/** * Author: Jason Luu * Date: May 2009 * * Read a circuit netlist in XML format and populate the netlist data structures for VPR */ #include #include #include #include "util.h" #include "hash.h" #include "vpr_types.h" #include "vpr_utils.h" #include "ReadLine.h" #include "globals.h" #include "ezxml.h" #include "read_xml_util.h" #include "read_netlist.h" #include "pb_type_graph.h" #include "cluster_legality.h" #include "token.h" #include "rr_graph.h" static void processPorts(INOUTP ezxml_t Parent, INOUTP t_pb* pb, INOUTP t_rr_node *rr_graph, INOUTP t_pb** rr_node_to_pb_mapping, INP struct s_hash **vpack_net_hash); static void processPb(INOUTP ezxml_t Parent, INOUTP t_pb* pb, INOUTP t_rr_node *rr_graph, INOUTP t_pb **rr_node_to_pb_mapping, INOUTP int *num_primitives, INP struct s_hash **vpack_net_hash, INP struct s_hash **logical_block_hash, INP int cb_index); static void processComplexBlock(INOUTP ezxml_t Parent, INOUTP t_block *cb, INP int index, INOUTP int *num_primitives, INP const t_arch *arch, INP struct s_hash **vpack_net_hash, INP struct s_hash **logical_block_hash); static struct s_net *alloc_and_init_netlist_from_hash(INP int ncount, INOUTP struct s_hash **nhash); static int add_net_to_hash(INOUTP struct s_hash **nhash, INP char *net_name, INOUTP int *ncount); static void load_external_nets_and_cb(INP int L_num_blocks, INP struct s_block block_list[], INP int ncount, INP struct s_net nlist[], OUTP int *ext_ncount, OUTP struct s_net **ext_nets, INP char **circuit_clocks); static void load_internal_cb_nets(INOUTP t_pb *top_level, INP t_pb_graph_node *pb_graph_node, INOUTP t_rr_node *rr_graph, INOUTP int * curr_net); static void alloc_internal_cb_nets(INOUTP t_pb *top_level, INP t_pb_graph_node *pb_graph_node, INOUTP t_rr_node *rr_graph, INP int pass); static void load_internal_cb_rr_graph_net_nums(INP t_rr_node * cur_rr_node, INP t_rr_node * rr_graph, INOUTP struct s_net * nets, INOUTP int * curr_net, INOUTP int * curr_sink); static void mark_constant_generators(INP int L_num_blocks, INP struct s_block block_list[], INP int ncount, INOUTP struct s_net nlist[]); static void mark_constant_generators_rec(INP t_pb *pb, INP t_rr_node *rr_graph, INOUTP struct s_net nlist[]); /** * Initializes the block_list with info from a netlist * net_file - Name of the netlist file to read * num_blocks - number of CLBs in netlist * block_list - array of blocks in netlist [0..num_blocks - 1] * num_nets - number of nets in netlist * net_list - nets in netlist [0..num_nets - 1] */ void read_netlist(INP const char *net_file, INP const t_arch *arch, OUTP int *L_num_blocks, OUTP struct s_block *block_list[], OUTP int *L_num_nets, OUTP struct s_net *net_list[]) { ezxml_t Cur, Prev, Top; int i; const char *Prop; int bcount; struct s_block *blist; int ext_ncount; struct s_net *ext_nlist; struct s_hash **vpack_net_hash, **logical_block_hash, *temp_hash; char **circuit_inputs, **circuit_outputs, **circuit_clocks; int Count, Len; int num_primitives = 0; /* Parse the file */ vpr_printf(TIO_MESSAGE_INFO, "Begin parsing packed FPGA netlist file.\n"); Top = ezxml_parse_file(net_file); if (NULL == Top) { vpr_printf(TIO_MESSAGE_ERROR, "Unable to load netlist file '%s'.\n", net_file); exit(1); } vpr_printf(TIO_MESSAGE_INFO, "Finished parsing packed FPGA netlist file.\n"); /* Root node should be block */ CheckElement(Top, "block"); /* Check top-level netlist attributes */ Prop = FindProperty(Top, "name", TRUE); vpr_printf(TIO_MESSAGE_INFO, "Netlist generated from file '%s'.\n", Prop); ezxml_set_attr(Top, "name", NULL); Prop = FindProperty(Top, "instance", TRUE); if (strcmp(Prop, "FPGA_packed_netlist[0]") != 0) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Expected instance to be \"FPGA_packed_netlist[0]\", found %s.", Top->line, Prop); exit(1); } ezxml_set_attr(Top, "instance", NULL); /* Parse top-level netlist I/Os */ Cur = FindElement(Top, "inputs", TRUE); circuit_inputs = GetNodeTokens(Cur); FreeNode(Cur); Cur = FindElement(Top, "outputs", TRUE); circuit_outputs = GetNodeTokens(Cur); FreeNode(Cur); Cur = FindElement(Top, "clocks", TRUE); CountTokensInString(Cur->txt, &Count, &Len); if (Count > 0) { circuit_clocks = GetNodeTokens(Cur); } else { circuit_clocks = NULL; } FreeNode(Cur); /* Parse all CLB blocks and all nets*/ bcount = CountChildren(Top, "block", 1); blist = (struct s_block *) my_calloc(bcount, sizeof(t_block)); /* create quick hash look up for vpack_net and logical_block Also reset logical block data structure for pb */ vpack_net_hash = alloc_hash_table(); logical_block_hash = alloc_hash_table(); for (i = 0; i < num_logical_nets; i++) { temp_hash = insert_in_hash_table(vpack_net_hash, vpack_net[i].name, i); assert(temp_hash->count == 1); } for (i = 0; i < num_logical_blocks; i++) { temp_hash = insert_in_hash_table(logical_block_hash, logical_block[i].name, i); logical_block[i].pb = NULL; assert(temp_hash->count == 1); } /* Prcoess netlist */ Cur = Top->child; i = 0; while (Cur) { if (0 == strcmp(Cur->name, "block")) { CheckElement(Cur, "block"); processComplexBlock(Cur, blist, i, &num_primitives, arch, vpack_net_hash, logical_block_hash); Prev = Cur; Cur = Cur->next; FreeNode(Prev); i++; } else { Cur = Cur->next; } } assert(i == bcount); assert(num_primitives == num_logical_blocks); /* Error check */ for (i = 0; i < num_logical_blocks; i++) { if (logical_block[i].pb == NULL) { vpr_printf(TIO_MESSAGE_ERROR, ".blif file and .net file do not match, .net file missing atom %s.