Commit e8d690f2 by Alan Mishchenko

Adding command 'testdec'.

parent 1b185838
...@@ -4811,7 +4811,7 @@ usage: ...@@ -4811,7 +4811,7 @@ usage:
***********************************************************************/ ***********************************************************************/
int Abc_CommandTestDec( Abc_Frame_t * pAbc, int argc, char ** argv ) int Abc_CommandTestDec( Abc_Frame_t * pAbc, int argc, char ** argv )
{ {
extern int Abc_DecTest( char * pFileName, int DecType ); extern int Abc_DecTest( char * pFileName, int DecType, int fVerbose );
char * pFileName; char * pFileName;
int c; int c;
int fVerbose = 0; int fVerbose = 0;
...@@ -4849,17 +4849,17 @@ int Abc_CommandTestDec( Abc_Frame_t * pAbc, int argc, char ** argv ) ...@@ -4849,17 +4849,17 @@ int Abc_CommandTestDec( Abc_Frame_t * pAbc, int argc, char ** argv )
// get the output file name // get the output file name
pFileName = argv[globalUtilOptind]; pFileName = argv[globalUtilOptind];
// call the testbench // call the testbench
Abc_DecTest( pFileName, DecType ); Abc_DecTest( pFileName, DecType, fVerbose );
return 0; return 0;
usage: usage:
Abc_Print( -2, "usage: testdec [-A <num>] [-vh] <file_name>\n" ); Abc_Print( -2, "usage: testdec [-A <num>] [-vh] <file_name>\n" );
Abc_Print( -2, "\t testbench for Boolean decomposition algorithms\n" ); Abc_Print( -2, "\t testbench for Boolean decomposition algorithms\n" );
Abc_Print( -2, "\t-A <num> : number of decomposition algorithm [default = %d]\n", DecType ); Abc_Print( -2, "\t-A <num> : decomposition algorithm [default = %d]\n", DecType );
Abc_Print( -2, "\t 0 : none (just read the input file)\n" ); Abc_Print( -2, "\t 0: none (reading and writing the file)\n" );
Abc_Print( -2, "\t 1 : algebraic factoring applied to ISOP\n" ); Abc_Print( -2, "\t 1: algebraic factoring applied to ISOP\n" );
Abc_Print( -2, "\t 2 : bi-decomposition with cofactoring\n" ); Abc_Print( -2, "\t 2: bi-decomposition with cofactoring\n" );
Abc_Print( -2, "\t 3 : disjoint-support decomposition\n" ); Abc_Print( -2, "\t 3: disjoint-support decomposition with cofactoring\n" );
Abc_Print( -2, "\t-v : toggle verbose printout [default = %s]\n", fVerbose? "yes": "no" ); Abc_Print( -2, "\t-v : toggle verbose printout [default = %s]\n", fVerbose? "yes": "no" );
Abc_Print( -2, "\t-h : print the command usage\n"); Abc_Print( -2, "\t-h : print the command usage\n");
return 1; return 1;
......
...@@ -18,7 +18,12 @@ ...@@ -18,7 +18,12 @@
***********************************************************************/ ***********************************************************************/
#include "base/abc/abc.h" #include "misc/extra/extra.h"
#include "misc/vec/vec.h"
#include "bool/bdc/bdc.h"
#include "bool/dec/dec.h"
#include "bool/kit/kit.h"
ABC_NAMESPACE_IMPL_START ABC_NAMESPACE_IMPL_START
...@@ -33,10 +38,460 @@ ABC_NAMESPACE_IMPL_START ...@@ -33,10 +38,460 @@ ABC_NAMESPACE_IMPL_START
// 2 - bi-decomposition // 2 - bi-decomposition
// 3 - DSD // 3 - DSD
// data-structure to store a bunch of truth tables
typedef struct Abc_TtStore_t_ Abc_TtStore_t;
struct Abc_TtStore_t_
{
int nVars;
int nwords;
int nFuncs;
word ** pFuncs;
};
// read/write/flip i-th bit of a bit string table:
static inline int Abc_TruthGetBit( word * p, int i ) { return (int)(p[i>>6] >> (i & 63)) & 1; }
static inline void Abc_TruthSetBit( word * p, int i ) { p[i>>6] |= (((word)1)<<(i & 63)); }
static inline void Abc_TruthXorBit( word * p, int i ) { p[i>>6] ^= (((word)1)<<(i & 63)); }
// read/write k-th digit d of a hexadecimal number:
static inline int Abc_TruthGetHex( word * p, int k ) { return (int)(p[k>>4] >> ((k<<2) & 63)) & 15; }
static inline void Abc_TruthSetHex( word * p, int k, int d ) { p[k>>4] |= (((word)d)<<((k<<2) & 63)); }
static inline void Abc_TruthXorHex( word * p, int k, int d ) { p[k>>4] ^= (((word)d)<<((k<<2) & 63)); }
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS /// /// FUNCTION DEFINITIONS ///
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
// read one hex character
