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/**
@file
@ingroup cudd
@brief Utility functions for ZDDs.
@author Hyong-Kyoon Shin, In-Ho Moon, 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 "cuddInt.h"
/*---------------------------------------------------------------------------*/
/* Constant declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Stucture declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Type declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Variable declarations */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Macro declarations */
/*---------------------------------------------------------------------------*/
/** \cond */
/*---------------------------------------------------------------------------*/
/* Static function prototypes */
/*---------------------------------------------------------------------------*/
static int zp2 (DdManager *zdd, DdNode *f, st_table *t);
static void zdd_print_minterm_aux (DdManager *zdd, DdNode *node, int level, int *list);
static void zddPrintCoverAux (DdManager *zdd, DdNode *node, int level, int *list);
static void zddSupportStep(DdNode * f, int * support);
static void zddClearFlag(DdNode * f);
/** \endcond */
/*---------------------------------------------------------------------------*/
/* Definition of exported functions */
/*---------------------------------------------------------------------------*/
/**
@brief Prints a disjoint sum of product form for a %ZDD.
@return 1 if successful; 0 otherwise.
@sideeffect None
@see Cudd_zddPrintDebug Cudd_zddPrintCover
*/
int
Cudd_zddPrintMinterm(
DdManager * zdd,
DdNode * node)
{
int i, size;
int *list;
size = (int)zdd->sizeZ;
list = ALLOC(int, size);
if (list == NULL) {
zdd->errorCode = CUDD_MEMORY_OUT;
return(0);
}
for (i = 0; i < size; i++) list[i] = 3; /* bogus value should disappear */
zdd_print_minterm_aux(zdd, node, 0, list);
FREE(list);
return(1);
} /* end of Cudd_zddPrintMinterm */
/**
@brief Prints a sum of products from a %ZDD representing a cover.
@return 1 if successful; 0 otherwise.
@sideeffect None
@see Cudd_zddPrintMinterm
*/
int
Cudd_zddPrintCover(
DdManager * zdd,
DdNode * node)
{
int i, size;
int *list;
size = (int)zdd->sizeZ;
if (size % 2 != 0) return(0); /* number of variables should be even */
list = ALLOC(int, size);
if (list == NULL) {
zdd->errorCode = CUDD_MEMORY_OUT;
return(0);
}
for (i = 0; i < size; i++) list[i] = 3; /* bogus value should disappear */
zddPrintCoverAux(zdd, node, 0, list);
FREE(list);
return(1);
} /* end of Cudd_zddPrintCover */
/**
@brief Prints to the standard output a %ZDD and its statistics.
@details The statistics include the number of nodes and the number of
minterms. (The number of minterms is also the number of combinations
in the set.) The statistics are printed if pr &gt; 0. Specifically:
<ul>
<li> pr = 0 : prints nothing
<li> pr = 1 : prints counts of nodes and minterms
<li> pr = 2 : prints counts + disjoint sum of products
<li> pr = 3 : prints counts + list of nodes
<li> pr &gt; 3 : prints counts + disjoint sum of products + list of nodes
</ul>
@return 1 if successful; 0 otherwise.
@sideeffect None
*/
int
Cudd_zddPrintDebug(
DdManager * zdd,
DdNode * f,
int n,
int pr)
{
DdNode *empty = DD_ZERO(zdd);
int nodes;
double minterms;
int retval = 1;
if (f == empty && pr > 0) {
(void) fprintf(zdd->out,": is the empty ZDD\n");
(void) fflush(zdd->out);
return(1);
}
if (pr > 0) {
nodes = Cudd_zddDagSize(f);
if (nodes == CUDD_OUT_OF_MEM) retval = 0;
minterms = Cudd_zddCountMinterm(zdd, f, n);
if (minterms == (double)CUDD_OUT_OF_MEM) retval = 0;
(void) fprintf(zdd->out,": %d nodes %g minterms\n",
nodes, minterms);
if (pr > 2)
if (!cuddZddP(zdd, f)) retval = 0;
if (pr == 2 || pr > 3) {
if (!Cudd_zddPrintMinterm(zdd, f)) retval = 0;
(void) fprintf(zdd->out,"\n");
}
(void) fflush(zdd->out);
}
return(retval);
} /* end of Cudd_zddPrintDebug */
/**
@brief Finds the first path of a %ZDD.
