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/**
@file
@ingroup mtr
@brief Functions to support group specification for reordering.
@see cudd package
@author Fabio Somenzi
@copyright@parblock
Copyright (c) 1995-2015, Regents of the University of Colorado
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
Neither the name of the University of Colorado nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
@endparblock
*/
#include "util.h"
#include "mtrInt.h"
/*---------------------------------------------------------------------------*/
/* Constant declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Stucture declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Type declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Variable declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Macro declarations */
/*---------------------------------------------------------------------------*/
/** \cond */
/*---------------------------------------------------------------------------*/
/* Static function prototypes */
/*---------------------------------------------------------------------------*/
static int mtrShiftHL (MtrNode *node, int shift);
/** \endcond */
/*---------------------------------------------------------------------------*/
/* Definition of exported functions */
/*---------------------------------------------------------------------------*/
/**
@brief Allocate new tree.
@details Allocate new tree with one node, whose low and size
fields are specified by the lower and size parameters.
@return pointer to tree root.
@sideeffect None
@see Mtr_InitTree Mtr_FreeTree
*/
MtrNode *
Mtr_InitGroupTree(
int lower,
int size)
{
MtrNode *root;
root = Mtr_InitTree();
if (root == NULL) return(NULL);
root->flags = MTR_DEFAULT;
root->low = lower;
root->size = size;
return(root);
} /* end of Mtr_InitGroupTree */
/**
@brief Makes a new group with size leaves starting at low.
@details If the new group intersects an existing group, it must
either contain it or be contained by it. This procedure relies on
the low and size fields of each node. It also assumes that the
children of each node are sorted in order of increasing low. In
case of a valid request, the flags of the new group are set to the
value passed in `flags.'
@return the pointer to the root of the new group upon successful
termination; NULL otherwise. If the group already exists, the
pointer to its root is returned.
@sideeffect None
@see Mtr_DissolveGroup Mtr_ReadGroups Mtr_FindGroup
*/
MtrNode *
Mtr_MakeGroup(
MtrNode * root /**< root of the group tree */,
unsigned int low /**< lower bound of the group */,
unsigned int size /**< size of the group */,
unsigned int flags /**< flags for the new group */)
{
MtrNode *node,
*first,
*last,
*previous,
*newn;
/* Sanity check. */
if (size == 0)
return(NULL);
/* Check whether current group includes new group. This check is
** necessary at the top-level call. In the subsequent calls it is
** redundant. */
if (low < (unsigned int) root->low ||
low + size > (unsigned int) (root->low + root->size))
return(NULL);
/* At this point we know that the new group is contained
** in the group of root. We have two possible cases here:
** - root is a terminal node;
** - root has children. */
/* Root has no children: create a new group. */
if (root->child == NULL) {
newn = Mtr_AllocNode();
if (newn == NULL) return(NULL); /* out of memory */
newn->low = low;
newn->size = size;
newn->flags = flags;
newn->parent = root;
newn->elder = newn->younger = newn->child = NULL;
root->child = newn;
return(newn);
}
/* Root has children: Find all children of root that are included
** in the new group. If the group of any child entirely contains
** the new group, call Mtr_MakeGroup recursively. */
previous = NULL;
first = root->child; /* guaranteed to be non-NULL */
while (first != NULL && low >= (unsigned int) (first->low + first->size)) {
previous = first;
first = first->younger;
}
if (first == NULL) {
/* We have scanned the entire list and we need to append a new
** child at the end of it. Previous points to the last child
** of root. */
newn = Mtr_AllocNode();
if (newn == NULL) return(NULL); /* out of memory */
newn->low = low;
newn->size = size;
newn->flags = flags;
newn->parent = root;
newn->elder = previous;
previous->younger = newn;
newn->younger = newn->child = NULL;
return(newn);
}
/* Here first is non-NULL and low < first->low + first->size. */
if (low >= (unsigned int) first->low &&