static inline int Abc_TruthReadHexDigit( char HexChar )
{
if ( HexChar >= '0' && HexChar <= '9' )
return HexChar - '0';
if ( HexChar >= 'A' && HexChar <= 'F' )
return HexChar - 'A' + 10;
if ( HexChar >= 'a' && HexChar <= 'f' )
return HexChar - 'a' + 10;
assert( 0 ); // not a hexadecimal symbol
return -1; // return value which makes no sense
}
// write one hex character
static inline void Abc_TruthWriteHexDigit( FILE * pFile, int HexDigit )
{
assert( HexDigit >= 0 && HexDigit < 16 );
if ( HexDigit < 10 )
fprintf( pFile, "%d", HexDigit );
else
fprintf( pFile, "%c", 'A' + HexDigit-10 );
}
// read one truth table in hexadecimal
void Abc_TruthReadHex( word * pTruth, char * pString, int nVars )
{
int nwords = (nVars < 7)? 1 : (1 << (nVars-6));
int k, Digit, nDigits = (nwords << 4);
char EndSymbol;
// skip the first 2 symbols if they are "0x"
if ( pString[0] == '0' && pString[1] == 'x' )
pString += 2;
// get the last symbol
EndSymbol = pString[nDigits];
// the end symbol of the TT (the one immediately following hex digits)
// should be one of the following: space, a new-line, or a zero-terminator
// (note that on Windows symbols '\r' can be inserted before each '\n')
assert( EndSymbol == ' ' || EndSymbol == '\n' || EndSymbol == '\r' || EndSymbol == '\0' );
// read hexadecimal digits in the reverse order
// (the last symbol in the string is the least significant digit)
for ( k = 0; k < nDigits; k++ )
{
Digit = Abc_TruthReadHexDigit( pString[nDigits - 1 - k] );
assert( Digit >= 0 && Digit < 16 );
Abc_TruthSetHex( pTruth, k, Digit );
}
}
// write one truth table in hexadecimal (do not add end-of-line!)
void Abc_TruthWriteHex( FILE * pFile, word * pTruth, int nVars )
{
int nDigits, Digit, k;
// write hexadecimal digits in the reverse order
// (the last symbol in the string is the least significant digit)
nDigits = (1 << (nVars-2));
for ( k = 0; k < nDigits; k++ )
{
Digit = Abc_TruthGetHex( pTruth, nDigits - 1 - k );
assert( Digit >= 0 && Digit < 16 );
Abc_TruthWriteHexDigit( pFile, Digit );
}
}
/**Function*************************************************************
Synopsis [Allocate/Deallocate storage for truth tables..]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Abc_TtStore_t * Abc_TruthStoreAlloc( int nVars, int nFuncs )
{
Abc_TtStore_t * p;
int i;
p = (Abc_TtStore_t *)malloc( sizeof(Abc_TtStore_t) );
p->nVars = nVars;
p->nwords = (nVars < 7) ? 1 : (1 << (nVars-6));
p->nFuncs = nFuncs;
// alloc array of 'nFuncs' pointers to truth tables
p->pFuncs = (word **)malloc( sizeof(word *) * p->nFuncs );
// alloc storage for 'nFuncs' truth tables as one chunk of memory
p->pFuncs[0] = (word *)calloc( sizeof(word), p->nFuncs * p->nwords );
// split it up into individual truth tables
for ( i = 1; i < p->nFuncs; i++ )
p->pFuncs[i] = p->pFuncs[i-1] + p->nwords;
return p;
}
void Abc_TruthStoreFree( Abc_TtStore_t * p )
{
free( p->pFuncs[0] );
free( p->pFuncs );
free( p );
}
/**Function*************************************************************
Synopsis [Read file contents.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
char * Abc_FileRead( char * pFileName )
{
FILE * pFile;
char * pBuffer;
int nFileSize;
pFile = fopen( pFileName, "rb" );
if ( pFile == NULL )
{
printf( "Cannot open file \"%s\" for reading.\n", pFileName );
return NULL;
}
// get the file size, in bytes
fseek( pFile, 0, SEEK_END );
nFileSize = ftell( pFile );
// move the file current reading position to the beginning
rewind( pFile );
// load the contents of the file into memory
pBuffer = (char *)malloc( nFileSize + 3 );
fread( pBuffer, nFileSize, 1, pFile );
// add several empty lines at the end
// (these will be used to signal the end of parsing)
pBuffer[ nFileSize + 0] = '\n';
pBuffer[ nFileSize + 1] = '\n';
// terminate the string with '\0'
pBuffer[ nFileSize + 2] = '\0';
fclose( pFile );
return pBuffer;
}
/**Function*************************************************************
Synopsis [Determine the number of variables by reading the first line.]
