#include #include #include "ace.h" #include "io_ace.h" #include "blif.h" #include "cycle.h" #include "sim.h" #include "bdd.h" #include "depth.h" #include "cube.h" // ABC Headers #include "base/abc/abc.h" #include "base/main/main.h" #include "base/io/ioAbc.h" //#include "vecInt.h" void print_status(Abc_Ntk_t * ntk); void alloc_and_init_activity_info(Abc_Ntk_t * ntk); void ace_update_latch_probs(Abc_Ntk_t * ntk); void print_node_bdd(Abc_Ntk_t * ntk); void print_nodes(Vec_Ptr_t * nodes); int ace_calc_activity(Abc_Ntk_t * ntk, int num_vectors, char * clk_name); st__table * ace_info_hash_table; void print_status(Abc_Ntk_t * ntk) { int i; Abc_Obj_t * obj; Abc_NtkForEachNode(ntk, obj, i) { Ace_Obj_Info_t * info = Ace_ObjInfo(obj); switch (info->status) { case ACE_UNDEF: printf("%d: UNDEFINED\n", i); break; case ACE_DEF: printf("%d: DEFINED\n", i); break; case ACE_SIM: printf("%d: SIM\n", i); break; case ACE_NEW: printf("%d: NEW\n", i); break; case ACE_OLD: printf("%d: OLD\n", i); break; default: printf("Invalid ABC object info status"); exit(1); } } } void alloc_and_init_activity_info(Abc_Ntk_t * ntk) { Vec_Ptr_t * node_vec; Abc_Obj_t * obj_ptr; int i; node_vec = Abc_NtkDfsSeq(ntk); Vec_PtrForEachEntry(Abc_Obj_t*, node_vec, obj_ptr, i) { Ace_Obj_Info_t * info = Ace_ObjInfo(obj_ptr); info->values = NULL; info->status = ACE_UNDEF; info->num_toggles = 0; info->num_ones = 0; } Vec_PtrFree(node_vec); } void ace_update_latch_probs(Abc_Ntk_t * ntk) { Abc_Obj_t * obj_ptr; Abc_Obj_t * fanin_ptr; Abc_Obj_t * fanout_ptr; Ace_Obj_Info_t * fanin_info; Ace_Obj_Info_t * fanout_info; int i; Abc_NtkForEachLatch(ntk, obj_ptr, i) { fanin_ptr = Abc_ObjFanin0(obj_ptr); fanout_ptr = Abc_ObjFanout0(obj_ptr); fanin_info = Ace_ObjInfo(fanin_ptr); fanout_info = Ace_ObjInfo(fanout_ptr); fanout_info->static_prob = fanin_info->static_prob; fanout_info->switch_prob = fanin_info->switch_prob; fanout_info->status = fanin_info->status; } } void print_node_bdd(Abc_Ntk_t * ntk) { Abc_Obj_t * obj; int i; Abc_NtkForEachNode(ntk, obj, i) { DdNode * node = (DdNode*) obj->pData; printf("Object: %d\n", obj->Id); fflush(0); //printf("Fanin: %d\n", Abc_ObjFaninNum(obj)); fflush(0); while (1) { if (node == Cudd_ReadOne((DdManager*)ntk->pManFunc)) { //printf("one!\n"); break; } else if (node == Cudd_ReadLogicZero((DdManager*)ntk->pManFunc)) { //printf("zero!\n"); break; } printf("\tVar: %hd (%08" PRIXPTR ")\n", Cudd_Regular(node)->index, (uintptr_t) node); fflush(0); DdNode * first_node; DdGen* gen = Cudd_FirstNode((DdManager*) ntk->pManFunc, node, &first_node); Cudd_GenFree(gen); node = Cudd_E(node); } } } void print_nodes(Vec_Ptr_t * nodes) { Abc_Obj_t * obj; int i; printf("Printing Nodes\n"); Vec_PtrForEachEntry(Abc_Obj_t*, nodes, obj, i) { printf("\t%d. %d-%d-%s\n", i, Abc_ObjId(obj), Abc_ObjType(obj), Abc_ObjName(obj)); } fflush(0); } int ace_calc_activity(Abc_Ntk_t * ntk, int num_vectors, char * clk_name) { int error = 0; Vec_Ptr_t * nodes_all; Vec_Ptr_t * nodes_logic; Vec_Ptr_t * next_state_node_vec; Vec_Ptr_t * latches_in_cycles_vec; Abc_Obj_t * obj; int i, j; Ace_Obj_Info_t * info; //Build BDD