@details Defines an iterator on the paths of a %ZDD and finds its first
path.<p>
A path is represented as an array of literals, which are integers in
{0, 1, 2}; 0 represents an else arc out of a node, 1 represents a then arc
out of a node, and 2 stands for the absence of a node.
The size of the array equals the number of variables in the manager at
the time Cudd_zddFirstCube is called.<p>
The paths that end in the empty terminal are not enumerated.
@return a generator that contains the information necessary to
continue the enumeration if successful; NULL otherwise.
@sideeffect The first path is returned as a side effect.
@see Cudd_zddForeachPath Cudd_zddNextPath Cudd_GenFree
Cudd_IsGenEmpty
*/
DdGen *
Cudd_zddFirstPath(
DdManager * zdd,
DdNode * f,
int ** path)
{
DdGen *gen;
DdNode *top, *next, *prev;
int i;
int nvars;
/* Sanity Check. */
if (zdd == NULL || f == NULL) return(NULL);
/* Allocate generator an initialize it. */
gen = ALLOC(DdGen,1);
if (gen == NULL) {
zdd->errorCode = CUDD_MEMORY_OUT;
return(NULL);
}
gen->manager = zdd;
gen->type = CUDD_GEN_ZDD_PATHS;
gen->status = CUDD_GEN_EMPTY;
gen->gen.cubes.cube = NULL;
gen->gen.cubes.value = DD_ZERO_VAL;
gen->stack.sp = 0;
gen->stack.stack = NULL;
gen->node = NULL;
nvars = zdd->sizeZ;
gen->gen.cubes.cube = ALLOC(int,nvars);
if (gen->gen.cubes.cube == NULL) {
zdd->errorCode = CUDD_MEMORY_OUT;
FREE(gen);
return(NULL);
}
for (i = 0; i < nvars; i++) gen->gen.cubes.cube[i] = 2;
/* The maximum stack depth is one plus the number of variables.
** because a path may have nodes at all levels, including the
** constant level.
*/
gen->stack.stack = ALLOC(DdNodePtr, nvars+1);
if (gen->stack.stack == NULL) {
zdd->errorCode = CUDD_MEMORY_OUT;
FREE(gen->gen.cubes.cube);
FREE(gen);
return(NULL);
}
for (i = 0; i <= nvars; i++) gen->stack.stack[i] = NULL;
/* Find the first path of the ZDD. */
gen->stack.stack[gen->stack.sp] = f; gen->stack.sp++;
while (1) {
top = gen->stack.stack[gen->stack.sp-1];
if (!cuddIsConstant(Cudd_Regular(top))) {
/* Take the else branch first. */
gen->gen.cubes.cube[Cudd_Regular(top)->index] = 0;
next = cuddE(Cudd_Regular(top));
gen->stack.stack[gen->stack.sp] = Cudd_Not(next); gen->stack.sp++;
} else if (Cudd_Regular(top) == DD_ZERO(zdd)) {
/* Backtrack. */
while (1) {
if (gen->stack.sp == 1) {
/* The current node has no predecessor. */
gen->status = CUDD_GEN_EMPTY;
gen->stack.sp--;
goto done;
}
prev = Cudd_Regular(gen->stack.stack[gen->stack.sp-2]);
next = cuddT(prev);
if (next != top) { /* follow the then branch next */
gen->gen.cubes.cube[prev->index] = 1;
gen->stack.stack[gen->stack.sp-1] = next;
break;
}
/* Pop the stack and try again. */
gen->gen.cubes.cube[prev->index] = 2;
gen->stack.sp--;
top = gen->stack.stack[gen->stack.sp-1];
}
} else {
gen->status = CUDD_GEN_NONEMPTY;
gen->gen.cubes.value = cuddV(Cudd_Regular(top));
goto done;
}
}
done:
*path = gen->gen.cubes.cube;
return(gen);
} /* end of Cudd_zddFirstPath */
/**
@brief Generates the next path of a %ZDD.