Description [Determine the number of functions by counting the lines.]
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_TruthGetParams( char * pFileName, int * pnVars, int * pnTruths )
{
char * pContents;
int i, nVars, nLines;
// prepare the output
if ( pnVars )
*pnVars = 0;
if ( pnTruths )
*pnTruths = 0;
// read data from file
pContents = Abc_FileRead( pFileName );
if ( pContents == NULL )
return;
// count the number of symbols before the first space or new-line
// (note that on Windows symbols '\r' can be inserted before each '\n')
for ( i = 0; pContents[i]; i++ )
if ( pContents[i] == ' ' || pContents[i] == '\n' || pContents[i] == '\r' )
break;
if ( pContents[i] == 0 )
printf( "Strange, the input file does not have spaces and new-lines...\n" );
// acount for the fact that truth tables may have "0x" at the beginning of each line
if ( pContents[0] == '0' && pContents[1] == 'x' )
i = i - 2;
// determine the number of variables
for ( nVars = 0; nVars < 32; nVars++ )
if ( 4 * i == (1 << nVars) ) // the number of bits equal to the size of truth table
break;
if ( nVars < 2 || nVars > 16 )
{
printf( "Does not look like the input file contains truth tables...\n" );
return;
}
if ( pnVars )
*pnVars = nVars;
// determine the number of functions by counting the lines
nLines = 0;
for ( i = 0; pContents[i]; i++ )
nLines += (pContents[i] == '\n');
if ( pnTruths )
*pnTruths = nLines;
ABC_FREE( pContents );
}
/**Function*************************************************************
Synopsis [Read truth tables from file.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_TruthStoreRead( char * pFileName, Abc_TtStore_t * p )
{
char * pContents;
int i, nLines;
pContents = Abc_FileRead( pFileName );
if ( pContents == NULL )
return;
// here it is assumed (without checking!) that each line of the file
// begins with a string of hexadecimal chars followed by space
// the file will be read till the first empty line (pContents[i] == '\n')
// (note that Abc_FileRead() added several empty lines at the end of the file contents)
for ( nLines = i = 0; pContents[i] != '\n'; )
{
// read one line
Abc_TruthReadHex( p->pFuncs[nLines++], &pContents[i], p->nVars );
// skip till after the end-of-line symbol
// (note that end-of-line symbol is also skipped)
while ( pContents[i++] != '\n' );
}
// adjust the number of functions read
// (we may have allocated more storage because some lines in the file were empty)
assert( p->nFuncs >= nLines );
p->nFuncs = nLines;
ABC_FREE( pContents );
}
/**Function*************************************************************
Synopsis [Write truth tables into file.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_TruthStoreWrite( char * pFileName, Abc_TtStore_t * p )
{
FILE * pFile;
int i;
pFile = fopen( pFileName, "wb" );
if ( pFile == NULL )
{
printf( "Cannot open file \"%s\" for writing.\n", pFileName );
return;
}
for ( i = 0; i < p->nFuncs; i++ )
{
Abc_TruthWriteHex( pFile, p->pFuncs[i], p->nVars );
fprintf( pFile, "\n" );
}
fclose( pFile );
}
/**Function*************************************************************
Synopsis [Read truth tables from input file and write them into output file.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_TruthStoreTest( char * pFileName )
{
Abc_TtStore_t * p;
char * pFileInput = pFileName;
char * pFileOutput = "out.txt";
int nVars, nTruths;
// figure out how many truth table and how many variables
Abc_TruthGetParams( pFileInput, &nVars, &nTruths );
if ( nVars < 2 || nVars > 16 || nTruths == 0 )
return;
// allocate data-structure
p = Abc_TruthStoreAlloc( nVars, nTruths );
// read info from file
Abc_TruthStoreRead( pFileInput, p );
// write into another file
Abc_TruthStoreWrite( pFileOutput, p );
// delete data-structure
Abc_TruthStoreFree( p );
printf( "Input file \"%s\" was copied into output file \"%s\".\n", pFileInput, pFileOutput );
}
/**Function*************************************************************
Synopsis [Apply decomposition to the truth table.]
Description [Returns the number of AIG nodes.]
