa_new_Level0 ( const SparseWA* swa )
 {
    Level0* level0 = swa->alloc_nofail( swa->cc, sizeof(Level0) );
    VG_(memset)(level0, 0, sizeof(*level0));
    level0->magic = Level0_MAGIC;
    return level0;
 }


 //////// SWA public interface

 void VG_(initIterSWA) ( SparseWA* swa )
 {
    swa->isUsed = 0;
    if (swa->root) swa_PUSH(swa, 0, 0, swa->root, 1/*start_new_node*/);
 }


 Bool VG_(nextIterSWA)( SparseWA* swa,
                        /*OUT*/UWord* keyP, /*OUT*/UWord* valP )
 {
    UWord p_key;
    Int   curr_ix;
    void* curr_nd;
    Int   resume_point;

    /* dispatch whatever's on top of the stack; what that actually
       means is to return to some previously-saved context. */
    dispatch:

    if (swa->isUsed == 0)
       return False;

    swa_POP(swa, &p_key, &curr_ix, &curr_nd, &resume_point);
    switch (resume_point) {
       case 1:  goto start_new_node;
       case 2:  goto resume_leaf_node;
       case 3:  goto resume_nonleaf_node;
       default: vg_assert(0);
    }

    start_new_node:
    if (*(UWord*)curr_nd == Level0_MAGIC) {
       /* curr_nd is a leaf node */
       Level0* level0 = (Level0*)curr_nd;
       for (curr_ix = 0; curr_ix < 256; curr_ix++) {
          if (swa_bitarray_read(level0->inUse, curr_ix) == 1) {
             swa_PUSH(swa, p_key, curr_ix, curr_nd, 2/*resume_leaf_node*/);
             *keyP = (p_key << 8) + (UWord)curr_ix;
             *valP = level0->words[curr_ix];
             return True;
             resume_leaf_node:
             level0 = (Level0*)curr_nd;
          }
       }
    } else {
       /* curr_nd is a non-leaf node */
       LevelN* levelN;
       vg_assert(*(UWord*)curr_nd == LevelN_MAGIC);
       levelN = (LevelN*)curr_nd;
       for (curr_ix = 0; curr_ix < 256; curr_ix++) {
          if (levelN->child[curr_ix]) {
             swa_PUSH(swa, p_key, curr_ix, curr_nd, 3/*resume_nonleaf_node*/);
             p_key = (p_key << 8) + (UWord)curr_ix;
             curr_nd = levelN->child[curr_ix];
             goto start_new_node;
             resume_nonleaf_node:
             levelN = (LevelN*)curr_nd;
          }
       }
    }

    goto dispatch;
 }


 SparseWA* VG_(newSWA) ( void*(*alloc_nofail)(const HChar* cc, SizeT),
                         const HChar* cc,
                         void(*dealloc)(void*) )
 {
    SparseWA* swa;
    vg_assert(alloc_nofail);
    vg_assert(cc);
    vg_assert(dealloc);
    swa = alloc_nofail( cc, sizeof(SparseWA) );
    VG_(memset)(swa, 0, sizeof(*swa));
    swa->alloc_nofail = alloc_nofail;
    swa->cc = cc;
    swa->dealloc = dealloc;
    swa->root = NULL;
    return swa;
 }


 static void swa_deleteSWA_wrk ( void(*dealloc)(void*), void* nd )
 {
    Int i;
    vg_assert(nd);
    if (*(UWord*)nd == LevelN_MAGIC) {
       LevelN* levelN = (LevelN*)nd;
       for (i = 0; i < 256; i++) {
          if (levelN->child[i]) {
             swa_deleteSWA_wrk( dealloc, levelN->child[i] );
          }
       }
    } else {
       vg_assert(*(UWord*)nd == Level0_MAGIC);
    }
    dealloc(nd);
 }
 void VG_(deleteSWA) ( SparseWA* swa )
 {
    if (swa->root)
       swa_deleteSWA_wrk( swa->dealloc, swa->root );
    swa->dealloc(swa);
 }