@details Generates the next path of a %ZDD onset, using generator
gen.
@return 0 if the enumeration is completed; 1 otherwise.
@sideeffect The path is returned as a side effect. The generator is
modified.
@see Cudd_zddForeachPath Cudd_zddFirstPath Cudd_GenFree
Cudd_IsGenEmpty
*/
int
Cudd_zddNextPath(
DdGen * gen,
int ** path)
{
DdNode *top, *next, *prev;
DdManager *zdd = gen->manager;
/* Backtrack from previously reached terminal node. */
while (1) {
if (gen->stack.sp == 1) {
/* The current node has no predecessor. */
gen->status = CUDD_GEN_EMPTY;
gen->stack.sp--;
goto done;
}
top = gen->stack.stack[gen->stack.sp-1];
prev = Cudd_Regular(gen->stack.stack[gen->stack.sp-2]);
next = cuddT(prev);
if (next != top) { /* follow the then branch next */
gen->gen.cubes.cube[prev->index] = 1;
gen->stack.stack[gen->stack.sp-1] = next;
break;
}
/* Pop the stack and try again. */
gen->gen.cubes.cube[prev->index] = 2;
gen->stack.sp--;
}
while (1) {
top = gen->stack.stack[gen->stack.sp-1];
if (!cuddIsConstant(Cudd_Regular(top))) {
/* Take the else branch first. */
gen->gen.cubes.cube[Cudd_Regular(top)->index] = 0;
next = cuddE(Cudd_Regular(top));
gen->stack.stack[gen->stack.sp] = Cudd_Not(next); gen->stack.sp++;
} else if (Cudd_Regular(top) == DD_ZERO(zdd)) {
/* Backtrack. */
while (1) {
if (gen->stack.sp == 1) {
/* The current node has no predecessor. */
gen->status = CUDD_GEN_EMPTY;
gen->stack.sp--;
goto done;
}
prev = Cudd_Regular(gen->stack.stack[gen->stack.sp-2]);
next = cuddT(prev);
if (next != top) { /* follow the then branch next */
gen->gen.cubes.cube[prev->index] = 1;
gen->stack.stack[gen->stack.sp-1] = next;
break;
}
/* Pop the stack and try again. */
gen->gen.cubes.cube[prev->index] = 2;
gen->stack.sp--;
top = gen->stack.stack[gen->stack.sp-1];
}
} else {
gen->status = CUDD_GEN_NONEMPTY;
gen->gen.cubes.value = cuddV(Cudd_Regular(top));
goto done;
}
}
done:
if (gen->status == CUDD_GEN_EMPTY) return(0);
*path = gen->gen.cubes.cube;
return(1);
} /* end of Cudd_zddNextPath */
/**
@brief Converts a path of a %ZDD representing a cover to a string.
@details The string represents an implicant of the cover. The path
is typically produced by Cudd_zddForeachPath. If the str input is
NULL, it allocates a new string. The string passed to this function
must have enough room for all variables and for the terminator.
@return a pointer to the string if successful; NULL otherwise.