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_TruthDecPerform( Abc_TtStore_t * p, int DecType, int fVerbose )
{
clock_t clk = clock();
int i, nNodes = 0;
char * pAlgoName = NULL;
if ( DecType == 1 )
pAlgoName = "factoring";
else if ( DecType == 2 )
pAlgoName = "bi-decomp";
else if ( DecType == 3 )
pAlgoName = "DSD";
if ( pAlgoName )
printf( "Applying %-10s to %8d func%s of %2d vars... ",
pAlgoName, p->nFuncs, (p->nFuncs == 1 ? "":"s"), p->nVars );
if ( fVerbose )
printf( "\n" );
if ( DecType == 1 )
{
// perform algebraic factoring and count AIG nodes
Dec_Graph_t * pFForm;
Vec_Int_t * vCover;
Vec_Str_t * vStr;
char * pSopStr;
vStr = Vec_StrAlloc( 10000 );
vCover = Vec_IntAlloc( 1 << 16 );
for ( i = 0; i < p->nFuncs; i++ )
{
if ( fVerbose )
printf( "%7d : ", i );
pSopStr = Kit_PlaFromTruthNew( (unsigned *)p->pFuncs[i], p->nVars, vCover, vStr );
pFForm = Dec_Factor( pSopStr );
nNodes += Dec_GraphNodeNum( pFForm );
if ( fVerbose )
Dec_GraphPrint( stdout, pFForm, NULL, NULL );
Dec_GraphFree( pFForm );
}
Vec_IntFree( vCover );
Vec_StrFree( vStr );
}
else if ( DecType == 2 )
{
// perform bi-decomposition and count AIG nodes
Bdc_Man_t * pManDec;
Bdc_Par_t Pars = {0}, * pPars = &Pars;
pPars->nVarsMax = p->nVars;
pManDec = Bdc_ManAlloc( pPars );
for ( i = 0; i < p->nFuncs; i++ )
{
if ( fVerbose )
printf( "%7d : ", i );
Bdc_ManDecompose( pManDec, (unsigned *)p->pFuncs[i], NULL, p->nVars, NULL, 1000 );
nNodes += Bdc_ManAndNum( pManDec );
if ( fVerbose )
Bdc_ManDecPrint( pManDec );
}
Bdc_ManFree( pManDec );
}
else if ( DecType == 3 )
{
// perform disjoint-support decomposition and count AIG nodes
// (non-DSD blocks are decomposed into 2:1 MUXes, each counting as 3 AIG nodes)
Kit_DsdNtk_t * pNtk;
for ( i = 0; i < p->nFuncs; i++ )
{
if ( fVerbose )
printf( "%7d : ", i );
pNtk = Kit_DsdDecomposeMux( (unsigned *)p->pFuncs[i], p->nVars, 3 );
if ( fVerbose )
Kit_DsdPrintExpanded( pNtk ), printf( "\n" );
nNodes += Kit_DsdCountAigNodes( pNtk );
Kit_DsdNtkFree( pNtk );
}
}
else assert( 0 );
printf( "AIG nodes =%9d ", nNodes );
Abc_PrintTime( 1, "Time", clock() - clk );
}
/**Function*************************************************************
Synopsis [Apply decomposition to truth tables.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_TruthDecTest( char * pFileName, int DecType, int fVerbose )
{
Abc_TtStore_t * p;
int nVars, nTruths;
// figure out how many truth tables and how many variables
Abc_TruthGetParams( pFileName, &nVars, &nTruths );
if ( nVars < 2 || nVars > 16 || nTruths == 0 )
return;
// allocate data-structure
p = Abc_TruthStoreAlloc( nVars, nTruths );
// read info from file
Abc_TruthStoreRead( pFileName, p );
// consider functions from the file
Abc_TruthDecPerform( p, DecType, fVerbose );
// delete data-structure
Abc_TruthStoreFree( p );
// printf( "Finished decomposing truth tables from file \"%s\".\n", pFileName );
}
/**Function************************************************************* /**Function*************************************************************
...@@ -49,14 +504,20 @@ ABC_NAMESPACE_IMPL_START ...@@ -49,14 +504,20 @@ ABC_NAMESPACE_IMPL_START
SeeAlso [] SeeAlso []
***********************************************************************/ ***********************************************************************/
int Abc_DecTest( char * pFileName, int DecType ) int Abc_DecTest( char * pFileName, int DecType, int fVerbose )
{ {
printf( "Trying to read file \"%s\".\n", pFileName ); if ( fVerbose )
printf( "Using truth tables from file \"%s\"...\n", pFileName );
if ( DecType == 0 )
Abc_TruthStoreTest( pFileName );
else if ( DecType >= 1 && DecType <= 3 )
Abc_TruthDecTest( pFileName, DecType, fVerbose );
else
printf( "Unknown decomposition type value (%d).\n", DecType );
fflush( stdout ); fflush( stdout );
return 0; return 0;
} }
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
/// END OF FILE /// /// END OF FILE ///
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
......
