/**CFile**************************************************************** FileName [sclLibScl.c] SystemName [ABC: Logic synthesis and verification system.] PackageName [Standard-cell library representation.] Synopsis [Liberty abstraction for delay-oriented mapping.] Author [Alan Mishchenko, Niklas Een] Affiliation [UC Berkeley] Date [Ver. 1.0. Started - August 24, 2012.] Revision [$Id: sclLibScl.c,v 1.0 2012/08/24 00:00:00 alanmi Exp $] ***********************************************************************/ #include "sclLib.h" #include "misc/st/st.h" #include "map/mio/mio.h" #include "bool/kit/kit.h" ABC_NAMESPACE_IMPL_START //////////////////////////////////////////////////////////////////////// /// DECLARATIONS /// //////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////// /// FUNCTION DEFINITIONS /// //////////////////////////////////////////////////////////////////////// /**Function************************************************************* Synopsis [Reading library from file.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ static void Abc_SclReadSurface( Vec_Str_t * vOut, int * pPos, SC_Surface * p ) { Vec_Flt_t * vVec; int i, j; for ( i = Vec_StrGetI(vOut, pPos); i != 0; i-- ) Vec_FltPush( p->vIndex0, Vec_StrGetF(vOut, pPos) ); for ( i = Vec_StrGetI(vOut, pPos); i != 0; i-- ) Vec_FltPush( p->vIndex1, Vec_StrGetF(vOut, pPos) ); for ( i = 0; i < Vec_FltSize(p->vIndex0); i++ ) { vVec = Vec_FltAlloc( Vec_FltSize(p->vIndex1) ); Vec_PtrPush( p->vData, vVec ); for ( j = 0; j < Vec_FltSize(p->vIndex1); j++ ) Vec_FltPush( vVec, Vec_StrGetF(vOut, pPos) ); } for ( i = 0; i < 3; i++ ) p->approx[0][i] = Vec_StrGetF( vOut, pPos ); for ( i = 0; i < 4; i++ ) p->approx[1][i] = Vec_StrGetF( vOut, pPos ); for ( i = 0; i < 6; i++ ) p->approx[2][i] = Vec_StrGetF( vOut, pPos ); } static int Abc_SclReadLibrary( Vec_Str_t * vOut, int * pPos, SC_Lib * p ) { int i, j, k, n; int version = Vec_StrGetI( vOut, pPos ); if ( version != ABC_SCL_CUR_VERSION ) { Abc_Print( -1, "Wrong version of the SCL file.\n" ); return 0; } assert( version == ABC_SCL_CUR_VERSION ); // wrong version of the file // Read non-composite fields: p->pName = Vec_StrGetS(vOut, pPos); p->default_wire_load = Vec_StrGetS(vOut, pPos); p->default_wire_load_sel = Vec_StrGetS(vOut, pPos); p->default_max_out_slew = Vec_StrGetF(vOut, pPos); p->unit_time = Vec_StrGetI(vOut, pPos); p->unit_cap_fst = Vec_StrGetF(vOut, pPos); p->unit_cap_snd = Vec_StrGetI(vOut, pPos); // Read 'wire_load' vector: for ( i = Vec_StrGetI(vOut, pPos); i != 0; i-- ) { SC_WireLoad * pWL = Abc_SclWireLoadAlloc(); Vec_PtrPush( p->vWireLoads, pWL ); pWL->pName = Vec_StrGetS(vOut, pPos); pWL->cap = Vec_StrGetF(vOut, pPos); pWL->slope = Vec_StrGetF(vOut, pPos); for ( j = Vec_StrGetI(vOut, pPos); j != 0; j-- ) { Vec_IntPush( pWL->vFanout, Vec_StrGetI(vOut, pPos) ); Vec_FltPush( pWL->vLen, Vec_StrGetF(vOut, pPos) ); } } // Read 'wire_load_sel' vector: for ( i = Vec_StrGetI(vOut, pPos); i != 0; i-- ) { SC_WireLoadSel * pWLS = Abc_SclWireLoadSelAlloc(); Vec_PtrPush( p->vWireLoadSels, pWLS ); pWLS->pName = Vec_StrGetS(vOut, pPos); for ( j = Vec_StrGetI(vOut, pPos); j != 0; j-- ) { Vec_FltPush( pWLS->vAreaFrom, Vec_StrGetF(vOut, pPos) ); Vec_FltPush( pWLS->vAreaTo, Vec_StrGetF(vOut, pPos) ); Vec_PtrPush( pWLS->vWireLoadModel, Vec_StrGetS(vOut, pPos) ); } } for ( i = Vec_StrGetI(vOut, pPos); i != 0; i-- ) { SC_Cell * pCell = Abc_SclCellAlloc(); pCell->Id = SC_LibCellNum(p); Vec_PtrPush( p->vCells, pCell ); pCell->pName = Vec_StrGetS(vOut, pPos); pCell->area = Vec_StrGetF(vOut, pPos); pCell->drive_strength = Vec_StrGetI(vOut, pPos); pCell->n_inputs = Vec_StrGetI(vOut, pPos); pCell->n_outputs = Vec_StrGetI(vOut, pPos); /* printf( "%s\n", pCell->pName ); if ( !strcmp( "XOR3_X4M_A9TL", pCell->pName ) ) { int s = 0; } */ for ( j = 0; j < pCell->n_inputs; j++ ) { SC_Pin * pPin = Abc_SclPinAlloc(); Vec_PtrPush( pCell->vPins, pPin ); pPin->dir = sc_dir_Input; pPin->pName = Vec_StrGetS(vOut, pPos); pPin->rise_cap = Vec_StrGetF(vOut, pPos); pPin->fall_cap = Vec_StrGetF(vOut, pPos); } for ( j = 0; j < pCell->n_outputs; j++ ) { SC_Pin * pPin = Abc_SclPinAlloc(); Vec_PtrPush( pCell->vPins, pPin ); pPin->dir = sc_dir_Output; pPin->pName = Vec_StrGetS(vOut, pPos); pPin->max_out_cap = Vec_StrGetF(vOut, pPos); pPin->max_out_slew = Vec_StrGetF(vOut, pPos); k = Vec_StrGetI(vOut, pPos); assert( k == pCell->n_inputs ); // read function // (possibly empty) formula is always given assert( version == ABC_SCL_CUR_VERSION ); assert( pPin->func_text == NULL ); pPin->func_text = Vec_StrGetS(vOut, pPos); if ( pPin->func_text[0] == 0 ) { // formula is not given - read truth table ABC_FREE( pPin->func_text ); assert( Vec_WrdSize(pPin->vFunc) == 0 ); Vec_WrdGrow( pPin->vFunc, Abc_Truth6WordNum(pCell->n_inputs) ); for ( k = 0; k < Vec_WrdCap(pPin->vFunc); k++ ) Vec_WrdPush( pPin->vFunc, Vec_StrGetW(vOut, pPos) ); } else { // formula is given - derive truth table SC_Pin * pPin2; Vec_Ptr_t * vNames; // collect input names vNames = Vec_PtrAlloc( pCell->n_inputs ); SC_CellForEachPinIn( pCell, pPin2, n ) Vec_PtrPush( vNames, pPin2->pName ); // derive truth table assert( Vec_WrdSize(pPin->vFunc) == 0 ); Vec_WrdFree( pPin->vFunc ); pPin->vFunc = Mio_ParseFormulaTruth( pPin->func_text, (char **)Vec_PtrArray(vNames), pCell->n_inputs ); Vec_PtrFree( vNames ); // skip truth table assert( Vec_WrdSize(pPin->vFunc) == Abc_Truth6WordNum(pCell->n_inputs) ); for ( k = 0; k < Vec_WrdSize(pPin->vFunc); k++ ) { word Value = Vec_StrGetW(vOut, pPos); assert( Value == Vec_WrdEntry(pPin->vFunc, k) ); } } // Read 'rtiming': (pin-to-pin timing tables for this particular output) for ( k = 0; k < pCell->n_inputs; k++ ) { SC_Timings * pRTime = Abc_SclTimingsAlloc(); Vec_PtrPush( pPin->vRTimings, pRTime ); pRTime->pName = Vec_StrGetS(vOut, pPos); n = Vec_StrGetI(vOut, pPos); assert( n <= 1 ); if ( n == 1 ) { SC_Timing * pTime = Abc_SclTimingAlloc(); Vec_PtrPush( pRTime->vTimings, pTime ); pTime->tsense = (SC_TSense)Vec_StrGetI(vOut, pPos); Abc_SclReadSurface( vOut, pPos, pTime->pCellRise ); Abc_SclReadSurface( vOut, pPos, pTime->pCellFall ); Abc_SclReadSurface( vOut, pPos, pTime->pRiseTrans ); Abc_SclReadSurface( vOut, pPos, pTime->pFallTrans ); } else assert( Vec_PtrSize(pRTime->vTimings) == 0 ); } } } return 1; } SC_Lib * Abc_SclReadFromStr( Vec_Str_t * vOut ) { SC_Lib * p; int Pos = 0; // read the library p = Abc_SclLibAlloc(); if ( !Abc_SclReadLibrary( vOut, &Pos, p ) ) return NULL; assert( Pos == Vec_StrSize(vOut) ); // hash gates by name Abc_SclHashCells( p ); Abc_SclLinkCells( p ); return p; } SC_Lib * Abc_SclReadFromFile( char * pFileName ) { SC_Lib * p; FILE * pFile; Vec_Str_t * vOut; 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 ); rewind( pFile ); // load the contents vOut = Vec_StrAlloc( nFileSize ); vOut->nSize = vOut->nCap; assert( nFileSize == Vec_StrSize(vOut) ); nFileSize = fread( Vec_StrArray(vOut), 1, Vec_StrSize(vOut), pFile ); assert( nFileSize == Vec_StrSize(vOut) ); fclose( pFile ); // read the library p = Abc_SclReadFromStr( vOut ); if ( p != NULL ) p->pFileName = Abc_UtilStrsav( pFileName ); if ( p != NULL ) Abc_SclLibNormalize( p ); Vec_StrFree( vOut ); return p; } /**Function************************************************************* Synopsis [Writing library into file.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ static void Abc_SclWriteSurface( Vec_Str_t * vOut, SC_Surface * p ) { Vec_Flt_t * vVec; float Entry; int i, k; Vec_StrPutI( vOut, Vec_FltSize(p->vIndex0) ); Vec_FltForEachEntry( p->vIndex0, Entry, i ) Vec_StrPutF( vOut, Entry ); Vec_StrPutI( vOut, Vec_FltSize(p->vIndex1) ); Vec_FltForEachEntry( p->vIndex1, Entry, i ) Vec_StrPutF( vOut, Entry ); Vec_PtrForEachEntry( Vec_Flt_t *, p->vData, vVec, i ) Vec_FltForEachEntry( vVec, Entry, k ) Vec_StrPutF( vOut, Entry ); for ( i = 0; i < 3; i++ ) Vec_StrPutF( vOut, p->approx[0][i] ); for ( i = 0; i < 4; i++ ) Vec_StrPutF( vOut, p->approx[1][i] ); for ( i = 0; i < 6; i++ ) Vec_StrPutF( vOut, p->approx[2][i] ); } static void Abc_SclWriteLibrary( Vec_Str_t * vOut, SC_Lib * p ) { SC_WireLoad * pWL; SC_WireLoadSel * pWLS; SC_Cell * pCell; SC_Pin * pPin; int n_valid_cells; int i, j, k; Vec_StrPutI( vOut, ABC_SCL_CUR_VERSION ); // Write non-composite fields: Vec_StrPutS( vOut, p->pName ); Vec_StrPutS( vOut, p->default_wire_load ); Vec_StrPutS( vOut, p->default_wire_load_sel ); Vec_StrPutF( vOut, p->default_max_out_slew ); assert( p->unit_time >= 0 ); assert( p->unit_cap_snd >= 0 ); Vec_StrPutI( vOut, p->unit_time ); Vec_StrPutF( vOut, p->unit_cap_fst ); Vec_StrPutI( vOut, p->unit_cap_snd ); // Write 'wire_load' vector: Vec_StrPutI( vOut, Vec_PtrSize(p->vWireLoads) ); SC_LibForEachWireLoad( p, pWL, i ) { Vec_StrPutS( vOut, pWL->pName ); Vec_StrPutF( vOut, pWL->cap ); Vec_StrPutF( vOut, pWL->slope ); Vec_StrPutI( vOut, Vec_IntSize(pWL->vFanout) ); for ( j = 0; j < Vec_IntSize(pWL->vFanout); j++ ) { Vec_StrPutI( vOut, Vec_IntEntry(pWL->vFanout, j) ); Vec_StrPutF( vOut, Vec_FltEntry(pWL->vLen, j) ); } } // Write 'wire_load_sel' vector: Vec_StrPutI( vOut, Vec_PtrSize(p->vWireLoadSels) ); SC_LibForEachWireLoadSel( p, pWLS, i ) { Vec_StrPutS( vOut, pWLS->pName ); Vec_StrPutI( vOut, Vec_FltSize(pWLS->vAreaFrom) ); for ( j = 0; j < Vec_FltSize(pWLS->vAreaFrom); j++) { Vec_StrPutF( vOut, Vec_FltEntry(pWLS->vAreaFrom, j) ); Vec_StrPutF( vOut, Vec_FltEntry(pWLS->vAreaTo, j) ); Vec_StrPutS( vOut, (char *)Vec_PtrEntry(pWLS->vWireLoadModel, j) ); } } // Write 'cells' vector: n_valid_cells = 0; SC_LibForEachCell( p, pCell, i ) if ( !