\n", logical_block[i].name); exit(1); } } /* TODO: Add additional check to make sure net connections match */ mark_constant_generators(bcount, blist, num_logical_nets, vpack_net); load_external_nets_and_cb(bcount, blist, num_logical_nets, vpack_net, &ext_ncount, &ext_nlist, circuit_clocks); /* TODO: create this function later check_top_IO_matches_IO_blocks(circuit_inputs, circuit_outputs, circuit_clocks, blist, bcount); */ FreeTokens(&circuit_inputs); if (circuit_outputs) FreeTokens(&circuit_outputs); if (circuit_clocks) FreeTokens(&circuit_clocks); FreeNode(Top); /* load mapping between external nets and all nets */ /* jluu TODO: Should use local variables here then assign to globals later, clean up later */ clb_to_vpack_net_mapping = (int *) my_malloc(ext_ncount * sizeof(int)); vpack_to_clb_net_mapping = (int *) my_malloc(num_logical_nets * sizeof(int)); for (i = 0; i < num_logical_nets; i++) { vpack_to_clb_net_mapping[i] = OPEN; } for (i = 0; i < ext_ncount; i++) { temp_hash = get_hash_entry(vpack_net_hash, ext_nlist[i].name); assert(temp_hash != NULL); clb_to_vpack_net_mapping[i] = temp_hash->index; vpack_to_clb_net_mapping[temp_hash->index] = i; } /* Return blocks and nets */ *L_num_blocks = bcount; *block_list = blist; *L_num_nets = ext_ncount; *net_list = ext_nlist; free_hash_table(logical_block_hash); free_hash_table(vpack_net_hash); } /** * XML parser to populate CLB info and to update nets with the nets of this CLB * Parent - XML tag for this CLB * clb - Array of CLBs in the netlist * index - index of the CLB to allocate and load information into * vpack_net_hash - hashtable of all nets in blif netlist * logical_block_hash - hashtable of all atoms in blif netlist */ static void processComplexBlock(INOUTP ezxml_t Parent, INOUTP t_block *cb, INP int index, INOUTP int *num_primitives, INP const t_arch *arch, INP struct s_hash **vpack_net_hash, INP struct s_hash **logical_block_hash) { const char *Prop; boolean found; int num_tokens = 0; t_token *tokens; int i; const t_pb_type * pb_type = NULL; /* parse cb attributes */ cb[index].pb = (t_pb*)my_calloc(1, sizeof(t_pb)); Prop = FindProperty(Parent, "name", TRUE); cb[index].name = my_strdup(Prop); cb[index].pb->name = my_strdup(Prop); ezxml_set_attr(Parent, "name", NULL); Prop = FindProperty(Parent, "instance", TRUE); tokens = GetTokensFromString(Prop, &num_tokens); ezxml_set_attr(Parent, "instance", NULL); if (num_tokens != 4 || tokens[0].type != TOKEN_STRING || tokens[1].type != TOKEN_OPEN_SQUARE_BRACKET || tokens[2].type != TOKEN_INT || tokens[3].type != TOKEN_CLOSE_SQUARE_BRACKET) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown syntax for instance %s in %s. Expected pb_type[instance_number].\n", Parent->line, Prop, Parent->name); exit(1); } assert(my_atoi(tokens[2].data) == index); found = FALSE; for (i = 0; i < num_types; i++) { if (strcmp(type_descriptors[i].name, tokens[0].data) == 0) { cb[index].type = &type_descriptors[i]; pb_type = cb[index].type->pb_type; found = TRUE; break; } } if (!found) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown cb type %s for cb %s #%d.\n", Parent->line, Prop, cb[index].name, index); exit(1); } /* Parse all pbs and CB internal nets*/ cb[index].pb->logical_block = OPEN; cb[index].pb->pb_graph_node = cb[index].type->pb_graph_head; num_rr_nodes = cb[index].pb->pb_graph_node->total_pb_pins; rr_node = (t_rr_node*)my_calloc((num_rr_nodes * 2) + cb[index].type->pb_type->num_input_pins + cb[index].type->pb_type->num_output_pins + cb[index].type->pb_type->num_clock_pins, sizeof(t_rr_node)); alloc_and_load_rr_graph_for_pb_graph_node(cb[index].pb->pb_graph_node, arch, 0); cb[index].pb->rr_node_to_pb_mapping = (t_pb **)my_calloc(cb[index].type->pb_graph_head->total_pb_pins, sizeof(t_pb *)); cb[index].pb->rr_graph = rr_node; Prop = FindProperty(Parent, "mode", TRUE); ezxml_set_attr(Parent, "mode", NULL); found = FALSE; for (i = 0; i < pb_type->num_modes; i++) { if (strcmp(Prop, pb_type->modes[i].name) == 0) { cb[index].pb->mode = i; found = TRUE; } } if (!found) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown mode %s for cb %s #%d.\n", Parent->line, Prop, cb[index].name, index); exit(1); } processPb(Parent, cb[index].pb, cb[index].pb->rr_graph, cb[index].pb->rr_node_to_pb_mapping, num_primitives, vpack_net_hash, logical_block_hash, index); cb[index].nets = (int *)my_malloc(cb[index].type->num_pins * sizeof(int)); for (i = 0; i < cb[index].type->num_pins; i++) { cb[index].nets[i] = OPEN; } alloc_internal_cb_nets(cb[index].pb, cb[index].pb->pb_graph_node, cb[index].pb->rr_graph, 1); alloc_internal_cb_nets(cb[index].pb, cb[index].pb->pb_graph_node, cb[index].pb->rr_graph, 2); i = 0; load_internal_cb_nets(cb[index].pb, cb[index].pb->pb_graph_node, cb[index].pb->rr_graph, &i); freeTokens(tokens, num_tokens); #if 0 /* print local nets */ for (i = 0; i < cb[index].pb->num_local_nets; i++) { vpr_printf(TIO_MESSAGE_INFO, "local net %s: ", cb[index].pb->name); for (j = 0; j <= cb[index].pb->local_nets[i].num_sinks; j++) { vpr_printf(TIO_MESSAGE_INFO, "%d ", cb[index].pb->local_nets[i].node_block[j]); } vpr_printf(TIO_MESSAGE_INFO, "\n"); } #endif } /** * XML parser to populate pb info and to