@sideeffect None
@see Cudd_zddForeachPath
*/
char *
Cudd_zddCoverPathToString(
DdManager *zdd /**< %DD manager */,
int *path /**< path of %ZDD representing a cover */,
char *str /**< pointer to string to use if != NULL */
)
{
int nvars = zdd->sizeZ;
int i;
char *res;
if (nvars & 1) return(NULL);
nvars >>= 1;
if (str == NULL) {
res = ALLOC(char, nvars+1);
if (res == NULL) return(NULL);
} else {
res = str;
}
for (i = 0; i < nvars; i++) {
int v = (path[2*i] << 2) | path[2*i+1];
switch (v) {
case 0:
case 2:
case 8:
case 10:
res[i] = '-';
break;
case 1:
case 9:
res[i] = '0';
break;
case 4:
case 6:
res[i] = '1';
break;
default:
res[i] = '?';
}
}
res[nvars] = 0;
return(res);
} /* end of Cudd_zddCoverPathToString */
/**
@brief Finds the variables on which a %ZDD depends.
@return a %BDD consisting of the product of the variables if
successful; NULL otherwise.
@sideeffect None
@see Cudd_Support
*/
DdNode *
Cudd_zddSupport(
DdManager * dd /**< manager */,
DdNode * f /**< %ZDD whose support is sought */)
{
int *support;
DdNode *res, *tmp, *var;
int i,j;
int size;
/* Allocate and initialize support array for ddSupportStep. */
size = ddMax(dd->size, dd->sizeZ);
support = ALLOC(int,size);
if (support == NULL) {
dd->errorCode = CUDD_MEMORY_OUT;
return(NULL);
}
for (i = 0; i < size; i++) {
support[i] = 0;
}
/* Compute support and clean up markers. */
zddSupportStep(Cudd_Regular(f),support);
zddClearFlag(Cudd_Regular(f));
/* Transform support from array to cube. */
do {
dd->reordered = 0;
res = DD_ONE(dd);
cuddRef(res);
for (j = size - 1; j >= 0; j--) { /* for each level bottom-up */
i = (j >= dd->size) ? j : dd->invperm[j];
if (support[i] == 1) {
/* The following call to cuddUniqueInter is guaranteed
** not to trigger reordering because the node we look up
** already exists. */
var = cuddUniqueInter(dd,i,dd->one,Cudd_Not(dd->one));
cuddRef(var);
tmp = cuddBddAndRecur(dd,res,var);
if (tmp == NULL) {
Cudd_RecursiveDeref(dd,res);
Cudd_RecursiveDeref(dd,var);
res = NULL;
break;
}
cuddRef(tmp);
Cudd_RecursiveDeref(dd,res);
Cudd_RecursiveDeref(dd,var);
res = tmp;
}
}
} while (dd->reordered == 1);
FREE(support);
if (res != NULL) cuddDeref(res);
if (dd->errorCode == CUDD_TIMEOUT_EXPIRED && dd->timeoutHandler) {
dd->timeoutHandler(dd, dd->tohArg);
}
return(res);
} /* end of Cudd_zddSupport */
/**
@brief Writes a dot file representing the argument ZDDs.
@details Writes a file representing the argument ZDDs in a format
suitable for the graph drawing program dot.
Cudd_zddDumpDot does not close the file: This is the caller
responsibility. Cudd_zddDumpDot uses a minimal unique subset of the
hexadecimal address of a node as name for it.
If the argument inames is non-null, it is assumed to hold the pointers
to the names of the inputs. Similarly for onames.
Cudd_zddDumpDot uses the following convention to draw arcs:
<ul>
<li> solid line: THEN arcs;
<li> dashed line: ELSE arcs.
</ul>
The dot options are chosen so that the drawing fits on a letter-size
sheet.
@return 1 in case of success; 0 otherwise (e.g., out-of-memory, file
system full).