...@@ -67,10 +67,12 @@ static inline Bdc_Fun_t * Bdc_NotCond( Bdc_Fun_t * p, int c ) { return (Bdc_F ...@@ -67,10 +67,12 @@ static inline Bdc_Fun_t * Bdc_NotCond( Bdc_Fun_t * p, int c ) { return (Bdc_F
/*=== bdcCore.c ==========================================================*/ /*=== bdcCore.c ==========================================================*/
extern Bdc_Man_t * Bdc_ManAlloc( Bdc_Par_t * pPars ); extern Bdc_Man_t * Bdc_ManAlloc( Bdc_Par_t * pPars );
extern void Bdc_ManFree( Bdc_Man_t * p ); extern void Bdc_ManFree( Bdc_Man_t * p );
extern void Bdc_ManDecPrint( Bdc_Man_t * p );
extern int Bdc_ManDecompose( Bdc_Man_t * p, unsigned * puFunc, unsigned * puCare, int nVars, Vec_Ptr_t * vDivs, int nNodesMax ); extern int Bdc_ManDecompose( Bdc_Man_t * p, unsigned * puFunc, unsigned * puCare, int nVars, Vec_Ptr_t * vDivs, int nNodesMax );
extern Bdc_Fun_t * Bdc_ManFunc( Bdc_Man_t * p, int i ); extern Bdc_Fun_t * Bdc_ManFunc( Bdc_Man_t * p, int i );
extern Bdc_Fun_t * Bdc_ManRoot( Bdc_Man_t * p ); extern Bdc_Fun_t * Bdc_ManRoot( Bdc_Man_t * p );
extern int Bdc_ManNodeNum( Bdc_Man_t * p ); extern int Bdc_ManNodeNum( Bdc_Man_t * p );
extern int Bdc_ManAndNum( Bdc_Man_t * p );
extern Bdc_Fun_t * Bdc_FuncFanin0( Bdc_Fun_t * p ); extern Bdc_Fun_t * Bdc_FuncFanin0( Bdc_Fun_t * p );
extern Bdc_Fun_t * Bdc_FuncFanin1( Bdc_Fun_t * p ); extern Bdc_Fun_t * Bdc_FuncFanin1( Bdc_Fun_t * p );
extern void * Bdc_FuncCopy( Bdc_Fun_t * p ); extern void * Bdc_FuncCopy( Bdc_Fun_t * p );
......
...@@ -46,6 +46,7 @@ ABC_NAMESPACE_IMPL_START ...@@ -46,6 +46,7 @@ ABC_NAMESPACE_IMPL_START
Bdc_Fun_t * Bdc_ManFunc( Bdc_Man_t * p, int i ) { return Bdc_FunWithId(p, i); } Bdc_Fun_t * Bdc_ManFunc( Bdc_Man_t * p, int i ) { return Bdc_FunWithId(p, i); }
Bdc_Fun_t * Bdc_ManRoot( Bdc_Man_t * p ) { return p->pRoot; } Bdc_Fun_t * Bdc_ManRoot( Bdc_Man_t * p ) { return p->pRoot; }
int Bdc_ManNodeNum( Bdc_Man_t * p ) { return p->nNodes; } int Bdc_ManNodeNum( Bdc_Man_t * p ) { return p->nNodes; }
int Bdc_ManAndNum( Bdc_Man_t * p ) { return p->nNodes-p->nVars-1;}
Bdc_Fun_t * Bdc_FuncFanin0( Bdc_Fun_t * p ) { return p->pFan0; } Bdc_Fun_t * Bdc_FuncFanin0( Bdc_Fun_t * p ) { return p->pFan0; }
Bdc_Fun_t * Bdc_FuncFanin1( Bdc_Fun_t * p ) { return p->pFan1; } Bdc_Fun_t * Bdc_FuncFanin1( Bdc_Fun_t * p ) { return p->pFan1; }
void * Bdc_FuncCopy( Bdc_Fun_t * p ) { return p->pCopy; } void * Bdc_FuncCopy( Bdc_Fun_t * p ) { return p->pCopy; }
...@@ -186,7 +187,7 @@ void Bdc_ManPrepare( Bdc_Man_t * p, Vec_Ptr_t * vDivs ) ...@@ -186,7 +187,7 @@ void Bdc_ManPrepare( Bdc_Man_t * p, Vec_Ptr_t * vDivs )
/**Function************************************************************* /**Function*************************************************************
Synopsis [Clears the manager.] Synopsis [Prints bi-decomposition in a simple format.]