low + size <= (unsigned int) (first->low + first->size)) {
/* The new group is contained in the group of first. */
newn = Mtr_MakeGroup(first, low, size, flags);
return(newn);
} else if (low + size <= first->low) {
/* The new group is entirely contained in the gap between
** previous and first. */
newn = Mtr_AllocNode();
if (newn == NULL) return(NULL); /* out of memory */
newn->low = low;
newn->size = size;
newn->flags = flags;
newn->child = NULL;
newn->parent = root;
newn->elder = previous;
newn->younger = first;
first->elder = newn;
if (previous != NULL) {
previous->younger = newn;
} else {
root->child = newn;
}
return(newn);
} else if (low < (unsigned int) first->low &&
low + size < (unsigned int) (first->low + first->size)) {
/* Trying to cut an existing group: not allowed. */
return(NULL);
} else if (low > first->low) {
/* The new group neither is contained in the group of first
** (this was tested above) nor contains it. It is therefore
** trying to cut an existing group: not allowed. */
return(NULL);
}
/* First holds the pointer to the first child contained in the new
** group. Here low <= first->low and low + size >= first->low +
** first->size. One of the two inequalities is strict. */
last = first;
while (last->younger != NULL &&
(unsigned int) (last->younger->low + last->younger->size) <= low + size) {
last = last->younger;
}
if (last == NULL) {
/* All the chilren of root from first onward become children
** of the new group. */
newn = Mtr_AllocNode();
if (newn == NULL) return(NULL); /* out of memory */
newn->low = low;
newn->size = size;
newn->flags = flags;
newn->child = first;
newn->parent = root;
newn->elder = previous;
newn->younger = NULL;
first->elder = NULL;
if (previous != NULL) {
previous->younger = newn;
} else {
root->child = newn;
}
last = first;
while (last != NULL) {
last->parent = newn;
last = last->younger;
}
return(newn);
}
/* Here last != NULL and low + size <= last->low + last->size. */
if (low + size - 1 >= (unsigned int) last->low &&
low + size < (unsigned int) (last->low + last->size)) {
/* Trying to cut an existing group: not allowed. */
return(NULL);
}
/* First and last point to the first and last of the children of
** root that are included in the new group. Allocate a new node
** and make all children of root between first and last chidren of
** the new node. Previous points to the child of root immediately
** preceeding first. If it is NULL, then first is the first child
** of root. */
newn = Mtr_AllocNode();
if (newn == NULL) return(NULL); /* out of memory */
newn->low = low;
newn->size = size;
newn->flags = flags;
newn->child = first;
newn->parent = root;
if (previous == NULL) {
root->child = newn;
} else {
previous->younger = newn;
}
newn->elder = previous;
newn->younger = last->younger;
if (last->younger != NULL) {
last->younger->elder = newn;
}
last->younger = NULL;
first->elder = NULL;
for (node = first; node != NULL; node = node->younger) {
node->parent = newn;
}
return(newn);
} /* end of Mtr_MakeGroup */
/**
@brief Merges the children of `group' with the children of its
parent.
@details Disposes of the node pointed by group. If group is the root
of the group tree, this procedure leaves the tree unchanged.
@return the pointer to the parent of `group' upon successful
termination; NULL otherwise.
@sideeffect None
@see Mtr_MakeGroup
*/
MtrNode *
Mtr_DissolveGroup(
MtrNode * group /**< group to be dissolved */)
{
MtrNode *parent;
MtrNode *last;
parent = group->parent;
if (parent == NULL) return(NULL);
if (MTR_TEST(group,MTR_TERMINAL) || group->child == NULL) return(NULL);
/* Make all children of group children of its parent, and make
** last point to the last child of group. */
for (last = group->child; last->younger != NULL; last = last->younger) {
last->parent = parent;
}
last->parent = parent;
last->younger = group->younger;
if (group->younger != NULL) {
group->younger->elder = last;
}
group->child->elder = group->elder;
if (group == parent->child) {
parent->child = group->child;
} else {
group->elder->younger = group->child;
}
Mtr_DeallocNode(group);
return(parent);
} /* end of Mtr_DissolveGroup */
/**
@brief Finds a group with size leaves starting at low, if it exists.
@details This procedure relies on the low and size fields of each
node. It also assumes that the children of each node are sorted in
order of increasing low.
@return the pointer to the root of the group upon successful
termination; NULL otherwise.