(pCell->seq || pCell->unsupp) ) n_valid_cells++; Vec_StrPutI( vOut, n_valid_cells ); SC_LibForEachCell( p, pCell, i ) { if ( pCell->seq || pCell->unsupp ) continue; Vec_StrPutS( vOut, pCell->pName ); Vec_StrPutF( vOut, pCell->area ); Vec_StrPutI( vOut, pCell->drive_strength ); // Write 'pins': (sorted at this point; first inputs, then outputs) Vec_StrPutI( vOut, pCell->n_inputs); Vec_StrPutI( vOut, pCell->n_outputs); SC_CellForEachPinIn( pCell, pPin, j ) { assert(pPin->dir == sc_dir_Input); Vec_StrPutS( vOut, pPin->pName ); Vec_StrPutF( vOut, pPin->rise_cap ); Vec_StrPutF( vOut, pPin->fall_cap ); } SC_CellForEachPinOut( pCell, pPin, j ) { SC_Timings * pRTime; word uWord; assert(pPin->dir == sc_dir_Output); Vec_StrPutS( vOut, pPin->pName ); Vec_StrPutF( vOut, pPin->max_out_cap ); Vec_StrPutF( vOut, pPin->max_out_slew ); Vec_StrPutI( vOut, pCell->n_inputs ); // write function Vec_StrPutS( vOut, pPin->func_text ? pPin->func_text : (char *)"" ); // write truth table assert( Vec_WrdSize(pPin->vFunc) == Abc_Truth6WordNum(pCell->n_inputs) ); Vec_WrdForEachEntry( pPin->vFunc, uWord, k ) // -- 'size = 1u << (n_vars - 6)' Vec_StrPutW( vOut, uWord ); // -- 64-bit number, written uncompressed (low-byte first) // Write 'rtiming': (pin-to-pin timing tables for this particular output) assert( Vec_PtrSize(pPin->vRTimings) == pCell->n_inputs ); SC_PinForEachRTiming( pPin, pRTime, k ) { Vec_StrPutS( vOut, pRTime->pName ); Vec_StrPutI( vOut, Vec_PtrSize(pRTime->vTimings) ); // -- NOTE! After post-processing, the size of the 'rtiming[k]' vector is either // 0 or 1 (in static timing, we have merged all tables to get the worst case). // The case with size 0 should only occur for multi-output gates. if ( Vec_PtrSize(pRTime->vTimings) == 1 ) { SC_Timing * pTime = (SC_Timing *)Vec_PtrEntry( pRTime->vTimings, 0 ); // -- NOTE! We don't need to save 'related_pin' string because we have sorted // the elements on input pins. Vec_StrPutI( vOut, (int)pTime->tsense); Abc_SclWriteSurface( vOut, pTime->pCellRise ); Abc_SclWriteSurface( vOut, pTime->pCellFall ); Abc_SclWriteSurface( vOut, pTime->pRiseTrans ); Abc_SclWriteSurface( vOut, pTime->pFallTrans ); } else assert( Vec_PtrSize(pRTime->vTimings) == 0 ); } } } } void Abc_SclWriteScl( char * pFileName, SC_Lib * p ) { Vec_Str_t * vOut; vOut = Vec_StrAlloc( 10000 ); Abc_SclWriteLibrary( vOut, p ); if ( Vec_StrSize(vOut) > 0 ) { FILE * pFile = fopen( pFileName, "wb" ); if ( pFile == NULL ) printf( "Cannot open file \"%s\" for writing.\n", pFileName ); else { fwrite( Vec_StrArray(vOut), 1, Vec_StrSize(vOut), pFile ); fclose( pFile ); } } Vec_StrFree( vOut ); } /**Function************************************************************* Synopsis [Writing library into text file.