 Bool VG_(lookupSWA) ( const SparseWA* swa,
                       /*OUT*/UWord* valP,
                       UWord key )
 {
    Int     i;
    UWord   ix;
    Level0* level0;
    LevelN* levelN;
    const Int _3_or_7 = sizeof(void*) - 1;

    vg_assert(swa);
    levelN = swa->root;

    /* levels 3/7 .. 1 */
    for (i = _3_or_7; i >= 1; i--) {
       if (!levelN) return False;
       vg_assert(levelN->level == i);
       vg_assert(levelN->nInUse > 0);
       ix = (key >> (i*8)) & 0xFF;
       levelN = levelN->child[ix];
    }

    /* level0 */
    level0 = (Level0*)levelN;
    if (!level0) return False;
    vg_assert(level0->magic == Level0_MAGIC);
    vg_assert(level0->nInUse > 0);
    ix = key & 0xFF;
    if (swa_bitarray_read(level0->inUse, ix) == 0) return False;
    *valP = level0->words[ix];
    return True;
 }


 Bool VG_(addToSWA) ( SparseWA* swa, UWord key, UWord val )
 {
    Int     i;
    UWord   ix;
    Level0* level0;
    LevelN* levelN;
    Bool    already_present;
    const Int _3_or_7 = sizeof(void*) - 1;

    vg_assert(swa);

    if (!swa->root)
       swa->root = swa_new_LevelN(swa, _3_or_7);
    levelN = swa->root;

    /* levels 3/7 .. 2 */
    for (i = _3_or_7; i >= 2; i--) {
       /* levelN is the level-i map */
       vg_assert(levelN);
       vg_assert(levelN->level == i);
       ix = (key >> (i*8)) & 0xFF;
       if (levelN->child[ix] == NULL) {
          levelN->child[ix] = swa_new_LevelN(swa, i-1);
          levelN->nInUse++;
       }
       vg_assert(levelN->nInUse >= 1 && levelN->nInUse <= 256);
       levelN = levelN->child[ix];
    }

    /* levelN is the level-1 map */
    vg_assert(levelN);
    vg_assert(levelN->level == 1);
    ix = (key >> (1*8)) & 0xFF;
    if (levelN->child[ix] == NULL) {
       levelN->child[ix] = swa_new_Level0(swa);
       levelN->nInUse++;
    }
    vg_assert(levelN->nInUse >= 1 && levelN->nInUse <= 256);
    level0 = levelN->child[ix];

    /* level0 is the level-0 map */
    vg_assert(level0);
    vg_assert(level0->magic == Level0_MAGIC);
    ix = key & 0xFF;
    if (swa_bitarray_read_then_set(level0->inUse, ix) == 0) {
       level0->nInUse++;
       already_present = False;
    } else {
       already_present = True;
    }
    vg_assert(level0->nInUse >= 1 && level0->nInUse <= 256);
    level0->words[ix] = val;

    return already_present;
 }


 Bool VG_(delFromSWA) ( SparseWA* swa,
                        /*OUT*/UWord* oldV, UWord key )
 {
    Int     i;
    UWord   ix;
    Level0* level0;
    LevelN* levelN;
    const Int _3_or_7 = sizeof(void*) - 1;

    LevelN* visited[_3_or_7];
    UWord   visitedIx[_3_or_7];
    Int     nVisited = 0;

    vg_assert(swa);
    levelN = swa->root;

    /* levels 3/7 .. 1 */
    for (i = _3_or_7; i >= 1; i--) {
       /* level i */
       if (!levelN) return False;
       vg_assert(levelN->level == i);
       vg_assert(levelN->nInUse > 0);
       ix = (key >> (i*8)) & 0xFF;
       visited[nVisited]     = levelN;
       visitedIx[nVisited++] = ix;
       levelN = levelN->child[ix];
    }

    /* level 0 */
    level0 = (Level0*)levelN;
    if (!level0) return False;
    vg_assert(level0->magic == Level0_MAGIC);
    vg_assert(level0->nInUse > 0);
    ix = key & 0xFF;

    if (swa_bitarray_read_then_clear(level0->inUse, ix) == 0)
       return False;