@sideeffect None
@see Cudd_DumpDot Cudd_zddPrintDebug
*/
int
Cudd_zddDumpDot(
DdManager * dd /**< manager */,
int n /**< number of output nodes to be dumped */,
DdNode ** f /**< array of output nodes to be dumped */,
char const * const * inames /**< array of input names (or NULL) */,
char const * const * onames /**< array of output names (or NULL) */,
FILE * fp /**< pointer to the dump file */)
{
DdNode *support = NULL;
DdNode *scan;
int *sorted = NULL;
int nvars = dd->sizeZ;
st_table *visited = NULL;
st_generator *gen;
int retval;
int i, j;
int slots;
DdNodePtr *nodelist;
ptruint refAddr, diff, mask = 0;
/* Build a bit array with the support of f. */
sorted = ALLOC(int,nvars);
if (sorted == NULL) {
dd->errorCode = CUDD_MEMORY_OUT;
goto failure;
}
for (i = 0; i < nvars; i++) sorted[i] = 0;
/* Take the union of the supports of each output function. */
for (i = 0; i < n; i++) {
support = Cudd_zddSupport(dd,f[i]);
if (support == NULL) goto failure;
cuddRef(support);
scan = support;
while (!cuddIsConstant(scan)) {
sorted[scan->index] = 1;
scan = cuddT(scan);
}
Cudd_RecursiveDeref(dd,support);
}
support = NULL; /* so that we do not try to free it in case of failure */
/* Initialize symbol table for visited nodes. */
visited = st_init_table(st_ptrcmp, st_ptrhash);
if (visited == NULL) goto failure;
/* Collect all the nodes of this DD in the symbol table. */
for (i = 0; i < n; i++) {
retval = cuddCollectNodes(f[i],visited);
if (retval == 0) goto failure;
}
/* Find how many most significant hex digits are identical
** in the addresses of all the nodes. Build a mask based
** on this knowledge, so that digits that carry no information
** will not be printed. This is done in two steps.
** 1. We scan the symbol table to find the bits that differ
** in at least 2 addresses.
** 2. We choose one of the possible masks. There are 8 possible
** masks for 32-bit integer, and 16 possible masks for 64-bit
** integers.
*/
/* Find the bits that are different. */
refAddr = (ptruint) f[0];
diff = 0;
gen = st_init_gen(visited);
while (st_gen(gen, (void **) &scan, NULL)) {
diff |= refAddr ^ (ptruint) scan;
}
st_free_gen(gen);
/* Choose the mask. */
for (i = 0; (unsigned) i < 8 * sizeof(ptruint); i += 4) {
mask = ((ptruint) 1 << i) - 1;
if (diff <= mask) break;
}
/* Write the header and the global attributes. */
retval = fprintf(fp,"digraph \"ZDD\" {\n");
if (retval == EOF) return(0);
retval = fprintf(fp,
"size = \"7.5,10\"\ncenter = true;\nedge [dir = none];\n");
if (retval == EOF) return(0);
/* Write the input name subgraph by scanning the support array. */
retval = fprintf(fp,"{ node [shape = plaintext];\n");
if (retval == EOF) goto failure;
retval = fprintf(fp," edge [style = invis];\n");
if (retval == EOF) goto failure;