@sideeffect None
*/
MtrNode *
Mtr_FindGroup(
MtrNode * root /**< root of the group tree */,
unsigned int low /**< lower bound of the group */,
unsigned int size /**< upper bound of the group */)
{
MtrNode *node;
#ifdef MTR_DEBUG
/* We cannot have a non-empty proper subgroup of a singleton set. */
assert(!MTR_TEST(root,MTR_TERMINAL));
#endif
/* Sanity check. */
if (size < 1) return(NULL);
/* Check whether current group includes the group sought. This
** check is necessary at the top-level call. In the subsequent
** calls it is redundant. */
if (low < (unsigned int) root->low ||
low + size > (unsigned int) (root->low + root->size))
return(NULL);
if (root->size == size && root->low == low)
return(root);
if (root->child == NULL)
return(NULL);
/* Find all chidren of root that are included in the new group. If
** the group of any child entirely contains the new group, call
** Mtr_MakeGroup recursively. */
node = root->child;
while (low >= (unsigned int) (node->low + node->size)) {
node = node->younger;
}
if (low + size <= (unsigned int) (node->low + node->size)) {
/* The group is contained in the group of node. */
node = Mtr_FindGroup(node, low, size);
return(node);
} else {
return(NULL);
}
} /* end of Mtr_FindGroup */
/**
@brief Swaps two children of a tree node.
@details Adjusts the high and low fields of the two nodes and their
descendants. The two children must be adjacent. However, first may
be the younger sibling of second.
@return 1 in case of success; 0 otherwise.
@sideeffect None
*/
int
Mtr_SwapGroups(
MtrNode * first /**< first node to be swapped */,
MtrNode * second /**< second node to be swapped */)
{
MtrNode *node;
MtrNode *parent;
int sizeFirst;
int sizeSecond;
if (second->younger == first) { /* make first first */
node = first;
first = second;
second = node;
} else if (first->younger != second) { /* non-adjacent */
return(0);
}
sizeFirst = first->size;
sizeSecond = second->size;
/* Swap the two nodes. */
parent = first->parent;
if (parent == NULL || second->parent != parent) return(0);
if (parent->child == first) {
parent->child = second;
} else { /* first->elder != NULL */
first->elder->younger = second;
}
if (second->younger != NULL) {
second->younger->elder = first;
}
first->younger = second->younger;
second->elder = first->elder;
first->elder = second;
second->younger = first;
/* Adjust the high and low fields. */
if (!mtrShiftHL(first,sizeSecond)) return(0);
if (!mtrShiftHL(second,-sizeFirst)) return(0);
return(1);
} /* end of Mtr_SwapGroups */
/**
@brief Fix variable tree at the end of tree sifting.
@details Fix the levels in the variable tree sorting siblings
according to them. It should be called on a non-NULL tree. It then
maintains this invariant. It applies insertion sorting to the list of
siblings The order is determined by permutation, which is used to find
the new level of the node index. Index must refer to the first variable
in the group.
@sideeffect The tree is modified.
*/
void
Mtr_ReorderGroups(
MtrNode *treenode,
int *permutation)
{
MtrNode *auxnode;
/* Initialize sorted list to first element. */
MtrNode *sorted = treenode;
sorted->low = permutation[sorted->index];
if (sorted->child != NULL)
Mtr_ReorderGroups(sorted->child, permutation);
auxnode = treenode->younger;
while (auxnode != NULL) {
MtrNode *rightplace;
MtrNode *moving = auxnode;
auxnode->low = permutation[auxnode->index];
if (auxnode->child != NULL)
Mtr_ReorderGroups(auxnode->child, permutation);
rightplace = auxnode->elder;
/* Find insertion point. */
while (rightplace != NULL && auxnode->low < rightplace->low)
rightplace = rightplace->elder;
auxnode = auxnode->younger;
if (auxnode != NULL) {
auxnode->elder = moving->elder;
auxnode->elder->younger = auxnode;
} else {
moving->elder->younger = NULL;
}
if (rightplace == NULL) { /* Move to head of sorted list. */
sorted->elder = moving;
moving->elder = NULL;
moving->younger = sorted;
sorted = moving;
} else { /* Splice. */
moving->elder = rightplace;
moving->younger = rightplace->younger;
if (rightplace->younger != NULL)
rightplace->younger->elder = moving;
rightplace->younger = moving;
}
}
/* Fix parent. */
if (sorted->parent != NULL)
sorted->parent->child = sorted;
} /* end of Mtr_ReorderGroups */
/**
@brief Prints the groups as a parenthesized list.