    *oldV = level0->words[ix];

    level0->nInUse--;
    if (level0->nInUse > 0)
       return True;

    vg_assert(nVisited == _3_or_7);
    swa->dealloc( level0 );

    /* levels 1 .. 3/7 */
    for (i = 1; i <= _3_or_7; i++) {
       /* level i */
       nVisited--;
       vg_assert(visited[nVisited]->child[ visitedIx[nVisited] ]);
       visited[nVisited]->child[ visitedIx[nVisited] ] = NULL;
       visited[nVisited]->nInUse--;
       vg_assert(visited[nVisited]->nInUse >= 0);
       if (visited[nVisited]->nInUse > 0)
          return True;
       swa->dealloc(visited[nVisited]);
    }

    vg_assert(nVisited == 0);
    swa->root = NULL;
    return True;
 }


 static UWord swa_sizeSWA_wrk ( const void* nd )
 {
    Int   i;
    if (*(const UWord*)nd == LevelN_MAGIC) {
       UWord sum = 0;
       const LevelN* levelN = nd;
       for (i = 0; i < 256; i++) {
          if (levelN->child[i]) {
             sum += swa_sizeSWA_wrk( levelN->child[i] );
          }
       }
       return sum;
    } else {
       const Level0* level0;
       vg_assert(*(const UWord*)nd == Level0_MAGIC);
       level0 = nd;
       return level0->nInUse;
    }
 }
 UWord VG_(sizeSWA) ( const SparseWA* swa )
 {
    if (swa->root)
       return swa_sizeSWA_wrk ( swa->root );
    else
       return 0;
 }


 /*--------------------------------------------------------------------*/
 /*--- end                                             m_sparsewa.c ---*/
 /*--------------------------------------------------------------------*/

	/--------------------------------------------------------------------/
	/--- An sparse array (of words) implementation. ---/
	/--- m_sparsewa.c ---/
	/--------------------------------------------------------------------/

	/*
	This file is part of Valgrind, a dynamic binary instrumentation
	framework.

	Copyright (C) 2008-2015 OpenWorks Ltd
	info@open-works.co.uk

	This program is free software; you can redistribute it and/or
	modify it under the terms of the GNU General Public License as
	published by the Free Software Foundation; either version 2 of the
	License, or (at your option) any later version.

	This program 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 for more details.

	You should have received a copy of the GNU General Public License
	along with this program; if not, write to the Free Software
	Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
	02111-1307, USA.

	The GNU General Public License is contained in the file COPYING.
	*/

	#include "pub_core_basics.h"
	#include "pub_core_libcassert.h"
	#include "pub_core_libcbase.h"
	#include "pub_core_sparsewa.h" /* self */

	/////////////////////////////////////////////////////////
	// //
	// SparseWA: Implementation //
	// //
	/////////////////////////////////////////////////////////

	//////// SWA data structures

	// (UInt) `echo "Level Zero Byte Map" \| md5sum`
	#define Level0_MAGIC 0x458ec222

	// (UInt) `echo "Level N Byte Map" \| md5sum`
	#define LevelN_MAGIC 0x0a280a1a

	/* It's important that the .magic field appears at offset zero in both
	structs, so that we can reliably distinguish between them. */

	typedef
	struct {
	UWord magic;
	UWord words[256];
	Int nInUse;
	UChar inUse[256/8];
	}
	Level0;

	typedef
	struct {
	UWord magic;
	void* child[256]; /* either LevelN* or Level0* */
	Int nInUse;
	Int level; /* 3 .. 1 on 32-bit, 7 .. 1 on 64-bit */
	}
	LevelN;

	typedef
	struct {
	UWord partial_key;
	Int curr_ix;
	void* curr_nd; /* LevelN* or Level0* */
	Int resume_point; /* 1, 2 or 3 */
	}
	SWAStackElem;

	struct _SparseWA {
	void* (alloc_nofail)(const HChar,SizeT);
	const HChar* cc;
	void (dealloc)(void);
	LevelN* root;
	SWAStackElem iterStack[8];
	Int isUsed;
	};