Abc_NtkSopToBdd(ntk); nodes_all = Abc_NtkDfsSeq(ntk); nodes_logic = Abc_NtkDfs(ntk, TRUE); //print_nodes(nodes_logic); Vec_PtrForEachEntry(Abc_Obj_t*, nodes_all, obj, i) { info = Ace_ObjInfo(obj); info->status = ACE_UNDEF; } Abc_NtkForEachPi(ntk, obj, i) { info = Ace_ObjInfo(obj); if (strcmp(Abc_ObjName(obj), clk_name) != 0) { assert(info->static_prob >= 0 && info->static_prob <= 1.0); assert(info->switch_prob >= 0 && info->switch_prob <= 1.0); assert(info->switch_act >= 0 && info->switch_act <= 1.0); assert(info->switch_prob <= 2.0 * (1.0 - info->static_prob)); assert(info->switch_prob <= 2.0 * info->static_prob); } info->status = ACE_DEF; } latches_in_cycles_vec = latches_in_cycles(ntk); printf("%d/%d latches are part of cycle(s)\n", latches_in_cycles_vec->nSize, Abc_NtkLatchNum(ntk)); fflush(0); //if (latches_in_cycles_vec->nSize) if (TRUE) { //print_status(ntk); printf("Stage 1: Simulating Probabilities...\n"); fflush(0); next_state_node_vec = Abc_NtkDfsSeq(ntk); //print_nodes(next_state_node_vec); ace_sim_activities(ntk, next_state_node_vec, num_vectors, 0.05); //ace_sim_activities(ntk, nodes_logic, num_vectors, 0.05); ace_update_latch_probs(ntk); Vec_PtrFree(next_state_node_vec); } //print_status(ntk); printf("Stage 2: Computing Probabilities...\n"); fflush(0); // Currently this stage does nothing #if 0 ace_bdd_get_literals (ntk, &leaves, &literals); i = 0; while(1) { //printf("Calc Iteration = %d\n", i++); fflush(0); if (ace_bdd_build_network_bdds(ntk, leaves, literals, ACE_MAX_BDD_SIZE, ACE_MIN_BDD_PROB) < 1) { break; } ace_update_latch_static_probs(ntk); ace_update_latch_switch_probs(ntk); } st__free_table(leaves); Vec_PtrFree(literals); #endif /*------------- Computing Register Output Activities. ---------------------*/ printf("Stage 3: Computing Register Output Activities...\n"); fflush(0); Abc_NtkForEachLatchOutput(ntk, obj, i) { Ace_Obj_Info_t * info2 = Ace_ObjInfo(obj); info2->switch_act = info2->switch_prob; assert(info2->switch_act >= 0.0); } Abc_NtkForEachPi(ntk, obj, i) { assert(Ace_ObjInfo(obj)->switch_act >= 0.0); } /*------------- Calculate switching activities. ---------------------*/ printf("Stage 4: Computing Switching Activities...\n"); fflush(0); /* Do latches first, then logic after */ Vec_PtrForEachEntry(Abc_Obj_t*, nodes_all, obj, i) { Ace_Obj_Info_t * info2 = Ace_ObjInfo(obj); switch (Abc_ObjType(obj)) { case ABC_OBJ_PI: if (strcmp(Abc_ObjName(obj), clk_name) == 0) { info2->switch_act = 2; info2->switch_prob = 1; info2->static_prob = 0.5; } else { info2->switch_act = info2->switch_prob; } break; case ABC_OBJ_BO: case ABC_OBJ_LATCH: info2->switch_act = info2->switch_prob; break; default: break; } } Vec_PtrForEachEntry(Abc_Obj_t*, nodes_logic, obj, i) { Ace_Obj_Info_t * info2 = Ace_ObjInfo(obj); //Ace_Obj_Info_t * fanin_info2; assert(Abc_ObjType(obj) == ABC_OBJ_NODE); if (Abc_ObjFaninNum(obj) < 1) { info2->switch_act = 0.0; continue; } else { Vec_Ptr_t * literals = Vec_PtrAlloc(0); Abc_Obj_t * fanin; assert(obj->Type == ABC_OBJ_NODE); Abc_ObjForEachFanin(obj, fanin, j) { Vec_PtrPush(literals, fanin); } info2->switch_act = ace_bdd_calc_switch_act((DdManager*)ntk->pManFunc, obj, literals); Vec_PtrFree(literals); } assert(info2->switch_act >= 0); } Vec_PtrFree(nodes_logic); Vec_PtrFree(latches_in_cycles_vec); return error; } Ace_Obj_Info_t * Ace_ObjInfo(Abc_Obj_t * obj) { Ace_Obj_Info_t * info; if (st__lookup(ace_info_hash_table, (char *) obj, (char **) &info)) { return info; } assert(0); return NULL; } void prob_epsilon_fix(double * d) { if (*d < 0) { assert(*d > 0 - EPSILON); *d = 0; } else if (*d > 1) { assert(*d < 1 + EPSILON); *d = 1.; } } int main(int argc, char * argv[]) { FILE * BLIF = NULL; FILE * IN_ACT = NULL; FILE * OUT_ACT = stdout; ace_pi_format_t pi_format = ACE_CODED; double p, d; int i; int depth; int error = 0; Abc_Frame_t * pAbc; Abc_Ntk_t * ntk; Abc_Obj_t * obj; int seed = 0; p = ACE_PI_STATIC_PROB; d = ACE_PI_SWITCH_PROB; char blif_file_name[BLIF_FILE_NAME_LEN]; char new_blif_file_name[BLIF_FILE_NAME_LEN]; char* clk_name = NULL; ace_io_parse_argv(argc, argv, &BLIF, &IN_ACT, &OUT_ACT, blif_file_name, new_blif_file_name, &pi_format, &p, &d, &seed, &clk_name); srand(seed); pAbc = Abc_FrameGetGlobalFrame(); ntk = Io_Read(blif_file_name, IO_FILE_BLIF, 1, 0); assert(ntk); printf("Objects in network: %d\n", Abc_NtkObjNum(ntk)); printf("PIs in network: %d\n", Abc_NtkPiNum(ntk)); printf("POs in network: %d\n", Abc_NtkPoNum(ntk)); printf("Nodes in network: %d\n", Abc_NtkNodeNum(ntk)); printf("Latches in network: %d\n", Abc_NtkLatchNum(ntk)); if (!Abc_NtkIsAcyclic(ntk)) { printf("Circuit has combinational loops\n"); exit(0); } // Alloc Aux Info Array // Full Allocation Ace_Obj_Info_t * info = (Ace_Obj_Info_t*) calloc(Abc_NtkObjNum(ntk), sizeof(Ace_Obj_Info_t)); ace_info_hash_table = st__init_table(st__ptrcmp, st__ptrhash); int objNum = 0; Abc_NtkForEachObj(ntk, obj, i) { st__insert(ace_info_hash_table, (char *) obj, (char *) &info[objNum]); objNum++; } // Check Depth depth = ace_calc_network_depth(ntk); printf("Max Depth: %d\n", depth); assert(depth > 0); alloc_and_init_activity_info(ntk); switch (pi_format) { case ACE_CODED: printf("Input activities will be assumed (%f, %f, %f)...\n", ACE_PI_STATIC_PROB, ACE_PI_SWITCH_PROB, ACE_PI_SWITCH_ACT); break; case ACE_PD: printf("Input activities will be (%f, %f, %f)...\n", p, d, d); fflush(0); break; case ACE_ACT: printf("Input activities will be read from an activity file...\n"); break; case ACE_VEC: printf("Input activities will be read from a vector file...\n"); break; default: printf("Error reading activities.\n"); error = ACE_ERROR; break; } if (!error) { if (clk_name == NULL) { // No clocks printf( "No clocks detected in blif file. This is not supported.\n"); error = ACE_ERROR; } else { printf("Clock detected: %s\n", clk_name); } } // Read Activities if (!error) { error = ace_io_read_activity(ntk, IN_ACT, pi_format, p, d, clk_name); } if (!error) { error = ace_calc_activity(ntk, ACE_NUM_VECTORS, clk_name); } //Abc_NtkToSop(ntk, 0); Abc_Ntk_t * new_ntk; new_ntk = Abc_NtkToNetlist(ntk); if (!error) { ace_io_print_activity(ntk, OUT_ACT); } if (!error) { Io_WriteHie(ntk, blif_file_name, new_blif_file_name); printf("Done\n"); } fflush(0); return 0; }