@details After each group, the group's flag are printed, preceded by a `|'.
For each flag (except MTR_TERMINAL) a character is printed.
<ul>
<li>F: MTR_FIXED
<li>N: MTR_NEWNODE
<li>S: MTR_SOFT
</ul>
The second argument, silent, if different from 0, causes
Mtr_PrintGroups to only check the syntax of the group tree.
@sideeffect None
@see Mtr_PrintTree
*/
void
Mtr_PrintGroups(
MtrNode const * root /**< root of the group tree */,
int silent /**< flag to check tree syntax only */)
{
MtrNode *node;
assert(root != NULL);
assert(root->younger == NULL || root->younger->elder == root);
assert(root->elder == NULL || root->elder->younger == root);
#if SIZEOF_VOID_P == 8
if (!silent) (void) printf("(%u",root->low);
#else
if (!silent) (void) printf("(%hu",root->low);
#endif
if (MTR_TEST(root,MTR_TERMINAL) || root->child == NULL) {
if (!silent) (void) printf(",");
} else {
node = root->child;
while (node != NULL) {
assert(node->low >= root->low && (int) (node->low + node->size) <= (int) (root->low + root->size));
assert(node->parent == root);
Mtr_PrintGroups(node,silent);
node = node->younger;
}
}
if (!silent) {
#if SIZEOF_VOID_P == 8
(void) printf("%u", (MtrHalfWord) (root->low + root->size - 1));
#else
(void) printf("%hu", (MtrHalfWord) (root->low + root->size - 1));
#endif
if (root->flags != MTR_DEFAULT) {
(void) printf("|");
if (MTR_TEST(root,MTR_FIXED)) (void) printf("F");
if (MTR_TEST(root,MTR_NEWNODE)) (void) printf("N");
if (MTR_TEST(root,MTR_SOFT)) (void) printf("S");
}
(void) printf(")");
if (root->parent == NULL) (void) printf("\n");
}
assert((root->flags &~(MTR_TERMINAL | MTR_SOFT | MTR_FIXED | MTR_NEWNODE)) == 0);
return;
} /* end of Mtr_PrintGroups */
/**
@brief Prints the variable order as a parenthesized list.
@details After each group, the group's flag are printed, preceded by a `|'.
For each flag (except MTR_TERMINAL) a character is printed.
<ul>
<li>F: MTR_FIXED
<li>N: MTR_NEWNODE
<li>S: MTR_SOFT
</ul>
The second argument, gives the map from levels to variable indices.
@return 1 if successful; 0 otherwise.
@sideeffect None
@see Mtr_PrintGroups
*/
int
Mtr_PrintGroupedOrder(
MtrNode const * root /**< root of the group tree */,
int const *invperm /**< map from levels to indices */,
FILE *fp /**< output file */)
{
MtrNode *child;
MtrHalfWord level;
int retval;
assert(root != NULL);
assert(root->younger == NULL || root->younger->elder == root);
assert(root->elder == NULL || root->elder->younger == root);
retval = fprintf(fp,"(");
if (retval == EOF) return(0);
level = root->low;
child = root->child;
while (child != NULL) {
assert(child->low >= root->low && (child->low + child->size) <= (root->low + root->size));
assert(child->parent == root);
while (level < child->low) {
retval = fprintf(fp,"%d%s", invperm[level], (level < root->low + root->size - 1) ? "," : "");
if (retval == EOF) return(0);
level++;
}
retval = Mtr_PrintGroupedOrder(child,invperm,fp);
if (retval == 0) return(0);
level += child->size;
if (level < root->low + root->size - 1) {
retval = fprintf(fp,",");
if (retval == EOF) return(0);
}
child = child->younger;
}
while (level < root->low + root->size) {
retval = fprintf(fp,"%d%s", invperm[level], (level < root->low + root->size - 1) ? "," : "");
if (retval == EOF) return(0);
level++;
}
if (root->flags != MTR_DEFAULT) {
retval = fprintf(fp,"|");
if (retval == EOF) return(0);
if (MTR_TEST(root,MTR_FIXED)) {
retval = fprintf(fp,"F");
if (retval == EOF) return(0);
}
if (MTR_TEST(root,MTR_NEWNODE)) {
retval = fprintf(fp,"N");
if (retval == EOF) return(0);
}
if (MTR_TEST(root,MTR_SOFT)) {
retval = fprintf(fp,"S");
if (retval == EOF) return(0);
}
}
retval = fprintf(fp,")");
if (retval == EOF) return(0);
if (root->parent == NULL) {
retval = fprintf(fp,"\n");
if (retval == EOF) return(0);
}
assert((root->flags &~(MTR_SOFT | MTR_FIXED | MTR_NEWNODE)) == 0);
return(1);
} /* end of Mtr_PrintGroupedOrder */
/**
@brief Reads groups from a file and creates a group tree.