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ static void Abc_SclWriteSurfaceText( FILE * s, SC_Surface * p ) { Vec_Flt_t * vVec; float Entry; int i, k; fprintf( s, " index_1(\"" ); Vec_FltForEachEntry( p->vIndex0, Entry, i ) fprintf( s, "%f%s", Entry, i == Vec_FltSize(p->vIndex0)-1 ? "":", " ); fprintf( s, "\");\n" ); fprintf( s, " index_2(\"" ); Vec_FltForEachEntry( p->vIndex1, Entry, i ) fprintf( s, "%f%s", Entry, i == Vec_FltSize(p->vIndex1)-1 ? "":", " ); fprintf( s, "\");\n" ); fprintf( s, " values (\"" ); Vec_PtrForEachEntry( Vec_Flt_t *, p->vData, vVec, i ) { Vec_FltForEachEntry( vVec, Entry, k ) fprintf( s, "%f%s", Entry, i == Vec_PtrSize(p->vData)-1 && k == Vec_FltSize(vVec)-1 ? "\");":", " ); if ( i == Vec_PtrSize(p->vData)-1 ) fprintf( s, "\n" ); else { fprintf( s, "\\\n" ); fprintf( s, " " ); } } /* fprintf( s, " approximations: \n" ); fprintf( s, " " ); for ( i = 0; i < 3; i++ ) fprintf( s, "%f ", p->approx[0][i] ); fprintf( s, "\n" ); fprintf( s, " " ); for ( i = 0; i < 4; i++ ) fprintf( s, "%f ", p->approx[1][i] ); fprintf( s, "\n" ); fprintf( s, " " ); for ( i = 0; i < 6; i++ ) fprintf( s, "%f ", p->approx[2][i] ); fprintf( s, "\n" ); fprintf( s, " \n" ); */ } static void Abc_SclWriteLibraryText( FILE * s, SC_Lib * p ) { SC_WireLoad * pWL; SC_WireLoadSel * pWLS; SC_Cell * pCell; SC_Pin * pPin; int n_valid_cells; int i, j, k; fprintf( s, "/* This Liberty file was generated by ABC on %s */\n", Extra_TimeStamp() ); fprintf( s, "/* The original unabridged library came from file \"%s\".*/\n\n", p->pFileName ); // fprintf( s, "%d", ABC_SCL_CUR_VERSION ); fprintf( s, "library(%s) {\n\n", p->pName ); if ( p->default_wire_load && strlen(p->default_wire_load) ) fprintf( s, " default_wire_load : \"%s\";\n", p->default_wire_load ); if ( p->default_wire_load_sel && strlen(p->default_wire_load_sel) ) fprintf( s, " default_wire_load_selection : \"%s\";\n", p->default_wire_load_sel ); if ( p->default_max_out_slew != -1 ) fprintf( s, " default_max_transition : %f;\n", p->default_max_out_slew ); if ( p->unit_time == 9 ) fprintf( s, " time_unit : \"1ns\";\n" ); else if ( p->unit_time == 10 ) fprintf( s, " time_unit : \"100ps\";\n" ); else if ( p->unit_time == 11 ) fprintf( s, " time_unit : \"10ps\";\n" ); else if ( p->unit_time == 12 ) fprintf( s, " time_unit : \"1ps\";\n" ); else assert( 0 ); fprintf( s, " capacitive_load_unit(%.1f,%s);\n", p->unit_cap_fst, p->unit_cap_snd == 12 ? "pf" : "ff" ); fprintf( s, "\n" ); // Write 'wire_load' vector: SC_LibForEachWireLoad( p, pWL, i ) { fprintf( s, " wire_load(\"%s\") {\n", pWL->pName ); fprintf( s, " capacitance : %f;\n", pWL->cap ); fprintf( s, " slope : %f;\n", pWL->slope ); for ( j = 0; j < Vec_IntSize(pWL->vFanout); j++ ) fprintf( s, " fanout_length( %d, %f );\n", Vec_IntEntry(pWL->vFanout, j), Vec_FltEntry(pWL->vLen, j) ); fprintf( s, " }\n\n" ); } // Write 'wire_load_sel' vector: SC_LibForEachWireLoadSel( p, pWLS, i ) { fprintf( s, " wire_load_selection(\"%s\") {\n", pWLS->pName ); for ( j = 0; j < Vec_FltSize(pWLS->vAreaFrom); j++) fprintf( s, " wire_load_from_area( %f, %f, %s );\n", Vec_FltEntry(pWLS->vAreaFrom, j), Vec_FltEntry(pWLS->vAreaTo, j), (char *)Vec_PtrEntry(pWLS->vWireLoadModel, j) ); fprintf( s, " }\n\n" ); } // Write 'cells' vector: n_valid_cells = 0; SC_LibForEachCell( p, pCell, i ) if ( !