/* We use a name ("CONST NODES") with an embedded blank, because
** it is unlikely to appear as an input name.
*/
retval = fprintf(fp," \"CONST NODES\" [style = invis];\n");
if (retval == EOF) goto failure;
for (i = 0; i < nvars; i++) {
if (sorted[dd->invpermZ[i]]) {
if (inames == NULL) {
retval = fprintf(fp,"\" %d \" -> ", dd->invpermZ[i]);
} else {
retval = fprintf(fp,"\" %s \" -> ", inames[dd->invpermZ[i]]);
}
if (retval == EOF) goto failure;
}
}
retval = fprintf(fp,"\"CONST NODES\"; \n}\n");
if (retval == EOF) goto failure;
/* Write the output node subgraph. */
retval = fprintf(fp,"{ rank = same; node [shape = box]; edge [style = invis];\n");
if (retval == EOF) goto failure;
for (i = 0; i < n; i++) {
if (onames == NULL) {
retval = fprintf(fp,"\"F%d\"", i);
} else {
retval = fprintf(fp,"\" %s \"", onames[i]);
}
if (retval == EOF) goto failure;
if (i == n - 1) {
retval = fprintf(fp,"; }\n");
} else {
retval = fprintf(fp," -> ");
}
if (retval == EOF) goto failure;
}
/* Write rank info: All nodes with the same index have the same rank. */
for (i = 0; i < nvars; i++) {
if (sorted[dd->invpermZ[i]]) {
retval = fprintf(fp,"{ rank = same; ");
if (retval == EOF) goto failure;
if (inames == NULL) {
retval = fprintf(fp,"\" %d \";\n", dd->invpermZ[i]);
} else {
retval = fprintf(fp,"\" %s \";\n", inames[dd->invpermZ[i]]);
}
if (retval == EOF) goto failure;
nodelist = dd->subtableZ[i].nodelist;
slots = dd->subtableZ[i].slots;
for (j = 0; j < slots; j++) {
scan = nodelist[j];
while (scan != NULL) {
if (st_is_member(visited,scan)) {
retval = fprintf(fp,"\"%#" PRIxPTR "\";\n",
((mask & (ptruint) scan) /
sizeof(DdNode)));
if (retval == EOF) goto failure;
}
scan = scan->next;
}
}
retval = fprintf(fp,"}\n");
if (retval == EOF) goto failure;
}
}
/* All constants have the same rank. */
retval = fprintf(fp,
"{ rank = same; \"CONST NODES\";\n{ node [shape = box]; ");
if (retval == EOF) goto failure;
nodelist = dd->constants.nodelist;
slots = dd->constants.slots;
for (j = 0; j < slots; j++) {
scan = nodelist[j];
while (scan != NULL) {
if (st_is_member(visited,scan)) {
retval = fprintf(fp,"\"%#" PRIxPTR "\";\n",
((mask & (ptruint) scan) / sizeof(DdNode)));
if (retval == EOF) goto failure;
}
scan = scan->next;
}
}
retval = fprintf(fp,"}\n}\n");
if (retval == EOF) goto failure;
/* Write edge info. */
/* Edges from the output nodes. */
for (i = 0; i < n; i++) {
if (onames == NULL) {
retval = fprintf(fp,"\"F%d\"", i);
} else {
retval = fprintf(fp,"\" %s \"", onames[i]);
}
if (retval == EOF) goto failure;
retval = fprintf(fp," -> \"%#" PRIxPTR "\" [style = solid];\n",
((mask & (ptruint) f[i]) / sizeof(DdNode)));
if (retval == EOF) goto failure;
}
/* Edges from internal nodes. */
for (i = 0; i < nvars; i++) {
if (sorted[dd->invpermZ[i]]) {
nodelist = dd->subtableZ[i].nodelist;
slots = dd->subtableZ[i].slots;
for (j = 0; j < slots; j++) {
scan = nodelist[j];
while (scan != NULL) {
if (st_is_member(visited,scan)) {
retval = fprintf(fp,
"\"%#" PRIxPTR "\" -> \"%#" PRIxPTR "\";\n",
((mask & (ptruint) scan) / sizeof(DdNode)),
((mask & (ptruint) cuddT(scan)) / sizeof(DdNode)));
if (retval == EOF) goto failure;
retval = fprintf(fp,
"\"%#" PRIxPTR "\" -> \"%#" PRIxPTR
"\" [style = dashed];\n",
((mask & (ptruint) scan) /
sizeof(DdNode)),
((mask & (ptruint) cuddE(scan)) /
sizeof(DdNode)));
if (retval == EOF) goto failure;
}
scan = scan->next;
}
}
}
}
/* Write constant labels. */
nodelist = dd->constants.nodelist;
slots = dd->constants.slots;
for (j = 0; j < slots; j++) {
scan = nodelist[j];
while (scan != NULL) {
if (st_is_member(visited,scan)) {
retval = fprintf(fp,"\"%#" PRIxPTR "\" [label = \"%g\"];\n",
((mask & (ptruint) scan) / sizeof(DdNode)),
cuddV(scan));
if (retval == EOF) goto failure;
}
scan = scan->next;
}
}
/* Write trailer and return. */
retval = fprintf(fp,"}\n");
if (retval == EOF) goto failure;
st_free_table(visited);
FREE(sorted);
return(1);
failure:
if (sorted != NULL) FREE(sorted);
if (visited != NULL) st_free_table(visited);
return(0);
} /* end of Cudd_zddDumpBlif */
/*---------------------------------------------------------------------------*/
/* Definition of internal functions */
/*---------------------------------------------------------------------------*/
/**
@brief Prints a %ZDD to the standard output. One line per node is
printed.