update internal nets of the parent CLB * Parent - XML tag for this pb_type * pb - physical block to use * vpack_net_hash - hashtable of original blif net names and indices * logical_block_hash - hashtable of original blif atom names and indices */ static void processPb(INOUTP ezxml_t Parent, INOUTP t_pb* pb, INOUTP t_rr_node *rr_graph, INOUTP t_pb** rr_node_to_pb_mapping, INOUTP int *num_primitives, INP struct s_hash **vpack_net_hash, INP struct s_hash **logical_block_hash, INP int cb_index) { ezxml_t Cur, Prev, lookahead; const char *Prop; const char *instance_type; int i, j, pb_index; boolean found; const t_pb_type *pb_type; t_token *tokens; int num_tokens; struct s_hash *temp_hash; Cur = FindElement(Parent, "inputs", TRUE); processPorts(Cur, pb, rr_graph, rr_node_to_pb_mapping, vpack_net_hash); FreeNode(Cur); Cur = FindElement(Parent, "outputs", TRUE); processPorts(Cur, pb, rr_graph, rr_node_to_pb_mapping, vpack_net_hash); FreeNode(Cur); Cur = FindElement(Parent, "clocks", TRUE); processPorts(Cur, pb, rr_graph, rr_node_to_pb_mapping, vpack_net_hash); FreeNode(Cur); pb_type = pb->pb_graph_node->pb_type; if (pb_type->num_modes == 0) { /* LUT specific optimizations */ if (strcmp(pb_type->blif_model, ".names") == 0) { pb->lut_pin_remap = (int*)my_malloc(pb_type->num_input_pins * sizeof(int)); for (i = 0; i < pb_type->num_input_pins; i++) { pb->lut_pin_remap[i] = OPEN; } } else { pb->lut_pin_remap = NULL; } temp_hash = get_hash_entry(logical_block_hash, pb->name); if (temp_hash == NULL) { vpr_printf(TIO_MESSAGE_ERROR, ".net file and .blif file do not match, encountered unknown primitive %s in .net file.\n", pb->name); exit(1); } pb->logical_block = temp_hash->index; assert(logical_block[temp_hash->index].pb == NULL); logical_block[temp_hash->index].pb = pb; logical_block[temp_hash->index].clb_index = cb_index; (*num_primitives)++; } else { /* process children of child if exists */ pb->child_pbs = (t_pb **)my_calloc(pb_type->modes[pb->mode].num_pb_type_children, sizeof(t_pb*)); for (i = 0; i < pb_type->modes[pb->mode].num_pb_type_children; i++) { pb->child_pbs[i] = (t_pb *)my_calloc( pb_type->modes[pb->mode].pb_type_children[i].num_pb, sizeof(t_pb)); for (j = 0; j < pb_type->modes[pb->mode].pb_type_children[i].num_pb; j++) { pb->child_pbs[i][j].logical_block = OPEN; } } /* Populate info for each physical block */ Cur = Parent->child; while (Cur) { if (0 == strcmp(Cur->name, "block")) { CheckElement(Cur, "block"); instance_type = FindProperty(Cur, "instance", TRUE); tokens = GetTokensFromString(instance_type, &num_tokens); ezxml_set_attr(Cur, "instance", NULL); if (num_tokens != 4 || tokens[0].type != TOKEN_STRING || tokens[1].type != TOKEN_OPEN_SQUARE_BRACKET || tokens[2].type != TOKEN_INT || tokens[3].type != TOKEN_CLOSE_SQUARE_BRACKET) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown syntax for instance %s in %s. Expected pb_type[instance_number].\n", Cur->line, instance_type, Cur->name); exit(1); } found = FALSE; pb_index = OPEN; for (i = 0; i < pb_type->modes[pb->mode].num_pb_type_children; i++) { if (strcmp( pb_type->modes[pb->mode].pb_type_children[i].name, tokens[0].data) == 0) { if (my_atoi(tokens[2].data) >= pb_type->modes[pb->mode].pb_type_children[i].num_pb) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Instance number exceeds # of pb available for instance %s in %s.\n", Cur->line, instance_type, Cur->name); exit(1); } pb_index = my_atoi(tokens[2].data); if (pb->child_pbs[i][pb_index].pb_graph_node != NULL) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] node is used by two different blocks %s and %s.\n", Cur->line, instance_type, pb->child_pbs[i][pb_index].name); exit(1); } pb->child_pbs[i][pb_index].pb_graph_node = &pb->pb_graph_node->child_pb_graph_nodes[pb->mode][i][pb_index]; found = TRUE; break; } } if (!found) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown pb type %s.\n", Cur->line, instance_type); exit(1); } Prop = FindProperty(Cur, "name", TRUE); ezxml_set_attr(Cur, "name", NULL); if (0 != strcmp(Prop, "open")) { pb->child_pbs[i][pb_index].name = my_strdup(Prop); /* Parse all pbs and CB internal nets*/ pb->child_pbs[i][pb_index].logical_block = OPEN; Prop = FindProperty(Cur, "mode", FALSE); if (Prop) { ezxml_set_attr(Cur, "mode", NULL); } pb->child_pbs[i][pb_index].mode = 0; found = FALSE; for (j = 0; j < pb->child_pbs[i][pb_index].pb_graph_node->pb_type->num_modes; j++) { if (strcmp(Prop, pb->child_pbs[i][pb_index].pb_graph_node->pb_type->modes[j].name) == 0) { pb->child_pbs[i][pb_index].mode = j; found = TRUE; } } if (!found && pb->child_pbs[i][pb_index].pb_graph_node->pb_type->num_modes != 0) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown mode %s for cb %s #%d.\n", Cur->line, Prop, pb->child_pbs[i][pb_index].name, pb_index); exit(1); } pb->child_pbs[i][pb_index].parent_pb = pb; pb->child_pbs[i][pb_index].rr_graph = pb->rr_graph; processPb(Cur, &pb->child_pbs[i][pb_index], rr_graph, rr_node_to_pb_mapping, num_primitives, vpack_net_hash, logical_block_hash, cb_index); } else { /* physical block has no used primitives but it may have used routing */ pb->child_pbs[i][pb_index].name = NULL; pb->child_pbs[i][pb_index].logical_block = OPEN; lookahead = FindElement(Cur, "outputs", FALSE); if (lookahead != NULL) { lookahead = FindFirstElement(lookahead, "port", TRUE); Prop = FindProperty(Cur, "mode", FALSE); if (Prop) { ezxml_set_attr(Cur, "mode", NULL); } pb->child_pbs[i][pb_index].mode = 0; found = FALSE; for (j = 0; j < pb->child_pbs[i][pb_index].pb_graph_node->pb_type->num_modes; j++) { if (strcmp(Prop, pb->child_pbs[i][pb_index].pb_graph_node->pb_type->modes[j].name) == 0) { pb->child_pbs[i][pb_index].mode = j; found = TRUE; } } if (!found && pb->child_pbs[i][pb_index].pb_graph_node->pb_type->num_modes != 0) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown mode %s for cb %s #%d.