Description [] Description []
...@@ -195,7 +196,7 @@ void Bdc_ManPrepare( Bdc_Man_t * p, Vec_Ptr_t * vDivs ) ...@@ -195,7 +196,7 @@ void Bdc_ManPrepare( Bdc_Man_t * p, Vec_Ptr_t * vDivs )
SeeAlso [] SeeAlso []
***********************************************************************/ ***********************************************************************/
void Bdc_ManDecPrint( Bdc_Man_t * p ) void Bdc_ManDecPrintSimple( Bdc_Man_t * p )
{ {
Bdc_Fun_t * pNode; Bdc_Fun_t * pNode;
int i; int i;
...@@ -211,7 +212,7 @@ void Bdc_ManDecPrint( Bdc_Man_t * p ) ...@@ -211,7 +212,7 @@ void Bdc_ManDecPrint( Bdc_Man_t * p )
printf( "%s%d &", Bdc_IsComplement(pNode->pFan0)? "-":"", Bdc_FunId(p,Bdc_Regular(pNode->pFan0)) ); printf( "%s%d &", Bdc_IsComplement(pNode->pFan0)? "-":"", Bdc_FunId(p,Bdc_Regular(pNode->pFan0)) );
printf( " %s%d ", Bdc_IsComplement(pNode->pFan1)? "-":"", Bdc_FunId(p,Bdc_Regular(pNode->pFan1)) ); printf( " %s%d ", Bdc_IsComplement(pNode->pFan1)? "-":"", Bdc_FunId(p,Bdc_Regular(pNode->pFan1)) );
} }
Extra_PrintBinary( stdout, pNode->puFunc, (1<<p->nVars) ); // Extra_PrintBinary( stdout, pNode->puFunc, (1<<p->nVars) );
printf( "\n" ); printf( "\n" );
} }
printf( "Root = %s%d.\n", Bdc_IsComplement(p->pRoot)? "-":"", Bdc_FunId(p,Bdc_Regular(p->pRoot)) ); printf( "Root = %s%d.\n", Bdc_IsComplement(p->pRoot)? "-":"", Bdc_FunId(p,Bdc_Regular(p->pRoot)) );
...@@ -219,6 +220,65 @@ void Bdc_ManDecPrint( Bdc_Man_t * p ) ...@@ -219,6 +220,65 @@ void Bdc_ManDecPrint( Bdc_Man_t * p )
/**Function************************************************************* /**Function*************************************************************
Synopsis [Prints bi-decomposition recursively.]
Description [This procedure prints bi-decomposition as a factored form.
In doing so, logic sharing, if present, will be replicated several times.]
SideEffects []
SeeAlso []
***********************************************************************/
void Bdc_ManDecPrint_rec( Bdc_Man_t * p, Bdc_Fun_t * pNode )
{
if ( pNode->Type == BDC_TYPE_PI )
printf( "%c", 'a' + Bdc_FunId(p,pNode) - 1 );
else if ( pNode->Type == BDC_TYPE_AND )
{
Bdc_Fun_t * pNode0 = Bdc_FuncFanin0( pNode );
Bdc_Fun_t * pNode1 = Bdc_FuncFanin1( pNode );
if ( Bdc_IsComplement(pNode0) )
printf( "!" );
if ( Bdc_IsComplement(pNode0) && Bdc_Regular(pNode0)->Type != BDC_TYPE_PI )
printf( "(" );
Bdc_ManDecPrint_rec( p, Bdc_Regular(pNode0) );
if ( Bdc_IsComplement(pNode0) && Bdc_Regular(pNode0)->Type != BDC_TYPE_PI )
printf( ")" );
if ( Bdc_IsComplement(pNode1) )
printf( "!" );
if ( Bdc_IsComplement(pNode1) && Bdc_Regular(pNode1)->Type != BDC_TYPE_PI )
printf( "(" );
Bdc_ManDecPrint_rec( p, Bdc_Regular(pNode1) );
if ( Bdc_IsComplement(pNode1) && Bdc_Regular(pNode1)->Type != BDC_TYPE_PI )
printf( ")" );
}
else assert( 0 );
}
void Bdc_ManDecPrint( Bdc_Man_t * p )
{
Bdc_Fun_t * pRoot = Bdc_Regular(p->pRoot);
printf( "F = " );
if ( pRoot->Type == BDC_TYPE_CONST1 ) // constant 0
printf( "Constant %d", !Bdc_IsComplement(p->pRoot) );
else if ( pRoot->Type == BDC_TYPE_PI ) // literal
printf( "%s%d", Bdc_IsComplement(p->pRoot) ? "!" : "", Bdc_FunId(p,pRoot)-1 );
else
{
if ( Bdc_IsComplement(p->pRoot) )
printf( "!(" );
Bdc_ManDecPrint_rec( p, pRoot );
if ( Bdc_IsComplement(p->pRoot) )
printf( ")" );
}
printf( "\n" );
}
/**Function*************************************************************
Synopsis [Performs decomposition of one function.] Synopsis [Performs decomposition of one function.]
Description [] Description []
......
