/********************************************************************* * The following code is part of the power modelling feature of VTR. * * For support: * http://code.google.com/p/vtr-verilog-to-routing/wiki/Power * * or email: * vtr.power.estimation@gmail.com * * If you are using power estimation for your researach please cite: * * Jeffrey Goeders and Steven Wilton. VersaPower: Power Estimation * for Diverse FPGA Architectures. In International Conference on * Field Programmable Technology, 2012. * ********************************************************************/ /** * This file provides utility functions used by power estimation. */ /************************* INCLUDES *********************************/ #include #include #include #include "vtr_assert.h" #include "vtr_memory.h" #include "power_util.h" #include "globals.h" #include "atom_netlist.h" #include "atom_netlist_utils.h" /************************* GLOBALS **********************************/ /************************* FUNCTION DECLARATIONS*********************/ static void log_msg(t_log* log_ptr, const char* msg); static void init_mux_arch_default(t_mux_arch* mux_arch, int levels, int num_inputs, float transistor_size); static void alloc_and_load_mux_graph_recursive(t_mux_node* node, int num_primary_inputs, int level, int starting_pin_idx); static t_mux_node* alloc_and_load_mux_graph(int num_inputs, int levels); /************************* FUNCTION DEFINITIONS *********************/ void power_zero_usage(t_power_usage* power_usage) { power_usage->dynamic = 0.; power_usage->leakage = 0.; } void power_add_usage(t_power_usage* dest, const t_power_usage* src) { dest->dynamic += src->dynamic; dest->leakage += src->leakage; } void power_scale_usage(t_power_usage* power_usage, float scale_factor) { power_usage->dynamic *= scale_factor; power_usage->leakage *= scale_factor; } float power_sum_usage(t_power_usage* power_usage) { return power_usage->dynamic + power_usage->leakage; } float power_perc_dynamic(t_power_usage* power_usage) { return power_usage->dynamic / power_sum_usage(power_usage); } void power_log_msg(e_power_log_type log_type, const char* msg) { auto& power_ctx = g_vpr_ctx.power(); log_msg(&power_ctx.output->logs[log_type], msg); } const char* transistor_type_name(e_tx_type type) { if (type == NMOS) { return "NMOS"; } else if (type == PMOS) { return "PMOS"; } else { return "Unknown"; } } float pin_dens(t_pb* pb, t_pb_graph_pin* pin, ClusterBlockId iblk) { float density = 0.; auto& cluster_ctx = g_vpr_ctx.clustering(); auto& power_ctx = g_vpr_ctx.mutable_power(); if (pb) { if (cluster_ctx.clb_nlist.block_pb(iblk)->pb_route.count(pin->pin_count_in_cluster)) { AtomNetId net_id = cluster_ctx.clb_nlist.block_pb(iblk)->pb_route[pin->pin_count_in_cluster].atom_net_id; density = power_ctx.atom_net_power[net_id].density; } } return density; } float pin_prob(t_pb* pb, t_pb_graph_pin* pin, ClusterBlockId iblk) { /* Assumed pull-up on unused interconnect */ float prob = 1.; auto& cluster_ctx = g_vpr_ctx.clustering(); auto& power_ctx = g_vpr_ctx.mutable_power(); if (pb) { if (cluster_ctx.clb_nlist.block_pb(iblk)->pb_route.count(pin->pin_count_in_cluster)) { AtomNetId net_id = cluster_ctx.clb_nlist.block_pb(iblk)->pb_route[pin->pin_count_in_cluster].atom_net_id; prob = power_ctx.atom_net_power[net_id].probability; } } return prob; } /** * This function determines the values of the selectors in a static mux, based * on the routing information. * - selector_values: (Return values) selected index at each mux level * - mux_node: * - selected_input_pin: The input index to the multi-level mux that is chosen */ bool mux_find_selector_values(int* selector_values, t_mux_node* mux_node, int selected_input_pin) { if (mux_node->level == 0) { if ((selected_input_pin >= mux_node->starting_pin_idx) && (selected_input_pin <= (mux_node->starting_pin_idx + mux_node->num_inputs))) { selector_values[mux_node->level] = selected_input_pin - mux_node->starting_pin_idx; return true; } } else { int input_idx; for (input_idx = 0; input_idx < mux_node->num_inputs; input_idx++) { if (mux_find_selector_values(selector_values, &mux_node->children[input_idx], selected_input_pin)) { selector_values[mux_node->level] = input_idx; return true; } } } return