\n", Cur->line, Prop, pb->child_pbs[i][pb_index].name, pb_index); exit(1); } pb->child_pbs[i][pb_index].parent_pb = pb; pb->child_pbs[i][pb_index].rr_graph = pb->rr_graph; processPb(Cur, &pb->child_pbs[i][pb_index], rr_graph, rr_node_to_pb_mapping, num_primitives, vpack_net_hash, logical_block_hash, cb_index); } } Prev = Cur; Cur = Cur->next; FreeNode(Prev); freeTokens(tokens, num_tokens); } else { Cur = Cur->next; } } } } /** * Allocates memory for nets and loads the name of the net so that it can be identified and loaded with * more complete information later * ncount - number of nets in the hashtable of nets * nhash - hashtable of nets * returns array of nets stored in hashtable */ static struct s_net *alloc_and_init_netlist_from_hash(INP int ncount, INOUTP struct s_hash **nhash) { struct s_net *nlist; struct s_hash_iterator hash_iter; struct s_hash *curr_net; int i; nlist = (struct s_net *)my_calloc(ncount, sizeof(struct s_net)); hash_iter = start_hash_table_iterator(); curr_net = get_next_hash(nhash, &hash_iter); while (curr_net != NULL) { assert(nlist[curr_net->index].name == NULL); nlist[curr_net->index].name = my_strdup(curr_net->name); nlist[curr_net->index].num_sinks = curr_net->count - 1; nlist[curr_net->index].node_block = (int *)my_malloc( curr_net->count * sizeof(int)); nlist[curr_net->index].node_block_pin = (int *)my_malloc( curr_net->count * sizeof(int)); nlist[curr_net->index].is_global = FALSE; for (i = 0; i < curr_net->count; i++) { nlist[curr_net->index].node_block[i] = OPEN; nlist[curr_net->index].node_block_pin[i] = OPEN; } curr_net = get_next_hash(nhash, &hash_iter); } return nlist; } /** * Adds net to hashtable of nets. If the net is "open", then this is a keyword so do not add it. * If the net already exists, increase the count on that net */ static int add_net_to_hash(INOUTP struct s_hash **nhash, INP char *net_name, INOUTP int *ncount) { struct s_hash *hash_value; if (strcmp(net_name, "open") == 0) { return OPEN; } hash_value = insert_in_hash_table(nhash, net_name, *ncount); if (hash_value->count == 1) { assert(*ncount == hash_value->index); (*ncount)++; } return hash_value->index; } static void processPorts(INOUTP ezxml_t Parent, INOUTP t_pb* pb, t_rr_node *rr_graph, INOUTP t_pb** rr_node_to_pb_mapping, INP struct s_hash **vpack_net_hash) { int i, j, in_port, out_port, clock_port, num_tokens; ezxml_t Cur, Prev; const char *Prop; char **pins; char *port_name, *interconnect_name; int rr_node_index; t_pb_graph_pin *** pin_node; int *num_ptrs, num_sets; struct s_hash *temp_hash; boolean found; Cur = Parent->child; while (Cur) { if (0 == strcmp(Cur->name, "port")) { CheckElement(Cur, "port"); Prop = FindProperty(Cur, "name", TRUE); ezxml_set_attr(Cur, "name", NULL); in_port = out_port = clock_port = 0; found = FALSE; for (i = 0; i < pb->pb_graph_node->pb_type->num_ports; i++) { if (0 == strcmp(pb->pb_graph_node->pb_type->ports[i].name, Prop)) { found = TRUE; break; } if (pb->pb_graph_node->pb_type->ports[i].is_clock && pb->pb_graph_node->pb_type->ports[i].type == IN_PORT) { clock_port++; } else if (!pb->pb_graph_node->pb_type->ports[i].is_clock && pb->pb_graph_node->pb_type->ports[i].type == IN_PORT) { in_port++; } else { assert( pb->pb_graph_node->pb_type->ports[i].type == OUT_PORT); out_port++; } } if (!found) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown port %s for pb %s[%d].\n", Cur->line, Prop, pb->pb_graph_node->pb_type->name, pb->pb_graph_node->placement_index); exit(1); } pins = GetNodeTokens(Cur); num_tokens = CountTokens(pins); if (0 == strcmp(Parent->name, "inputs")) { if (num_tokens != pb->pb_graph_node->num_input_pins[in_port]) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Incorrect # pins %d found for port %s for pb %s[%d].\n", Cur->line, num_tokens, Prop, pb->pb_graph_node->pb_type->name, pb->pb_graph_node->placement_index); exit(1); } } else if (0 == strcmp(Parent->name, "outputs")) { if (num_tokens != pb->pb_graph_node->num_output_pins[out_port]) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Incorrect # pins %d found for port %s for pb %s[%d].\n", Cur->line, num_tokens, Prop, pb->pb_graph_node->pb_type->name, pb->pb_graph_node->placement_index); exit(1); } } else { if (num_tokens != pb->pb_graph_node->num_clock_pins[clock_port]) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Incorrect # pins %d found for port %s for pb %s[%d].\n", Cur->line, num_tokens, Prop, pb->pb_graph_node->pb_type->name, pb->pb_graph_node->placement_index); exit(1); } } if (0 == strcmp(Parent->name, "inputs") || 0 == strcmp(Parent->name, "clocks")) { if (pb->parent_pb == NULL) { /* top-level, connections are nets to route */ for (i = 0; i < num_tokens; i++) { if (0 == strcmp(Parent->name, "inputs")) rr_node_index = pb->pb_graph_node->input_pins[in_port][i].pin_count_in_cluster; else rr_node_index = pb->pb_graph_node->clock_pins[clock_port][i].pin_count_in_cluster; if (strcmp(pins[i], "open") != 0) { temp_hash = get_hash_entry(vpack_net_hash, pins[i]); if (temp_hash == NULL) { vpr_printf(TIO_MESSAGE_ERROR, ".blif and .net do not match, unknown net %s found in .net file.