(pCell->seq || pCell->unsupp) ) n_valid_cells++; SC_LibForEachCell( p, pCell, i ) { if ( pCell->seq || pCell->unsupp ) continue; fprintf( s, "\n" ); fprintf( s, " cell(%s) {\n", pCell->pName ); fprintf( s, " /* n_inputs = %d n_outputs = %d */\n", pCell->n_inputs, pCell->n_outputs ); fprintf( s, " area : %f;\n", pCell->area ); fprintf( s, " drive_strength : %d;\n", pCell->drive_strength ); SC_CellForEachPinIn( pCell, pPin, j ) { assert(pPin->dir == sc_dir_Input); fprintf( s, " pin(%s) {\n", pPin->pName ); fprintf( s, " direction : %s;\n", "input" ); fprintf( s, " fall_capacitance : %f;\n", pPin->fall_cap ); fprintf( s, " rise_capacitance : %f;\n", pPin->rise_cap ); fprintf( s, " }\n" ); } SC_CellForEachPinOut( pCell, pPin, j ) { SC_Timings * pRTime; // word uWord; assert(pPin->dir == sc_dir_Output); fprintf( s, " pin(%s) {\n", pPin->pName ); fprintf( s, " direction : %s;\n", "output" ); fprintf( s, " max_capacitance : %f;\n", pPin->max_out_cap ); fprintf( s, " max_transition : %f;\n", pPin->max_out_slew ); fprintf( s, " function : \"%s\";\n", pPin->func_text ? pPin->func_text : "?" ); fprintf( s, " /* truth table = " ); Extra_PrintHex( s, (unsigned *)Vec_WrdArray(pPin->vFunc), pCell->n_inputs ); fprintf( s, " */\n" ); // Write 'rtiming': (pin-to-pin timing tables for this particular output) assert( Vec_PtrSize(pPin->vRTimings) == pCell->n_inputs ); SC_PinForEachRTiming( pPin, pRTime, k ) { if ( Vec_PtrSize(pRTime->vTimings) == 1 ) { SC_Timing * pTime = (SC_Timing *)Vec_PtrEntry( pRTime->vTimings, 0 ); fprintf( s, " timing() {\n" ); fprintf( s, " related_pin : \"%s\"\n", pRTime->pName ); if ( pTime->tsense == sc_ts_Pos ) fprintf( s, " timing_sense : positive_unate;\n" ); else if ( pTime->tsense == sc_ts_Neg ) fprintf( s, " timing_sense : negative_unate;\n" ); else if ( pTime->tsense == sc_ts_Non ) fprintf( s, " timing_sense : non_unate;\n" ); else assert( 0 ); fprintf( s, " cell_rise() {\n" ); Abc_SclWriteSurfaceText( s, pTime->pCellRise ); fprintf( s, " }\n" ); fprintf( s, " cell_fall() {\n" ); Abc_SclWriteSurfaceText( s, pTime->pCellFall ); fprintf( s, " }\n" ); fprintf( s, " rise_transition() {\n" ); Abc_SclWriteSurfaceText( s, pTime->pRiseTrans ); fprintf( s, " }\n" ); fprintf( s, " fall_transition() {\n" ); Abc_SclWriteSurfaceText( s, pTime->pFallTrans ); fprintf( s, " }\n" ); fprintf( s, " }\n" ); } else assert( Vec_PtrSize(pRTime->vTimings) == 0 ); } fprintf( s, " }\n" ); } fprintf( s, " }\n" ); } fprintf( s, "}\n\n" ); } void Abc_SclWriteLiberty( char * pFileName, SC_Lib * p ) { FILE * pFile = fopen( pFileName, "wb" ); if ( pFile == NULL ) printf( "Cannot open text file \"%s\" for writing.\n", pFileName ); else { Abc_SclWriteLibraryText( pFile, p ); fclose( pFile ); printf( "Dumped internal library into Liberty file \"%s\".\n", pFileName ); } } //////////////////////////////////////////////////////////////////////// /// END OF FILE /// //////////////////////////////////////////////////////////////////////// ABC_NAMESPACE_IMPL_END