false; } static void log_msg(t_log* log_ptr, const char* msg) { int msg_idx; /* Check if this message is already in the log */ for (msg_idx = 0; msg_idx < log_ptr->num_messages; msg_idx++) { if (strcmp(log_ptr->messages[msg_idx], msg) == 0) { return; } } if (log_ptr->num_messages <= MAX_LOGS) { log_ptr->num_messages++; log_ptr->messages = (char**)vtr::realloc(log_ptr->messages, log_ptr->num_messages * sizeof(char*)); } else { /* Can't add any more messages */ return; } if (log_ptr->num_messages == (MAX_LOGS + 1)) { const char* full_msg = "\n***LOG IS FULL***\n"; log_ptr->messages[log_ptr->num_messages - 1] = (char*)vtr::calloc(strlen(full_msg) + 1, sizeof(char)); strncpy(log_ptr->messages[log_ptr->num_messages - 1], full_msg, strlen(full_msg) + 1); } else { size_t len = strlen(msg) + 1; log_ptr->messages[log_ptr->num_messages - 1] = (char*)vtr::calloc(len, sizeof(char)); strncpy(log_ptr->messages[log_ptr->num_messages - 1], msg, len); } } /** * Calculates the number of buffer stages required, to achieve a given buffer fanout * final_stage_size: Size of the final inverter in the buffer, relative to a min size * desired_stage_effort: The desired gain between stages, typically 4 */ int power_calc_buffer_num_stages(float final_stage_size, float desired_stage_effort) { int N = 1; if (final_stage_size <= 1.0) { N = 1; } else if (final_stage_size < desired_stage_effort) N = 2; else { N = (int)(log(final_stage_size) / log(desired_stage_effort) + 1); /* We always round down. * Perhaps N+1 would be closer to the desired stage effort, but the delay savings * would likely not be worth the extra power/area */ } return N; } /** * Calculates the required effort of each stage of a buffer * - N: The number of stages of the buffer * - final_stage_size: Size of the final inverter in the buffer, relative to a min size */ float calc_buffer_stage_effort(int N, float final_stage_size) { if (N > 1) return pow((double)final_stage_size, (1.0 / ((double)N - 1))); else return 1.0; } /** * This functions returns the LUT SRAM values from the given logic terms * - LUT_size: The number of LUT inputs * - truth_table: The logic terms saved from the BLIF file */ char* alloc_SRAM_values_from_truth_table(int LUT_size, const AtomNetlist::TruthTable& truth_table) { int num_SRAM_bits = 1 << LUT_size; //SRAM value stored as a string of '0' and '1' characters // Initialize to all zeros char* SRAM_values = (char*)vtr::calloc(num_SRAM_bits + 1, sizeof(char)); SRAM_values[num_SRAM_bits] = '\0'; if (truth_table.empty()) { for (int i = 0; i < num_SRAM_bits; i++) { SRAM_values[i] = '1'; } return SRAM_values; } /* Check if this is an unconnected node - hopefully these will be * ignored by VPR in the future */ if (truth_table.size() == 1) { //Single row check to see if a constant node if (truth_table[0].size() == 1) { if (truth_table[0][0] == vtr::LogicValue::TRUE) { //Mark all the SRAM values as ON for (int i = 0; i < num_SRAM_bits; i++) { SRAM_values[i] = '1'; } return SRAM_values; } else { VTR_ASSERT(truth_table[0][0] == vtr::LogicValue::FALSE); return SRAM_values; } } } auto expanded_truth_table = expand_truth_table(truth_table, LUT_size); std::vector lut_mask = truth_table_to_lut_mask(expanded_truth_table, LUT_size); VTR_ASSERT(lut_mask.size() == (size_t)num_SRAM_bits); //Convert to string for (size_t i = 0; i < lut_mask.size(); ++i) { switch (lut_mask[i]) { case vtr::LogicValue::TRUE: SRAM_values[i] = '1'; break; case vtr::LogicValue::FALSE: SRAM_values[i] = '0'; break; default: VTR_ASSERT(false); } } return SRAM_values; } /* Reduce mux levels for multiplexers that are too small for the preset number of levels */ void mux_arch_fix_levels(t_mux_arch* mux_arch) { while (((1 << mux_arch->levels) > mux_arch->num_inputs) && (mux_arch->levels > 1)) { mux_arch->levels--; } } float clb_net_density(ClusterNetId net_idx) { if (net_idx == ClusterNetId::INVALID()) { return 0.; } else { auto& power_ctx = g_vpr_ctx.power(); return power_ctx.clb_net_power[net_idx].density; } } float clb_net_prob(ClusterNetId net_idx) { if (net_idx == ClusterNetId::INVALID()) { return 0.; } else { auto& power_ctx = g_vpr_ctx.power(); return power_ctx.clb_net_power[net_idx].probability; } } const char* interconnect_type_name(enum e_interconnect type) { switch (type) { case COMPLETE_INTERC: return "complete"; case MUX_INTERC: return "mux"; case DIRECT_INTERC: return "direct"; default: return ""; } } void output_log(t_log* log_ptr, FILE* fp) { int msg_idx; for (msg_idx = 0; msg_idx < log_ptr->num_messages; msg_idx++) { fprintf(fp, "%s\n", log_ptr->messages[msg_idx]); } } void output_logs(FILE* fp, t_log* logs, int num_logs) { int log_idx; for (log_idx = 0; log_idx < num_logs; log_idx++) { if (logs[log_idx].num_messages) { power_print_title(fp, logs[log_idx].name); output_log(&logs[log_idx], fp); fprintf(fp, "\n"); } } } float power_buffer_size_from_logical_effort(float C_load) { auto& power_ctx = g_vpr_ctx.power(); return std::max(1.0f, C_load / power_ctx.commonly_used->INV_1X_C_in / (2 * power_ctx.arch->logical_effort_factor)); } void power_print_title(FILE* fp, const char* title) { int i; const int width = 80; int firsthalf = (width - strlen(title) - 2) / 2; int secondhalf = width - strlen(title) - 2 - firsthalf; for (i = 1; i <= firsthalf; i++) fprintf(fp, "-"); fprintf(fp, " %s ", title); for (i = 1; i <= secondhalf; i++) fprintf(fp, "-"); fprintf(fp, "\n"); } t_mux_arch* power_get_mux_arch(int num_mux_inputs, float transistor_size) { int i; t_power_mux_info* mux_info = nullptr; auto& power_ctx = g_vpr_ctx.power(); /* Find the mux archs for the given transistor size */ std::map::iterator it; it = power_ctx.commonly_used->mux_info.find(transistor_size); if (it == power_ctx.commonly_used->mux_info.end()) { mux_info = new t_power_mux_info; mux_info->mux_arch = nullptr; mux_info->mux_arch_max_size = 0; VTR_ASSERT(power_ctx.commonly_used->mux_info[transistor_size] == nullptr); power_ctx.commonly_used->mux_info[transistor_size] = mux_info; } else { mux_info = it->second; } if (num_mux_inputs > mux_info->mux_arch_max_size) { mux_info->mux_arch = (t_mux_arch*)vtr::realloc(mux_info->mux_arch, (num_mux_inputs + 1) * sizeof(t_mux_arch)); for (i = mux_info->mux_arch_max_size + 1; i <= num_mux_inputs; i++) { init_mux_arch_default(&mux_info->mux_arch[i], 2, i, transistor_size); } mux_info->mux_arch_max_size = num_mux_inputs; } return &mux_info->mux_arch[num_mux_inputs]; } /** * Generates a default multiplexer architecture of given size and number of levels */ static void init_mux_arch_default(t_mux_arch* mux_arch, int levels, int num_inputs, float transistor_size) { mux_arch->levels = levels; mux_arch->num_inputs = num_inputs; mux_arch_fix_levels(mux_arch); mux_arch->transistor_size = transistor_size; mux_arch->mux_graph_head = alloc_and_load_mux_graph(num_inputs, mux_arch->levels); } /** * Allocates a builds a multiplexer graph with given # inputs and levels */ static t_mux_node* alloc_and_load_mux_graph(int num_inputs, int levels) { t_mux_node* node; node = (t_mux_node*)vtr::malloc(sizeof(t_mux_node)); alloc_and_load_mux_graph_recursive(node, num_inputs, levels - 1, 0); return node; } static void alloc_and_load_mux_graph_recursive(t_mux_node* node, int num_primary_inputs, int level, int starting_pin_idx) { int child_idx; int pin_idx = starting_pin_idx; node->num_inputs = (int)(pow(num_primary_inputs, 1 / ((float)level + 1)) + 0.5); node->level = level; node->starting_pin_idx = starting_pin_idx; if (level != 0) { node->children = (t_mux_node*)vtr::calloc(node->num_inputs, sizeof(t_mux_node)); for (child_idx = 0; child_idx < node->num_inputs; child_idx++) { int num_child_pi = num_primary_inputs / node->num_inputs; if (child_idx < (num_primary_inputs % node->num_inputs)) { num_child_pi++; } alloc_and_load_mux_graph_recursive(&node->children[child_idx], num_child_pi, level - 1, pin_idx); pin_idx += num_child_pi; } } } bool power_method_is_transistor_level(e_power_estimation_method estimation_method) { switch (estimation_method) { case POWER_METHOD_AUTO_SIZES: case POWER_METHOD_SPECIFY_SIZES: return true; default: return false; } } bool power_method_is_recursive(e_power_estimation_method method) { switch (method) { case POWER_METHOD_IGNORE: case POWER_METHOD_TOGGLE_PINS: case POWER_METHOD_C_INTERNAL: case POWER_METHOD_ABSOLUTE: return false; case POWER_METHOD_AUTO_SIZES: case POWER_METHOD_SPECIFY_SIZES: case POWER_METHOD_SUM_OF_CHILDREN: return true; case POWER_METHOD_UNDEFINED: default: VTR_ASSERT(0); } // to get rid of warning return false; }