@details Each group is specified by three fields:
low size flags.
Low and size are (short) integers. Flags is a string composed of the
following characters (with associated translation):
<ul>
<li>D: MTR_DEFAULT
<li>F: MTR_FIXED
<li>N: MTR_NEWNODE
<li>S: MTR_SOFT
<li>T: MTR_TERMINAL
</ul>
Normally, the only flags that are needed are D and F. Groups and
fields are separated by white space (spaces, tabs, and newlines).
@return a pointer to the group tree if successful; NULL otherwise.
@sideeffect None
@see Mtr_InitGroupTree Mtr_MakeGroup
*/
MtrNode *
Mtr_ReadGroups(
FILE * fp /**< file pointer */,
int nleaves /**< number of leaves of the new tree */)
{
int low;
int size;
int err;
unsigned int flags;
MtrNode *root;
MtrNode *node;
char attrib[8*sizeof(unsigned int)+1];
char *c;
root = Mtr_InitGroupTree(0,nleaves);
if (root == NULL) return NULL;
while (! feof(fp)) {
/* Read a triple and check for consistency. */
err = fscanf(fp, "%d %d %s", &low, &size, attrib);
if (err == EOF) {
break;
} else if (err != 3) {
Mtr_FreeTree(root);
return(NULL);
} else if (low < 0 || low+size > nleaves || size < 1) {
Mtr_FreeTree(root);
return(NULL);
} else if (strlen(attrib) > 8 * sizeof(MtrHalfWord)) {
/* Not enough bits in the flags word to store these many
** attributes. */
Mtr_FreeTree(root);
return(NULL);
}
/* Parse the flag string. Currently all flags are permitted,
** to make debugging easier. Normally, specifying NEWNODE
** wouldn't be allowed. */
flags = MTR_DEFAULT;
for (c=attrib; *c != 0; c++) {
switch (*c) {
case 'D':
break;
case 'F':
flags |= MTR_FIXED;
break;
case 'N':
flags |= MTR_NEWNODE;
break;
case 'S':
flags |= MTR_SOFT;
break;
case 'T':
flags |= MTR_TERMINAL;
break;
default:
return NULL;
}
}
node = Mtr_MakeGroup(root, (MtrHalfWord) low, (MtrHalfWord) size,
flags);
if (node == NULL) {
Mtr_FreeTree(root);
return(NULL);
}
}
return(root);
} /* end of Mtr_ReadGroups */
/*---------------------------------------------------------------------------*/
/* Definition of internal functions */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Definition of static functions */
/*---------------------------------------------------------------------------*/
/**
@brief Adjusts the low fields of a node and its descendants.
@details Adds shift to low of each node. Checks that no
out-of-bounds values result.
@return 1 in case of success; 0 otherwise.
@sideeffect None
*/
static int
mtrShiftHL(
MtrNode * node /**< group tree node */,
int shift /**< amount by which low should be changed */)
{
MtrNode *auxnode;
int low;
low = (int) node->low;
low += shift;
if (low < 0 || low + (int) (node->size - 1) > (int) MTR_MAXHIGH) return(0);
node->low = (MtrHalfWord) low;
if (!MTR_TEST(node,MTR_TERMINAL) && node->child != NULL) {
auxnode = node->child;
do {
if (!mtrShiftHL(auxnode,shift)) return(0);
auxnode = auxnode->younger;
} while (auxnode != NULL);
}
return(1);
} /* end of mtrShiftHL */