\n.", pins[i]); } rr_graph[rr_node_index].net_num = temp_hash->index; } rr_node_to_pb_mapping[rr_node_index] = pb; } } else { for (i = 0; i < num_tokens; i++) { if (0 == strcmp(pins[i], "open")) { continue; } interconnect_name = strstr(pins[i], "->"); *interconnect_name = '\0'; interconnect_name += 2; port_name = pins[i]; pin_node = alloc_and_load_port_pin_ptrs_from_string( pb->pb_graph_node->pb_type->parent_mode->interconnect[0].line_num, pb->pb_graph_node->parent_pb_graph_node, pb->pb_graph_node->parent_pb_graph_node->child_pb_graph_nodes[pb->parent_pb->mode], port_name, &num_ptrs, &num_sets, TRUE, TRUE); assert(num_sets == 1 && num_ptrs[0] == 1); if (0 == strcmp(Parent->name, "inputs")) rr_node_index = pb->pb_graph_node->input_pins[in_port][i].pin_count_in_cluster; else rr_node_index = pb->pb_graph_node->clock_pins[clock_port][i].pin_count_in_cluster; rr_graph[rr_node_index].prev_node = pin_node[0][0]->pin_count_in_cluster; rr_node_to_pb_mapping[rr_node_index] = pb; found = FALSE; for (j = 0; j < pin_node[0][0]->num_output_edges; j++) { if (0 == strcmp(interconnect_name, pin_node[0][0]->output_edges[j]->interconnect->name)) { found = TRUE; break; } } for (j = 0; j < num_sets; j++) { free(pin_node[j]); } free(pin_node); free(num_ptrs); if (!found) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown interconnect %s connecting to pin %s.\n", Cur->line, interconnect_name, port_name); exit(1); } } } } if (0 == strcmp(Parent->name, "outputs")) { if (pb->pb_graph_node->pb_type->num_modes == 0) { /* primitives are drivers of nets */ for (i = 0; i < num_tokens; i++) { rr_node_index = pb->pb_graph_node->output_pins[out_port][i].pin_count_in_cluster; if (strcmp(pins[i], "open") != 0) { temp_hash = get_hash_entry(vpack_net_hash, pins[i]); if (temp_hash == NULL) { vpr_printf(TIO_MESSAGE_ERROR, ".blif and .net do not match, unknown net %s found in .net file.\n", pins[i]); } rr_graph[rr_node_index].net_num = temp_hash->index; } rr_node_to_pb_mapping[rr_node_index] = pb; } } else { for (i = 0; i < num_tokens; i++) { if (0 == strcmp(pins[i], "open")) { continue; } interconnect_name = strstr(pins[i], "->"); *interconnect_name = '\0'; interconnect_name += 2; port_name = pins[i]; pin_node = alloc_and_load_port_pin_ptrs_from_string( pb->pb_graph_node->pb_type->modes[pb->mode].interconnect->line_num, pb->pb_graph_node, pb->pb_graph_node->child_pb_graph_nodes[pb->mode], port_name, &num_ptrs, &num_sets, TRUE, TRUE); assert(num_sets == 1 && num_ptrs[0] == 1); rr_node_index = pb->pb_graph_node->output_pins[out_port][i].pin_count_in_cluster; rr_graph[rr_node_index].prev_node = pin_node[0][0]->pin_count_in_cluster; rr_node_to_pb_mapping[rr_node_index] = pb; found = FALSE; for (j = 0; j < pin_node[0][0]->num_output_edges; j++) { if (0 == strcmp(interconnect_name, pin_node[0][0]->output_edges[j]->interconnect->name)) { found = TRUE; break; } } for (j = 0; j < num_sets; j++) { free(pin_node[j]); } free(pin_node); free(num_ptrs); if (!found) { vpr_printf(TIO_MESSAGE_ERROR, "[Line %d] Unknown interconnect %s connecting to pin %s.\n", Cur->line, interconnect_name, port_name); exit(1); } interconnect_name -= 2; *interconnect_name = '-'; } } } FreeTokens(&pins); Prev = Cur; Cur = Cur->next; FreeNode(Prev); } else { Cur = Cur->next; } } } /** * This function updates the nets list and the connections between that list and the complex block */ static void load_external_nets_and_cb(INP int L_num_blocks, INP struct s_block block_list[], INP int ncount, INP struct s_net nlist[], OUTP int *ext_ncount, OUTP struct s_net **ext_nets, INP char **circuit_clocks) { int i, j, k, ipin; struct s_hash **ext_nhash; t_rr_node *rr_graph; t_pb_graph_pin *pb_graph_pin; int *count; int netnum, num_tokens; *ext_ncount = 0; ext_nhash = alloc_hash_table(); /* Assumes that complex block pins are ordered inputs, outputs, globals */ /* Determine the external nets of complex block */ for (i = 0; i < L_num_blocks; i++) { ipin = 0; if (block_list[i].type->pb_type->num_input_pins + block_list[i].type->pb_type->num_output_pins + block_list[i].type->pb_type->num_clock_pins != block_list[i].type->num_pins / block_list[i].type->capacity) { assert(0); } /* First determine nets external to complex blocks */ assert( block_list[i].type->pb_type->num_input_pins + block_list[i].type->pb_type->num_output_pins + block_list[i].type->pb_type->num_clock_pins == block_list[i].type->num_pins / block_list[i].type->capacity); rr_graph = block_list[i].pb->rr_graph; for (j = 0; j < block_list[i].pb->pb_graph_node->num_input_ports; j++) { for (k = 0; k < block_list[i].pb->pb_graph_node->num_input_pins[j]; k++) { pb_graph_pin = &block_list[i].pb->pb_graph_node->input_pins[j][k]; assert(pb_graph_pin->pin_count_in_cluster == ipin); if (rr_graph[pb_graph_pin->pin_count_in_cluster].net_num != OPEN) { block_list[i].nets[ipin] = add_net_to_hash(ext_nhash, nlist[rr_graph[pb_graph_pin->pin_count_in_cluster].net_num].name, ext_ncount); } else { block_list[i].nets[ipin] = OPEN; } ipin++; } } for (j = 0; j < block_list[i].pb->pb_graph_node->num_output_ports; j++) { for (k = 0; k < block_list[i].pb->pb_graph_node->num_output_pins[j]; k++) { pb_graph_pin = &block_list[i].pb->pb_graph_node->output_pins[j][k]; assert(pb_graph_pin->pin_count_in_cluster == ipin); if (rr_graph[pb_graph_pin->pin_count_in_cluster].net_num != OPEN) { block_list[i].nets[ipin] = add_net_to_hash(ext_nhash, nlist[rr_graph[pb_graph_pin->pin_count_in_cluster].net_num].name, ext_ncount); } else { block_list[i].nets[ipin] = OPEN; } ipin++; } } for (j = 0; j < block_list[i].pb->pb_graph_node->num_clock_ports; j++) { for (k = 0; k < block_list[i].pb->pb_graph_node->num_clock_pins[j]; k++) { pb_graph_pin = &block_list[i].pb->pb_graph_node->clock_pins[j][k]; assert(pb_graph_pin->pin_count_in_cluster == ipin); if (rr_graph[pb_graph_pin->pin_count_in_cluster].net_num != OPEN) { block_list[i].nets[ipin] = add_net_to_hash(ext_nhash, nlist[rr_graph[pb_graph_pin->pin_count_in_cluster].net_num].name, ext_ncount); } else { block_list[i].nets[ipin] = OPEN; } ipin++; } } for (j = ipin; j < block_list[i].type->num_pins; j++) { block_list[i].nets[ipin] = OPEN; } } /* alloc and partially load the list of external nets */ (*ext_nets) = alloc_and_init_netlist_from_hash(*ext_ncount, ext_nhash); /* Load global nets */ num_tokens = CountTokens(circuit_clocks); count = (int *)my_calloc(*ext_ncount, sizeof(int)); /* complete load of external nets so that each net points back to the blocks */ for (i = 0; i < L_num_blocks; i++) { ipin = 0; rr_graph = block_list[i].pb->rr_graph; for (j = 0; j < block_list[i].type->num_pins; j++) { netnum = block_list[i].nets[j]; if (netnum != OPEN) { if (RECEIVER == block_list[i].type->class_inf[block_list[i].type->pin_class[j]].type) { count[netnum]++; if(count[netnum] > (*ext_nets)[netnum].num_sinks) { vpr_printf(TIO_MESSAGE_ERROR, "net %s #%d inconsistency, expected %d terminals but encountered %d terminals, it is likely net terminal is disconnected in netlist file.\n", (*ext_nets)[netnum].name, netnum, count[netnum], (*ext_nets)[netnum].num_sinks); exit(1); } (*ext_nets)[netnum].node_block[count[netnum]] = i; (*ext_nets)[netnum].node_block_pin[count[netnum]] = j; (*ext_nets)[netnum].is_global = block_list[i].type->is_global_pin[j]; /* Error check performed later to ensure no mixing of global and non-global signals */ } else { assert( DRIVER == block_list[i].type->class_inf[block_list[i].type->pin_class[j]].type); assert((*ext_nets)[netnum].node_block[0] == OPEN); (*ext_nets)[netnum].node_block[0] = i; (*ext_nets)[netnum].node_block_pin[0] = j; } } } } /* Error check global and non global signals */ for (i = 0; i < *ext_ncount; i++) { for (j = 1; j <= (*ext_nets)[i].num_sinks; j++) { if (block_list[(*ext_nets)[i].node_block[j]].type->is_global_pin[(*ext_nets)[i].node_block_pin[j]] != (*ext_nets)[i].is_global) { vpr_printf(TIO_MESSAGE_ERROR, "Netlist attempts to connect net %s to both global and non-global pins.\n", (*ext_nets)[i].name); exit(1); } } for (j = 0; j < num_tokens; j++) { if (strcmp(circuit_clocks[j], (*ext_nets)[i].name) == 0) { assert((*ext_nets)[i].is_global == TRUE); /* above code should have caught this case, if not, then bug in code */ } } } free(count); free_hash_table(ext_nhash); } /* Recursive function that fills rr_graph of cb with net numbers starting at the given rr_node */ static int count_sinks_internal_cb_rr_graph_net_nums( INP t_rr_node * cur_rr_node, INP t_rr_node * rr_graph) { int i; int count = 0; for (i = 0; i < cur_rr_node->num_edges; i++) { if (&rr_graph[rr_graph[cur_rr_node->edges[i]].prev_node] == cur_rr_node) { if (!(rr_graph[cur_rr_node->edges[i]].net_num == OPEN || rr_graph[cur_rr_node->edges[i]].net_num == cur_rr_node->net_num)) { assert( rr_graph[cur_rr_node->edges[i]].net_num == OPEN || rr_graph[cur_rr_node->edges[i]].net_num == cur_rr_node->net_num); } count += count_sinks_internal_cb_rr_graph_net_nums( &rr_graph[cur_rr_node->edges[i]], rr_graph); } } if (count == 0) { return 1; /* terminal node */ } else { return count; } } /* Recursive function that fills rr_graph of cb with net numbers starting at the given rr_node */ static void load_internal_cb_rr_graph_net_nums(INP t_rr_node * cur_rr_node, INP t_rr_node * rr_graph, INOUTP struct s_net * nets, INOUTP int * curr_net, INOUTP int * curr_sink) { int i; boolean terminal; terminal = TRUE; for (i = 0; i < cur_rr_node->num_edges; i++) { if (&rr_graph[rr_graph[cur_rr_node->edges[i]].prev_node] == cur_rr_node) { /* TODO: If multiple edges to same node (should not happen in reasonable design) this always selects the last edge, need to be smart about it in future (ie. select fastest edge */ assert( rr_graph[cur_rr_node->edges[i]].net_num == OPEN || rr_graph[cur_rr_node->edges[i]].net_num == cur_rr_node->net_num); rr_graph[cur_rr_node->edges[i]].net_num = cur_rr_node->net_num; rr_graph[cur_rr_node->edges[i]].prev_edge = i; load_internal_cb_rr_graph_net_nums(&rr_graph[cur_rr_node->edges[i]], rr_graph, nets, curr_net, curr_sink); terminal = FALSE; } } if (terminal == TRUE) { /* Since the routing node index is known, assign that instead of the more obscure node block */ nets[*curr_net].node_block[*curr_sink] = cur_rr_node->pb_graph_pin->pin_count_in_cluster; nets[*curr_net].node_block_pin[*curr_sink] = OPEN; nets[*curr_net].node_block_port[*curr_sink] = OPEN; (*curr_sink)++; } } /* Load