	//////// SWA helper functions (bitarray)

	static inline UWord swa_bitarray_read ( const UChar* arr, UWord ix ) {
	UWord bix = ix >> 3;
	UWord off = ix & 7;
	return (arr[bix] >> off) & 1;
	}

	static inline UWord swa_bitarray_read_then_set ( UChar* arr, UWord ix ) {
	UWord bix = ix >> 3;
	UWord off = ix & 7;
	UChar old = arr[bix];
	UChar nyu = old \| (1 << off);
	arr[bix] = nyu;
	return (old >> off) & 1;
	}

	static inline UWord swa_bitarray_read_then_clear ( UChar* arr, UWord ix ) {
	UWord bix = ix >> 3;
	UWord off = ix & 7;
	UChar old = arr[bix];
	UChar nyu = old & ~(1 << off);
	arr[bix] = nyu;
	return (old >> off) & 1;
	}

	//////// SWA helper functions (iteration)

	static void swa_PUSH ( SparseWA* swa, UWord partial_key, Int curr_ix,
	void* curr_nd, Int resume_point )
	{
	Int sp = swa->isUsed;
	const Int _3_or_7 = sizeof(void*) - 1;
	// if (0) VG_(printf)("PUSH, old sp = %d\n", sp);
	vg_assert(sp >= 0 && sp <= _3_or_7);
	swa->iterStack[sp].partial_key = partial_key;
	swa->iterStack[sp].curr_ix = curr_ix;
	swa->iterStack[sp].curr_nd = curr_nd;
	swa->iterStack[sp].resume_point = resume_point;
	swa->isUsed = sp+1;
	}

	static void swa_POP ( SparseWA* swa,
	UWord* partial_key, Int* curr_ix,
	void** curr_nd, Int* resume_point )
	{
	Int sp = swa->isUsed - 1;
	const Int _3_or_7 = sizeof(void*) - 1;
	// if (0) VG_(printf)("POP, old sp = %d\n", sp+1);
	vg_assert(sp >= 0 && sp <= _3_or_7);
	*partial_key = swa->iterStack[sp].partial_key;
	*curr_ix = swa->iterStack[sp].curr_ix;
	*curr_nd = swa->iterStack[sp].curr_nd;
	*resume_point = swa->iterStack[sp].resume_point;
	swa->isUsed = sp;
	}

	//////// SWA helper functions (allocation)

	static LevelN* swa_new_LevelN ( const SparseWA* swa, Int level )
	{
	LevelN* levelN = swa->alloc_nofail( swa->cc, sizeof(LevelN) );
	VG_(memset)(levelN, 0, sizeof(*levelN));
	levelN->magic = LevelN_MAGIC;
	levelN->level = level;
	return levelN;
	}

	static Level0* swa_new_Level0 ( const SparseWA* swa )
	{
	Level0* level0 = swa->alloc_nofail( swa->cc, sizeof(Level0) );
	VG_(memset)(level0, 0, sizeof(*level0));
	level0->magic = Level0_MAGIC;
	return level0;
	}


	//////// SWA public interface

	void VG_(initIterSWA) ( SparseWA* swa )
	{
	swa->isUsed = 0;
	if (swa->root) swa_PUSH(swa, 0, 0, swa->root, 1/start_new_node/);
	}


	Bool VG_(nextIterSWA)( SparseWA* swa,
	/OUT/UWord* keyP, /OUT/UWord* valP )
	{
	UWord p_key;
	Int curr_ix;
	void* curr_nd;
	Int resume_point;

	/* dispatch whatever's on top of the stack; what that actually
	means is to return to some previously-saved context. */
	dispatch:

	if (swa->isUsed == 0)
	return False;

	swa_POP(swa, &p_key, &curr_ix, &curr_nd, &resume_point);
	switch (resume_point) {
	case 1: goto start_new_node;
	case 2: goto resume_leaf_node;
	case 3: goto resume_nonleaf_node;
	default: vg_assert(0);
	}