@return 1 if successful; 0 otherwise.
@sideeffect None
@see Cudd_zddPrintDebug
*/
int
cuddZddP(
DdManager * zdd,
DdNode * f)
{
int retval;
st_table *table = st_init_table(st_ptrcmp, st_ptrhash);
if (table == NULL) return(0);
retval = zp2(zdd, f, table);
st_free_table(table);
(void) fputc('\n', zdd->out);
return(retval);
} /* end of cuddZddP */
/*---------------------------------------------------------------------------*/
/* Definition of static functions */
/*---------------------------------------------------------------------------*/
/**
@brief Performs the recursive step of cuddZddP.
@return 1 in case of success; 0 otherwise.
@sideeffect None
*/
static int
zp2(
DdManager * zdd,
DdNode * f,
st_table * t)
{
DdNode *n;
int T, E;
DdNode *base = DD_ONE(zdd);
if (f == NULL)
return(0);
if (Cudd_IsConstantInt(f)) {
(void)fprintf(zdd->out, "ID = %d\n", (f == base));
return(1);
}
if (st_is_member(t, f) == 1)
return(1);
if (st_insert(t, f, NULL) == ST_OUT_OF_MEM)
return(0);
(void) fprintf(zdd->out, "ID = 0x%" PRIxPTR "\tindex = %u\tr = %u\t",
(ptruint)f / (ptruint) sizeof(DdNode), f->index, f->ref);
n = cuddT(f);
if (Cudd_IsConstantInt(n)) {
(void) fprintf(zdd->out, "T = %d\t\t", (n == base));
T = 1;
} else {
(void) fprintf(zdd->out, "T = 0x%" PRIxPTR "\t", (ptruint) n /
(ptruint) sizeof(DdNode));
T = 0;
}
n = cuddE(f);
if (Cudd_IsConstantInt(n)) {
(void) fprintf(zdd->out, "E = %d\n", (n == base));
E = 1;
} else {
(void) fprintf(zdd->out, "E = 0x%" PRIxPTR "\n", (ptruint) n /
(ptruint) sizeof(DdNode));
E = 0;
}
if (E == 0)
if (zp2(zdd, cuddE(f), t) == 0) return(0);
if (T == 0)
if (zp2(zdd, cuddT(f), t) == 0) return(0);
return(1);
} /* end of zp2 */
/**
@brief Performs the recursive step of Cudd_zddPrintMinterm.
@sideeffect None
*/
static void
zdd_print_minterm_aux(
DdManager * zdd /* manager */,
DdNode * node /* current node */,
int level /* depth in the recursion */,
int * list /* current recursion path */)
{
DdNode *Nv, *Nnv;
int i, v;
DdNode *base = DD_ONE(zdd);
if (Cudd_IsConstantInt(node)) {
if (node == base) {
/* Check for missing variable. */
if (level != zdd->sizeZ) {
list[zdd->invpermZ[level]] = 0;
zdd_print_minterm_aux(zdd, node, level + 1, list);
return;
