/**CFile**************************************************************** FileName [fpgaCore.c] PackageName [MVSIS 1.3: Multi-valued logic synthesis system.] Synopsis [Technology mapping for variable-size-LUT FPGAs.] Author [MVSIS Group] Affiliation [UC Berkeley] Date [Ver. 2.0. Started - August 18, 2004.] Revision [$Id: fpgaCore.c,v 1.7 2004/10/01 23:41:04 satrajit Exp $] ***********************************************************************/ #include "fpgaInt.h" ABC_NAMESPACE_IMPL_START //////////////////////////////////////////////////////////////////////// /// DECLARATIONS /// //////////////////////////////////////////////////////////////////////// static int Fpga_MappingPostProcess( Fpga_Man_t * p ); extern clock_t s_MappingTime; extern int s_MappingMem; //////////////////////////////////////////////////////////////////////// /// FUNCTION DEFINITIONS /// //////////////////////////////////////////////////////////////////////// /**Function************************************************************* Synopsis [Performs technology mapping for the given object graph.] Description [The object graph is stored in the mapping manager. First, all the AND-nodes, which fanout into the POs, are collected in the DFS fashion. Next, three steps are performed: the k-feasible cuts are computed for each node, the truth tables are computed for each cut, and the delay-optimal matches are assigned for each node.] SideEffects [] SeeAlso [] ***********************************************************************/ int Fpga_Mapping( Fpga_Man_t * p ) { clock_t clk, clkTotal = clock(); // collect the nodes reachable from POs in the DFS order (including the choices) p->vAnds = Fpga_MappingDfs( p, 1 ); Fpga_ManReportChoices( p ); // recomputes levels Fpga_MappingSetChoiceLevels( p ); // compute the cuts of nodes in the DFS order clk = clock(); Fpga_MappingCuts( p ); p->timeCuts = clock() - clk; // match the truth tables to the supergates clk = clock(); if ( !Fpga_MappingMatches( p, 1 ) ) return 0; p->timeMatch = clock() - clk; // perform area recovery clk = clock(); if ( !Fpga_MappingPostProcess( p ) ) return 0; p->timeRecover = clock() - clk; //ABC_PRT( "Total mapping time", clock() - clkTotal ); s_MappingTime = clock() - clkTotal; s_MappingMem = Fpga_CutCountAll(p) * (sizeof(Fpga_Cut_t) - sizeof(int) * (FPGA_MAX_LEAVES - p->nVarsMax)); // print the AI-graph used for mapping //Fpga_ManShow( p, "test" ); // if ( p->fVerbose ) // Fpga_MappingPrintOutputArrivals( p ); if ( p->fVerbose ) { ABC_PRT( "Total time", clock() - clkTotal ); } return 1; } /**Function************************************************************* Synopsis [Postprocesses the mapped network for area recovery.] Description [This procedure assumes that the mapping is assigned. It iterates the loop, in which the required times are computed and the mapping is updated. It is conceptually similar to the paper: V. Manohararajah, S. D. Brown, Z. G. Vranesic, Heuristics for area minimization in LUT-based FPGA technology mapping. Proc. IWLS '04.] SideEffects [] SeeAlso [] ***********************************************************************/ int Fpga_MappingPostProcess( Fpga_Man_t * p ) { int fShowSwitching = 0; int fRecoverAreaFlow = 1; int fRecoverArea = 1; float aAreaTotalCur, aAreaTotalCur2; int Iter; clock_t clk; //if ( p->fVerbose ) // printf( "Best clock period = %5.2f\n", Fpga_TimeComputeArrivalMax(p) ); // compute area, set references, and collect nodes used in the mapping Iter = 1; aAreaTotalCur = Fpga_MappingSetRefsAndArea( p ); if ( p->fVerbose ) { printf( "Iteration %dD : Area = %8.1f ", Iter++, aAreaTotalCur ); if ( fShowSwitching ) printf( "Switch = %8.1f ", Fpga_MappingGetSwitching(p,p->vMapping) ); else printf( "Delay = %5.2f ", Fpga_TimeComputeArrivalMax(p) ); ABC_PRT( "Time", p->timeMatch ); } if ( !p->fAreaRecovery ) return 1; if ( fRecoverAreaFlow ) { clk = clock(); // compute the required times and the fanouts Fpga_TimeComputeRequiredGlobal( p, 1 ); // remap topologically Fpga_MappingMatches( p, 0 ); // get the resulting area // aAreaTotalCur = Fpga_MappingSetRefsAndArea( p ); aAreaTotalCur = Fpga_MappingAreaTrav( p ); // note that here we do not update the reference counter // for some reason, this works better on benchmarks if ( p->fVerbose ) { printf( "Iteration %dF : Area = %8.1f ", Iter++, aAreaTotalCur ); if ( fShowSwitching ) printf( "Switch = %8.1f ", Fpga_MappingGetSwitching(p,p->vMapping) ); else printf( "Delay = %5.2f ", Fpga_TimeComputeArrivalMax(p) ); ABC_PRT( "Time", clock() - clk ); } } // update reference counters aAreaTotalCur2 = Fpga_MappingSetRefsAndArea( p ); assert( aAreaTotalCur == aAreaTotalCur2 ); if ( fRecoverArea ) { clk = clock(); // compute the required times and the fanouts Fpga_TimeComputeRequiredGlobal( p, 0 ); // remap topologically if ( p->fSwitching ) Fpga_MappingMatchesSwitch( p ); else Fpga_MappingMatchesArea( p ); // get the resulting area aAreaTotalCur = Fpga_MappingSetRefsAndArea( p ); if ( p->fVerbose ) { printf( "Iteration %d%s : Area = %8.1f ", Iter++, (p->fSwitching?"S":"A"), aAreaTotalCur ); if ( fShowSwitching ) printf( "Switch = %8.1f ", Fpga_MappingGetSwitching(p,p->vMapping) ); else printf( "Delay = %5.2f ", Fpga_TimeComputeArrivalMax(p) ); ABC_PRT( "Time", clock() - clk ); } } p->fAreaGlo = aAreaTotalCur; return 1; } ABC_NAMESPACE_IMPL_END