...@@ -112,17 +112,17 @@ struct Kit_DsdObj_t_ ...@@ -112,17 +112,17 @@ struct Kit_DsdObj_t_
unsigned Offset : 8; // offset to the truth table unsigned Offset : 8; // offset to the truth table
unsigned nRefs : 8; // offset to the truth table unsigned nRefs : 8; // offset to the truth table
unsigned nFans : 6; // the number of fanins of this node unsigned nFans : 6; // the number of fanins of this node
unsigned char pFans[0]; // the fanin literals unsigned short pFans[0]; // the fanin literals
}; };
// DSD network // DSD network
typedef struct Kit_DsdNtk_t_ Kit_DsdNtk_t; typedef struct Kit_DsdNtk_t_ Kit_DsdNtk_t;
struct Kit_DsdNtk_t_ struct Kit_DsdNtk_t_
{ {
unsigned char nVars; // at most 16 (perhaps 18?) unsigned short nVars; // at most 16 (perhaps 18?)
unsigned char nNodesAlloc; // the number of allocated nodes (at most nVars) unsigned short nNodesAlloc; // the number of allocated nodes (at most nVars)
unsigned char nNodes; // the number of nodes unsigned short nNodes; // the number of nodes
unsigned char Root; // the root of the tree unsigned short Root; // the root of the tree
unsigned * pMem; // memory for the truth tables (memory manager?) unsigned * pMem; // memory for the truth tables (memory manager?)
unsigned * pSupps; // supports of the nodes unsigned * pSupps; // supports of the nodes
Kit_DsdObj_t** pNodes; // the nodes Kit_DsdObj_t** pNodes; // the nodes
...@@ -142,7 +142,7 @@ struct Kit_DsdMan_t_ ...@@ -142,7 +142,7 @@ struct Kit_DsdMan_t_
Vec_Int_t * vNodes; // temporary array for BDD nodes Vec_Int_t * vNodes; // temporary array for BDD nodes
}; };
static inline unsigned Kit_DsdObjOffset( int nFans ) { return (nFans >> 2) + ((nFans & 3) > 0); } static inline unsigned Kit_DsdObjOffset( int nFans ) { return (nFans >> 1) + ((nFans & 1) > 0); }
static inline unsigned * Kit_DsdObjTruth( Kit_DsdObj_t * pObj ) { return pObj->Type == KIT_DSD_PRIME ? (unsigned *)pObj->pFans + pObj->Offset: NULL; } static inline unsigned * Kit_DsdObjTruth( Kit_DsdObj_t * pObj ) { return pObj->Type == KIT_DSD_PRIME ? (unsigned *)pObj->pFans + pObj->Offset: NULL; }
static inline int Kit_DsdNtkObjNum( Kit_DsdNtk_t * pNtk ){ return pNtk->nVars + pNtk->nNodes; } static inline int Kit_DsdNtkObjNum( Kit_DsdNtk_t * pNtk ){ return pNtk->nVars + pNtk->nNodes; }
static inline Kit_DsdObj_t * Kit_DsdNtkObj( Kit_DsdNtk_t * pNtk, int Id ) { assert( Id >= 0 && Id < pNtk->nVars + pNtk->nNodes ); return Id < pNtk->nVars ? NULL : pNtk->pNodes[Id - pNtk->nVars]; } static inline Kit_DsdObj_t * Kit_DsdNtkObj( Kit_DsdNtk_t * pNtk, int Id ) { assert( Id >= 0 && Id < pNtk->nVars + pNtk->nNodes ); return Id < pNtk->nVars ? NULL : pNtk->pNodes[Id - pNtk->nVars]; }
...@@ -538,6 +538,7 @@ extern void Kit_DsdNtkFree( Kit_DsdNtk_t * pNtk ); ...@@ -538,6 +538,7 @@ extern void Kit_DsdNtkFree( Kit_DsdNtk_t * pNtk );
extern int Kit_DsdNonDsdSizeMax( Kit_DsdNtk_t * pNtk ); extern int Kit_DsdNonDsdSizeMax( Kit_DsdNtk_t * pNtk );
extern Kit_DsdObj_t * Kit_DsdNonDsdPrimeMax( Kit_DsdNtk_t * pNtk ); extern Kit_DsdObj_t * Kit_DsdNonDsdPrimeMax( Kit_DsdNtk_t * pNtk );
extern unsigned Kit_DsdNonDsdSupports( Kit_DsdNtk_t * pNtk ); extern unsigned Kit_DsdNonDsdSupports( Kit_DsdNtk_t * pNtk );
extern int Kit_DsdCountAigNodes( Kit_DsdNtk_t * pNtk );
extern unsigned Kit_DsdGetSupports( Kit_DsdNtk_t * p ); extern unsigned Kit_DsdGetSupports( Kit_DsdNtk_t * p );
extern Kit_DsdNtk_t * Kit_DsdExpand( Kit_DsdNtk_t * p ); extern Kit_DsdNtk_t * Kit_DsdExpand( Kit_DsdNtk_t * p );
extern Kit_DsdNtk_t * Kit_DsdShrink( Kit_DsdNtk_t * p, int pPrios[] ); extern Kit_DsdNtk_t * Kit_DsdShrink( Kit_DsdNtk_t * p, int pPrios[] );
......