}
/* Terminal case: Print one cube based on the current recursion
** path.
*/
for (i = 0; i < zdd->sizeZ; i++) {
v = list[i];
if (v == 0)
(void) fprintf(zdd->out,"0");
else if (v == 1)
(void) fprintf(zdd->out,"1");
else if (v == 3)
(void) fprintf(zdd->out,"@"); /* should never happen */
else
(void) fprintf(zdd->out,"-");
}
(void) fprintf(zdd->out," 1\n");
}
} else {
/* Check for missing variable. */
if (level != cuddIZ(zdd,node->index)) {
list[zdd->invpermZ[level]] = 0;
zdd_print_minterm_aux(zdd, node, level + 1, list);
return;
}
Nnv = cuddE(node);
Nv = cuddT(node);
if (Nv == Nnv) {
list[node->index] = 2;
zdd_print_minterm_aux(zdd, Nnv, level + 1, list);
return;
}
list[node->index] = 1;
zdd_print_minterm_aux(zdd, Nv, level + 1, list);
list[node->index] = 0;
zdd_print_minterm_aux(zdd, Nnv, level + 1, list);
}
return;
} /* end of zdd_print_minterm_aux */
/**
@brief Performs the recursive step of Cudd_zddPrintCover.
@sideeffect None
*/
static void
zddPrintCoverAux(
DdManager * zdd /* manager */,
DdNode * node /* current node */,
int level /* depth in the recursion */,
int * list /* current recursion path */)
{
DdNode *Nv, *Nnv;
int i, v;
DdNode *base = DD_ONE(zdd);
if (Cudd_IsConstantInt(node)) {
if (node == base) {
/* Check for missing variable. */
if (level != zdd->sizeZ) {
list[zdd->invpermZ[level]] = 0;
zddPrintCoverAux(zdd, node, level + 1, list);
return;
}
/* Terminal case: Print one cube based on the current recursion
** path.
*/
for (i = 0; i < zdd->sizeZ; i += 2) {
v = list[i] * 4 + list[i+1];
if (v == 0)
(void) putc('-',zdd->out);
else if (v == 4)
(void) putc('1',zdd->out);
else if (v == 1)
(void) putc('0',zdd->out);
else
(void) putc('@',zdd->out); /* should never happen */
}
(void) fprintf(zdd->out," 1\n");
}
} else {
/* Check for missing variable. */
if (level != cuddIZ(zdd,node->index)) {
list[zdd->invpermZ[level]] = 0;
zddPrintCoverAux(zdd, node, level + 1, list);
return;
}
Nnv = cuddE(node);
Nv = cuddT(node);
if (Nv == Nnv) {
list[node->index] = 2;
zddPrintCoverAux(zdd, Nnv, level + 1, list);
return;
}
list[node->index] = 1;
zddPrintCoverAux(zdd, Nv, level + 1, list);
list[node->index] = 0;
zddPrintCoverAux(zdd, Nnv, level + 1, list);
}
return;
} /* end of zddPrintCoverAux */
/**
@brief Performs the recursive step of Cudd_zddSupport.
@details Performs a DFS from f. The support is accumulated in supp
as a side effect. Uses the LSB of the then pointer as visited flag.
@sideeffect None
@see zddClearFlag
*/
static void
zddSupportStep(
DdNode * f,
int * support)
{
if (cuddIsConstant(f) || Cudd_IsComplement(f->next)) {
return;
}
support[f->index] = 1;
zddSupportStep(cuddT(f),support);
zddSupportStep(Cudd_Regular(cuddE(f)),support);
/* Mark as visited. */
f->next = Cudd_Not(f->next);
return;
} /* end of zddSupportStep */
/**
@brief Performs a DFS from f, clearing the LSB of the next
pointers.
@sideeffect None
@see zddSupportStep
*/
static void
zddClearFlag(
DdNode * f)
{
if (!Cudd_IsComplement(f->next)) {
return;
}
/* Clear visited flag. */
f->next = Cudd_Regular(f->next);
if (cuddIsConstant(f)) {
return;
}
zddClearFlag(cuddT(f));
zddClearFlag(Cudd_Regular(cuddE(f)));
return;
} /* end of zddClearFlag */