	start_new_node:
	if ((UWord)curr_nd == Level0_MAGIC) {
	/* curr_nd is a leaf node */
	Level0* level0 = (Level0*)curr_nd;
	for (curr_ix = 0; curr_ix < 256; curr_ix++) {
	if (swa_bitarray_read(level0->inUse, curr_ix) == 1) {
	swa_PUSH(swa, p_key, curr_ix, curr_nd, 2/resume_leaf_node/);
	*keyP = (p_key << 8) + (UWord)curr_ix;
	*valP = level0->words[curr_ix];
	return True;
	resume_leaf_node:
	level0 = (Level0*)curr_nd;
	}
	}
	} else {
	/* curr_nd is a non-leaf node */
	LevelN* levelN;
	vg_assert((UWord)curr_nd == LevelN_MAGIC);
	levelN = (LevelN*)curr_nd;
	for (curr_ix = 0; curr_ix < 256; curr_ix++) {
	if (levelN->child[curr_ix]) {
	swa_PUSH(swa, p_key, curr_ix, curr_nd, 3/resume_nonleaf_node/);
	p_key = (p_key << 8) + (UWord)curr_ix;
	curr_nd = levelN->child[curr_ix];
	goto start_new_node;
	resume_nonleaf_node:
	levelN = (LevelN*)curr_nd;
	}
	}
	}

	goto dispatch;
	}


	SparseWA* VG_(newSWA) ( void(alloc_nofail)(const HChar* cc, SizeT),
	const HChar* cc,
	void(dealloc)(void) )
	{
	SparseWA* swa;
	vg_assert(alloc_nofail);
	vg_assert(cc);
	vg_assert(dealloc);
	swa = alloc_nofail( cc, sizeof(SparseWA) );
	VG_(memset)(swa, 0, sizeof(*swa));
	swa->alloc_nofail = alloc_nofail;
	swa->cc = cc;
	swa->dealloc = dealloc;
	swa->root = NULL;
	return swa;
	}


	static void swa_deleteSWA_wrk ( void(dealloc)(void), void* nd )
	{
	Int i;
	vg_assert(nd);
	if ((UWord)nd == LevelN_MAGIC) {
	LevelN* levelN = (LevelN*)nd;
	for (i = 0; i < 256; i++) {
	if (levelN->child[i]) {
	swa_deleteSWA_wrk( dealloc, levelN->child[i] );
	}
	}
	} else {
	vg_assert((UWord)nd == Level0_MAGIC);
	}
	dealloc(nd);
	}
	void VG_(deleteSWA) ( SparseWA* swa )
	{
	if (swa->root)
	swa_deleteSWA_wrk( swa->dealloc, swa->root );
	swa->dealloc(swa);
	}


	Bool VG_(lookupSWA) ( const SparseWA* swa,
	/OUT/UWord* valP,
	UWord key )
	{
	Int i;
	UWord ix;
	Level0* level0;
	LevelN* levelN;
	const Int _3_or_7 = sizeof(void*) - 1;

	vg_assert(swa);
	levelN = swa->root;

	/* levels 3/7 .. 1 */
	for (i = _3_or_7; i >= 1; i--) {
	if (!levelN) return False;
	vg_assert(levelN->level == i);
	vg_assert(levelN->nInUse > 0);
	ix = (key >> (i*8)) & 0xFF;
	levelN = levelN->child[ix];
	}

	/* level0 */
	level0 = (Level0*)levelN;
	if (!level0) return False;
	vg_assert(level0->magic == Level0_MAGIC);
	vg_assert(level0->nInUse > 0);
	ix = key & 0xFF;
	if (swa_bitarray_read(level0->inUse, ix) == 0) return False;
	*valP = level0->words[ix];
	return True;
	}


	Bool VG_(addToSWA) ( SparseWA* swa, UWord key, UWord val )
	{
	Int i;
	UWord ix;
	Level0* level0;
	LevelN* levelN;
	Bool already_present;
	const Int _3_or_7 = sizeof(void*) - 1;

	vg_assert(swa);

	if (!swa->root)
	swa->root = swa_new_LevelN(swa, _3_or_7);
	levelN = swa->root;