...@@ -1485,7 +1485,7 @@ Kit_DsdNtk_t * Kit_DsdExpand( Kit_DsdNtk_t * p ) ...@@ -1485,7 +1485,7 @@ Kit_DsdNtk_t * Kit_DsdExpand( Kit_DsdNtk_t * p )
SeeAlso [] SeeAlso []
***********************************************************************/ ***********************************************************************/
void Kit_DsdCompSort( int pPrios[], unsigned uSupps[], unsigned char * piLits, int nVars, unsigned piLitsRes[] ) void Kit_DsdCompSort( int pPrios[], unsigned uSupps[], unsigned short * piLits, int nVars, unsigned piLitsRes[] )
{ {
int nSuppSizes[16], Priority[16], pOrder[16]; int nSuppSizes[16], Priority[16], pOrder[16];
int i, k, iVarBest, SuppMax, PrioMax; int i, k, iVarBest, SuppMax, PrioMax;
...@@ -1827,6 +1827,90 @@ int Kit_DsdFindLargeBox( Kit_DsdNtk_t * pNtk, int Size ) ...@@ -1827,6 +1827,90 @@ int Kit_DsdFindLargeBox( Kit_DsdNtk_t * pNtk, int Size )
/**Function************************************************************* /**Function*************************************************************
Synopsis [Returns 1 if there is a component with more than 3 inputs.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Kit_DsdCountAigNodes_rec( Kit_DsdNtk_t * pNtk, int Id )
{
Kit_DsdObj_t * pObj;
unsigned iLit, i, RetValue;
pObj = Kit_DsdNtkObj( pNtk, Id );
if ( pObj == NULL )
return 0;
if ( pObj->Type == KIT_DSD_CONST1 || pObj->Type == KIT_DSD_VAR )
return 0;
if ( pObj->nFans < 2 ) // why this happens? - need to figure out
return 0;
assert( pObj->nFans > 1 );
if ( pObj->Type == KIT_DSD_AND )
RetValue = ((int)pObj->nFans - 1);
else if ( pObj->Type == KIT_DSD_XOR )
RetValue = ((int)pObj->nFans - 1) * 3;
else if ( pObj->Type == KIT_DSD_PRIME )
{
// assuming MUX decomposition
assert( (int)pObj->nFans == 3 );
RetValue = 3;
}
else assert( 0 );
Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i )
RetValue += Kit_DsdCountAigNodes_rec( pNtk, Abc_Lit2Var(iLit) );
return RetValue;
}
/**Function*************************************************************
Synopsis [Returns 1 if there is a component with more than 3 inputs.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Kit_DsdCountAigNodes2( Kit_DsdNtk_t * pNtk )
{
return Kit_DsdCountAigNodes_rec( pNtk, Abc_Lit2Var(pNtk->Root) );
}
/**Function*************************************************************
Synopsis [Returns 1 if there is a component with more than 3 inputs.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Kit_DsdCountAigNodes( Kit_DsdNtk_t * pNtk )
{
Kit_DsdObj_t * pObj;
int i, Counter = 0;
for ( i = 0; i < pNtk->nNodes; i++ )
{
pObj = pNtk->pNodes[i];
if ( pObj->Type == KIT_DSD_AND )
Counter += ((int)pObj->nFans - 1);
else if ( pObj->Type == KIT_DSD_XOR )
Counter += ((int)pObj->nFans - 1) * 3;
else if ( pObj->Type == KIT_DSD_PRIME ) // assuming MUX decomposition
Counter += 3;
}
return Counter;
}
/**Function*************************************************************
Synopsis [Returns 1 if the non-DSD 4-var func is implementable with two 3-LUTs.] Synopsis [Returns 1 if the non-DSD 4-var func is implementable with two 3-LUTs.]
Description [] Description []
...@@ -1883,7 +1967,7 @@ int Kit_DsdCheckVar4Dec2( Kit_DsdNtk_t * pNtk0, Kit_DsdNtk_t * pNtk1 ) ...@@ -1883,7 +1967,7 @@ int Kit_DsdCheckVar4Dec2( Kit_DsdNtk_t * pNtk0, Kit_DsdNtk_t * pNtk1 )
SeeAlso [] SeeAlso []
***********************************************************************/ ***********************************************************************/
void Kit_DsdDecompose_rec( Kit_DsdNtk_t * pNtk, Kit_DsdObj_t * pObj, unsigned uSupp, unsigned char * pPar, int nDecMux ) void Kit_DsdDecompose_rec( Kit_DsdNtk_t * pNtk, Kit_DsdObj_t * pObj, unsigned uSupp, unsigned short * pPar, int nDecMux )
{ {
Kit_DsdObj_t * pRes, * pRes0, * pRes1; Kit_DsdObj_t * pRes, * pRes0, * pRes1;
int nWords = Kit_TruthWordNum(pObj->nFans); int nWords = Kit_TruthWordNum(pObj->nFans);
......
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