internal cb nets and fill rr_graph of cb with net numbers */ static void load_internal_cb_nets(INOUTP t_pb *top_level, INP t_pb_graph_node *pb_graph_node, INOUTP t_rr_node *rr_graph, INOUTP int * curr_net) { int i, j, k; const t_pb_type *pb_type; int temp, size; struct s_net * nets; pb_type = pb_graph_node->pb_type; nets = top_level->local_nets; temp = 0; if (pb_graph_node->parent_pb_graph_node == NULL) { /* determine nets driven from inputs at top level */ *curr_net = 0; for (i = 0; i < pb_graph_node->num_input_ports; i++) { for (j = 0; j < pb_graph_node->num_input_pins[i]; j++) { if (rr_graph[pb_graph_node->input_pins[i][j].pin_count_in_cluster].net_num != OPEN) { load_internal_cb_rr_graph_net_nums( &rr_graph[pb_graph_node->input_pins[i][j].pin_count_in_cluster], rr_graph, nets, curr_net, &temp); assert(temp == nets[*curr_net].num_sinks); temp = 0; size = strlen(pb_graph_node->pb_type->name) + pb_graph_node->placement_index / 10 + i / 10 + j / 10 + pb_graph_node->input_pins[i][j].pin_count_in_cluster / 10 + 26; nets[*curr_net].name = (char *)my_calloc(size, sizeof(char)); sprintf(nets[*curr_net].name, "%s[%d].input[%d][%d].pin[%d]", pb_graph_node->pb_type->name, pb_graph_node->placement_index, i, j, pb_graph_node->input_pins[i][j].pin_count_in_cluster); (*curr_net)++; } } } for (i = 0; i < pb_graph_node->num_clock_ports; i++) { for (j = 0; j < pb_graph_node->num_clock_pins[i]; j++) { if (rr_graph[pb_graph_node->clock_pins[i][j].pin_count_in_cluster].net_num != OPEN) { load_internal_cb_rr_graph_net_nums( &rr_graph[pb_graph_node->clock_pins[i][j].pin_count_in_cluster], rr_graph, nets, curr_net, &temp); assert(temp == nets[*curr_net].num_sinks); temp = 0; nets[*curr_net].is_global = TRUE; size = strlen(pb_graph_node->pb_type->name) + pb_graph_node->placement_index / 10 + i / 10 + j / 10 + pb_graph_node->clock_pins[i][j].pin_count_in_cluster / 10 + 26; nets[*curr_net].name = (char *)my_calloc(size, sizeof(char)); sprintf(nets[*curr_net].name, "%s[%d].clock[%d][%d].pin[%d]", pb_graph_node->pb_type->name, pb_graph_node->placement_index, i, j, pb_graph_node->clock_pins[i][j].pin_count_in_cluster); (*curr_net)++; } } } } if (pb_type->blif_model != NULL) { /* This is a terminal node so it might drive nets, find and map the rr_graph path for those nets */ for (i = 0; i < pb_graph_node->num_output_ports; i++) { for (j = 0; j < pb_graph_node->num_output_pins[i]; j++) { if (rr_graph[pb_graph_node->output_pins[i][j].pin_count_in_cluster].net_num != OPEN) { load_internal_cb_rr_graph_net_nums( &rr_graph[pb_graph_node->output_pins[i][j].pin_count_in_cluster], rr_graph, nets, curr_net, &temp); assert(temp == nets[*curr_net].num_sinks); temp = 0; size = strlen(pb_graph_node->pb_type->name) + pb_graph_node->placement_index / 10 + i / 10 + j / 10 + pb_graph_node->output_pins[i][j].pin_count_in_cluster / 10 + 26; nets[*curr_net].name = (char *)my_calloc(size, sizeof(char)); sprintf(nets[*curr_net].name, "%s[%d].output[%d][%d].pin[%d]", pb_graph_node->pb_type->name, pb_graph_node->placement_index, i, j, pb_graph_node->output_pins[i][j].pin_count_in_cluster); (*curr_net)++; } } } } else { /* Recurse down to primitives */ for (i = 0; i < pb_type->num_modes; i++) { for (j = 0; j < pb_type->modes[i].num_pb_type_children; j++) { for (k = 0; k < pb_type->modes[i].pb_type_children[j].num_pb; k++) { load_internal_cb_nets(top_level, &pb_graph_node->child_pb_graph_nodes[i][j][k], rr_graph, curr_net); } } } } if (pb_graph_node->parent_pb_graph_node == NULL) { /* at top level */ assert(*curr_net == top_level->num_local_nets); } } /* allocate space to store nets internal to cb two pass algorithm, pass 1 count and allocate # nets, pass 2 determine # sinks */ static void alloc_internal_cb_nets(INOUTP t_pb *top_level, INP t_pb_graph_node *pb_graph_node, INOUTP t_rr_node *rr_graph, INP int pass) { int i, j, k; const t_pb_type *pb_type; int num_sinks; pb_type = pb_graph_node->pb_type; if (pb_graph_node->parent_pb_graph_node == NULL) { /* determine nets driven from inputs at top level */ top_level->num_local_nets = 0; if (pass == 1) top_level->local_nets = NULL; for (i = 0; i < pb_graph_node->num_input_ports; i++) { for (j = 0; j < pb_graph_node->num_input_pins[i]; j++) { if (rr_graph[pb_graph_node->input_pins[i][j].pin_count_in_cluster].net_num != OPEN) { if (pass == 2) { num_sinks = count_sinks_internal_cb_rr_graph_net_nums( &rr_graph[pb_graph_node->input_pins[i][j].pin_count_in_cluster], rr_graph); top_level->local_nets[top_level->num_local_nets].num_sinks = num_sinks; top_level->local_nets[top_level->num_local_nets].node_block = (int *) my_calloc(num_sinks, sizeof(int)); top_level->local_nets[top_level->num_local_nets].node_block_port = (int *) my_calloc(num_sinks, sizeof(int)); top_level->local_nets[top_level->num_local_nets].node_block_pin = (int *) my_calloc(num_sinks, sizeof(int)); } top_level->num_local_nets++; } } } for (i = 0; i < pb_graph_node->num_clock_ports; i++) { for (j = 0; j < pb_graph_node->num_clock_pins[i]; j++) { if (rr_graph[pb_graph_node->clock_pins[i][j].pin_count_in_cluster].net_num != OPEN) { if (pass == 2) { num_sinks = count_sinks_internal_cb_rr_graph_net_nums( &rr_graph[pb_graph_node->clock_pins[i][j].pin_count_in_cluster], rr_graph); top_level->local_nets[top_level->num_local_nets].num_sinks = num_sinks; top_level->local_nets[top_level->num_local_nets].node_block = (int *) my_calloc(num_sinks, sizeof(int)); top_level->local_nets[top_level->num_local_nets].node_block_port = (int *) my_calloc(num_sinks, sizeof(int)); top_level->local_nets[top_level->num_local_nets].node_block_pin = (int *) my_calloc(num_sinks, sizeof(int)); } top_level->num_local_nets++; } } } } if (pb_type->blif_model != NULL) { /* This is a terminal node so it might drive nets, find and map the rr_graph path for those nets */ for (i = 0; i < pb_graph_node->num_output_ports; i++) { for (j = 0; j < pb_graph_node->num_output_pins[i]; j++) { if (rr_graph[pb_graph_node->output_pins[i][j].pin_count_in_cluster].net_num != OPEN) { if (pass == 2) { num_sinks = count_sinks_internal_cb_rr_graph_net_nums( &rr_graph[pb_graph_node->output_pins[i][j].pin_count_in_cluster], rr_graph); top_level->local_nets[top_level->num_local_nets].num_sinks = num_sinks; top_level->local_nets[top_level->num_local_nets].node_block = (int *) my_calloc(num_sinks, sizeof(int)); top_level->local_nets[top_level->num_local_nets].node_block_port = (int *) my_calloc(num_sinks, sizeof(int)); top_level->local_nets[top_level->num_local_nets].node_block_pin = (int *) my_calloc(num_sinks, sizeof(int)); } top_level->num_local_nets++; } } } } else { /* Recurse down to primitives */ for (i = 0; i < pb_type->num_modes; i++) { for (j = 0; j < pb_type->modes[i].num_pb_type_children; j++) { for (k = 0; k < pb_type->modes[i].pb_type_children[j].num_pb; k++) { alloc_internal_cb_nets(top_level, &pb_graph_node->child_pb_graph_nodes[i][j][k], rr_graph, pass); } } } } if (pb_graph_node->parent_pb_graph_node == NULL) { /* at top level */ if (pass == 1) { top_level->local_nets = (struct s_net *)my_calloc(top_level->num_local_nets, sizeof(struct s_net)); } } } static void mark_constant_generators(INP int L_num_blocks, INP struct s_block block_list[], INP int ncount, INOUTP struct s_net nlist[]) { int i; for (i = 0; i < L_num_blocks; i++) { mark_constant_generators_rec(block_list[i].pb, block_list[i].pb->rr_graph, nlist); } } static void mark_constant_generators_rec(INP t_pb *pb, INP t_rr_node *rr_graph, INOUTP struct s_net nlist[]) { int i, j; t_pb_type *pb_type; boolean const_gen; if (pb->pb_graph_node->pb_type->blif_model == NULL) { for (i = 0; i < pb->pb_graph_node->pb_type->modes[pb->mode].num_pb_type_children; i++) { pb_type = &(pb->pb_graph_node->pb_type->modes[pb->mode].pb_type_children[i]); for (j = 0; j < pb_type->num_pb; j++) { if (pb->child_pbs[i][j].name != NULL) { mark_constant_generators_rec(&(pb->child_pbs[i][j]), rr_graph, nlist); } } } } else if (strcmp(pb->pb_graph_node->pb_type->name, "inpad") != 0) { const_gen = TRUE; for (i = 0; i < pb->pb_graph_node->num_input_ports && const_gen == TRUE; i++) { for (j = 0; j < pb->pb_graph_node->num_input_pins[i] && const_gen == TRUE; j++) { if (rr_graph[pb->pb_graph_node->input_pins[i][j].pin_count_in_cluster].net_num != OPEN) { const_gen = FALSE; } } } for (i = 0; i < pb->pb_graph_node->num_clock_ports && const_gen == TRUE; i++) { for (j = 0; j < pb->pb_graph_node->num_clock_pins[i] && const_gen == TRUE; j++) { if (rr_graph[pb->pb_graph_node->clock_pins[i][j].pin_count_in_cluster].net_num != OPEN) { const_gen = FALSE; } } } if (const_gen == TRUE) { vpr_printf(TIO_MESSAGE_INFO, "%s is a constant generator.\n", pb->name); for (i = 0; i < pb->pb_graph_node->num_output_ports; i++) { for (j = 0; j < pb->pb_graph_node->num_output_pins[i]; j++) { if (rr_graph[pb->pb_graph_node->output_pins[i][j].pin_count_in_cluster].net_num != OPEN) { nlist[rr_graph[pb->pb_graph_node->output_pins[i][j].pin_count_in_cluster].net_num].is_const_gen = TRUE; } } } } } } /* Free logical blocks of netlist */ void free_logical_blocks(void) { int iblk, i; t_model_ports *port; struct s_linked_vptr *tvptr, *next; for (iblk = 0; iblk < num_logical_blocks; iblk++) { port = logical_block[iblk].model->inputs; i = 0; while (port) { if (!port->is_clock) { free(logical_block[iblk].input_nets[i]); if (logical_block[iblk].input_net_tnodes) { if (logical_block[iblk].input_net_tnodes[i]) free(logical_block[iblk].input_net_tnodes[i]); } i++; } port = port->next; } if (logical_block[iblk].input_net_tnodes) free(logical_block[iblk].input_net_tnodes); tvptr = logical_block[iblk].packed_molecules; while (tvptr != NULL) { next = tvptr->next; free(tvptr); tvptr = next; } free(logical_block[iblk].input_nets); port = logical_block[iblk].model->outputs; i = 0; while (port) { free(logical_block[iblk].output_nets[i]); if (logical_block[iblk].output_net_tnodes) { if (logical_block[iblk].output_net_tnodes[i]) free(logical_block[iblk].output_net_tnodes[i]); } i++; port = port->next; } if (logical_block[iblk].output_net_tnodes) { free(logical_block[iblk].output_net_tnodes); } free(logical_block[iblk].output_nets); free(logical_block[iblk].name); tvptr = logical_block[iblk].truth_table; while (tvptr != NULL) { if (tvptr->data_vptr) free(tvptr->data_vptr); next = tvptr->next; free(tvptr); tvptr = next; } } free(logical_block); logical_block = NULL; } /* Free logical blocks of netlist */ void free_logical_nets(void) { int inet; for (inet = 0; inet < num_logical_nets; inet++) { free(vpack_net[inet].name); free(vpack_net[inet].node_block); free(vpack_net[inet].node_block_port); free(vpack_net[inet].node_block_pin); } free(vpack_net); vpack_net = NULL; }