	/* levels 3/7 .. 2 */
	for (i = _3_or_7; i >= 2; i--) {
	/* levelN is the level-i map */
	vg_assert(levelN);
	vg_assert(levelN->level == i);
	ix = (key >> (i*8)) & 0xFF;
	if (levelN->child[ix] == NULL) {
	levelN->child[ix] = swa_new_LevelN(swa, i-1);
	levelN->nInUse++;
	}
	vg_assert(levelN->nInUse >= 1 && levelN->nInUse <= 256);
	levelN = levelN->child[ix];
	}

	/* levelN is the level-1 map */
	vg_assert(levelN);
	vg_assert(levelN->level == 1);
	ix = (key >> (1*8)) & 0xFF;
	if (levelN->child[ix] == NULL) {
	levelN->child[ix] = swa_new_Level0(swa);
	levelN->nInUse++;
	}
	vg_assert(levelN->nInUse >= 1 && levelN->nInUse <= 256);
	level0 = levelN->child[ix];

	/* level0 is the level-0 map */
	vg_assert(level0);
	vg_assert(level0->magic == Level0_MAGIC);
	ix = key & 0xFF;
	if (swa_bitarray_read_then_set(level0->inUse, ix) == 0) {
	level0->nInUse++;
	already_present = False;
	} else {
	already_present = True;
	}
	vg_assert(level0->nInUse >= 1 && level0->nInUse <= 256);
	level0->words[ix] = val;

	return already_present;
	}


	Bool VG_(delFromSWA) ( SparseWA* swa,
	/OUT/UWord* oldV, UWord key )
	{
	Int i;
	UWord ix;
	Level0* level0;
	LevelN* levelN;
	const Int _3_or_7 = sizeof(void*) - 1;

	LevelN* visited[_3_or_7];
	UWord visitedIx[_3_or_7];
	Int nVisited = 0;

	vg_assert(swa);
	levelN = swa->root;

	/* levels 3/7 .. 1 */
	for (i = _3_or_7; i >= 1; i--) {
	/* level i */
	if (!levelN) return False;
	vg_assert(levelN->level == i);
	vg_assert(levelN->nInUse > 0);
	ix = (key >> (i*8)) & 0xFF;
	visited[nVisited] = levelN;
	visitedIx[nVisited++] = ix;
	levelN = levelN->child[ix];
	}

	/* level 0 */
	level0 = (Level0*)levelN;
	if (!level0) return False;
	vg_assert(level0->magic == Level0_MAGIC);
	vg_assert(level0->nInUse > 0);
	ix = key & 0xFF;

	if (swa_bitarray_read_then_clear(level0->inUse, ix) == 0)
	return False;

	*oldV = level0->words[ix];

	level0->nInUse--;
	if (level0->nInUse > 0)
	return True;

	vg_assert(nVisited == _3_or_7);
	swa->dealloc( level0 );

	/* levels 1 .. 3/7 */
	for (i = 1; i <= _3_or_7; i++) {
	/* level i */
	nVisited--;
	vg_assert(visited[nVisited]->child[ visitedIx[nVisited] ]);
	visited[nVisited]->child[ visitedIx[nVisited] ] = NULL;
	visited[nVisited]->nInUse--;
	vg_assert(visited[nVisited]->nInUse >= 0);
	if (visited[nVisited]->nInUse > 0)
	return True;
	swa->dealloc(visited[nVisited]);
	}

	vg_assert(nVisited == 0);
	swa->root = NULL;
	return True;
	}


	static UWord swa_sizeSWA_wrk ( const void* nd )
	{
	Int i;
	if ((const UWord)nd == LevelN_MAGIC) {
	UWord sum = 0;
	const LevelN* levelN = nd;
	for (i = 0; i < 256; i++) {
	if (levelN->child[i]) {
	sum += swa_sizeSWA_wrk( levelN->child[i] );
	}
	}
	return sum;
	} else {
	const Level0* level0;
	vg_assert((const UWord)nd == Level0_MAGIC);
	level0 = nd;
	return level0->nInUse;
	}
	}
	UWord VG_(sizeSWA) ( const SparseWA* swa )
	{
	if (swa->root)
	return swa_sizeSWA_wrk ( swa->root );
	else
	return 0;
	}



	/--------------------------------------------------------------------/
	/--- end m_sparsewa.c ---/
	/--------------------------------------------------------------------/