From 9cafb850bdc8ba404add817f90c25faef6ecf9e3 Mon Sep 17 00:00:00 2001 From: Nick Date: Fri, 13 Sep 2019 07:48:05 -0400 Subject: Revert "add /src/gpuwattch formatting" This reverts commit b7776785a18d3f4e6229cd625f92c11b55894b75. --- src/gpuwattch/gpgpu_sim_wrapper.cc | 1432 +++++++++++++++++------------------- 1 file changed, 664 insertions(+), 768 deletions(-) (limited to 'src/gpuwattch/gpgpu_sim_wrapper.cc') diff --git a/src/gpuwattch/gpgpu_sim_wrapper.cc b/src/gpuwattch/gpgpu_sim_wrapper.cc index 2431f65..efb3e6b 100644 --- a/src/gpuwattch/gpgpu_sim_wrapper.cc +++ b/src/gpuwattch/gpgpu_sim_wrapper.cc @@ -7,16 +7,14 @@ // // Redistributions of source code must retain the above copyright notice, this // list of conditions and the following disclaimer. -// Redistributions in binary form must reproduce the above copyright notice, -// this +// Redistributions in binary form must reproduce the above copyright notice, this // list of conditions and the following disclaimer in the documentation and/or // other materials provided with the distribution. // Neither the name of The University of British Columbia nor the names of its // contributors may be used to endorse or promote products derived from this // software without specific prior written permission. // -// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" -// AND +// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND // ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED // WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE // DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE @@ -30,836 +28,734 @@ #include "gpgpu_sim_wrapper.h" #include #define SP_BASE_POWER 0 -#define SFU_BASE_POWER 0 +#define SFU_BASE_POWER 0 -static const char* pwr_cmp_label[] = { - "IBP,", "ICP,", "DCP,", "TCP,", "CCP,", "SHRDP,", - "RFP,", "SPP,", "SFUP,", "FPUP,", "SCHEDP,", "L2CP,", - "MCP,", "NOCP,", "DRAMP,", "PIPEP,", "IDLE_COREP,", "CONST_DYNAMICP"}; + +static const char * pwr_cmp_label[] = {"IBP,", "ICP,", "DCP,", "TCP,", "CCP,", "SHRDP,", "RFP,", "SPP,", + "SFUP,", "FPUP,", "SCHEDP,", "L2CP,", "MCP,", "NOCP,", "DRAMP,", + "PIPEP,", "IDLE_COREP,", "CONST_DYNAMICP"}; enum pwr_cmp_t { - IBP = 0, - ICP, - DCP, - TCP, - CCP, - SHRDP, - RFP, - SPP, - SFUP, - FPUP, - SCHEDP, - L2CP, - MCP, - NOCP, - DRAMP, - PIPEP, - IDLE_COREP, - CONST_DYNAMICP, - NUM_COMPONENTS_MODELLED + IBP=0, + ICP, + DCP, + TCP, + CCP, + SHRDP, + RFP, + SPP, + SFUP, + FPUP, + SCHEDP, + L2CP, + MCP, + NOCP, + DRAMP, + PIPEP, + IDLE_COREP, + CONST_DYNAMICP, + NUM_COMPONENTS_MODELLED }; -gpgpu_sim_wrapper::gpgpu_sim_wrapper(bool power_simulation_enabled, - char* xmlfile) { - kernel_sample_count = 0; - total_sample_count = 0; - - kernel_tot_power = 0; - - num_pwr_cmps = NUM_COMPONENTS_MODELLED; - num_perf_counters = NUM_PERFORMANCE_COUNTERS; - - // Initialize per-component counter/power vectors - avg_max_min_counters init; - kernel_cmp_pwr.resize(NUM_COMPONENTS_MODELLED, init); - kernel_cmp_perf_counters.resize(NUM_PERFORMANCE_COUNTERS, init); - - kernel_power = init; // Per-kernel powers - gpu_tot_power = init; // Global powers - - sample_cmp_pwr.resize(NUM_COMPONENTS_MODELLED, 0); - - sample_perf_counters.resize(NUM_PERFORMANCE_COUNTERS, 0); - initpower_coeff.resize(NUM_PERFORMANCE_COUNTERS, 0); - effpower_coeff.resize(NUM_PERFORMANCE_COUNTERS, 0); - - const_dynamic_power = 0; - proc_power = 0; - - g_power_filename = NULL; - g_power_trace_filename = NULL; - g_metric_trace_filename = NULL; - g_steady_state_tracking_filename = NULL; - xml_filename = xmlfile; - g_power_simulation_enabled = power_simulation_enabled; - g_power_trace_enabled = false; - g_steady_power_levels_enabled = false; - g_power_trace_zlevel = 0; - g_power_per_cycle_dump = false; - gpu_steady_power_deviation = 0; - gpu_steady_min_period = 0; - - gpu_stat_sample_freq = 0; - p = new ParseXML(); - if (g_power_simulation_enabled) { - p->parse(xml_filename); - } - proc = new Processor(p); - power_trace_file = NULL; - metric_trace_file = NULL; - steady_state_tacking_file = NULL; - has_written_avg = false; - init_inst_val = false; + +gpgpu_sim_wrapper::gpgpu_sim_wrapper( bool power_simulation_enabled, char* xmlfile) { + kernel_sample_count=0; + total_sample_count=0; + + kernel_tot_power=0; + + num_pwr_cmps=NUM_COMPONENTS_MODELLED; + num_perf_counters=NUM_PERFORMANCE_COUNTERS; + + // Initialize per-component counter/power vectors + avg_max_min_counters init; + kernel_cmp_pwr.resize(NUM_COMPONENTS_MODELLED, init); + kernel_cmp_perf_counters.resize(NUM_PERFORMANCE_COUNTERS, init); + + kernel_power = init; // Per-kernel powers + gpu_tot_power = init; // Global powers + + sample_cmp_pwr.resize(NUM_COMPONENTS_MODELLED, 0); + + sample_perf_counters.resize(NUM_PERFORMANCE_COUNTERS, 0); + initpower_coeff.resize(NUM_PERFORMANCE_COUNTERS, 0); + effpower_coeff.resize(NUM_PERFORMANCE_COUNTERS, 0); + + const_dynamic_power=0; + proc_power=0; + + g_power_filename = NULL; + g_power_trace_filename = NULL; + g_metric_trace_filename = NULL; + g_steady_state_tracking_filename = NULL; + xml_filename= xmlfile; + g_power_simulation_enabled= power_simulation_enabled; + g_power_trace_enabled= false; + g_steady_power_levels_enabled= false; + g_power_trace_zlevel= 0; + g_power_per_cycle_dump= false; + gpu_steady_power_deviation= 0; + gpu_steady_min_period= 0; + + gpu_stat_sample_freq=0; + p=new ParseXML(); + if (g_power_simulation_enabled){ + p->parse(xml_filename); + } + proc = new Processor(p); + power_trace_file = NULL; + metric_trace_file = NULL; + steady_state_tacking_file = NULL; + has_written_avg=false; + init_inst_val=false; + } -gpgpu_sim_wrapper::~gpgpu_sim_wrapper() {} +gpgpu_sim_wrapper::~gpgpu_sim_wrapper() { } -bool gpgpu_sim_wrapper::sanity_check(double a, double b) { - if (b == 0) - return (abs(a - b) < 0.00001); - else - return (abs(a - b) / abs(b) < 0.00001); +bool gpgpu_sim_wrapper::sanity_check(double a, double b) +{ + if (b == 0) + return (abs(a-b)<0.00001); + else + return (abs(a-b)/abs(b)<0.00001); - return false; + return false; } -void gpgpu_sim_wrapper::init_mcpat( - char* xmlfile, char* powerfilename, char* power_trace_filename, - char* metric_trace_filename, char* steady_state_filename, - bool power_sim_enabled, bool trace_enabled, bool steady_state_enabled, - bool power_per_cycle_dump, double steady_power_deviation, - double steady_min_period, int zlevel, double init_val, - int stat_sample_freq) { - // Write File Headers for (-metrics trace, -power trace) - - reset_counters(); - static bool mcpat_init = true; - - // initialize file name if it is not set - time_t curr_time; - time(&curr_time); - char* date = ctime(&curr_time); - char* s = date; - while (*s) { - if (*s == ' ' || *s == '\t' || *s == ':') *s = '-'; - if (*s == '\n' || *s == '\r') *s = 0; - s++; - } - - if (mcpat_init) { - g_power_filename = powerfilename; - g_power_trace_filename = power_trace_filename; - g_metric_trace_filename = metric_trace_filename; - g_steady_state_tracking_filename = steady_state_filename; - xml_filename = xmlfile; - g_power_simulation_enabled = power_sim_enabled; - g_power_trace_enabled = trace_enabled; - g_steady_power_levels_enabled = steady_state_enabled; - g_power_trace_zlevel = zlevel; - g_power_per_cycle_dump = power_per_cycle_dump; - gpu_steady_power_deviation = steady_power_deviation; - gpu_steady_min_period = steady_min_period; - - gpu_stat_sample_freq = stat_sample_freq; - - // p->sys.total_cycles=gpu_stat_sample_freq*4; - p->sys.total_cycles = gpu_stat_sample_freq; - power_trace_file = NULL; - metric_trace_file = NULL; - steady_state_tacking_file = NULL; - - if (g_power_trace_enabled) { - power_trace_file = gzopen(g_power_trace_filename, "w"); - metric_trace_file = gzopen(g_metric_trace_filename, "w"); - if ((power_trace_file == NULL) || (metric_trace_file == NULL)) { - printf("error - could not open trace files \n"); - exit(1); - } - gzsetparams(power_trace_file, g_power_trace_zlevel, Z_DEFAULT_STRATEGY); - - gzprintf(power_trace_file, "power,"); - for (unsigned i = 0; i < num_pwr_cmps; i++) { - gzprintf(power_trace_file, pwr_cmp_label[i]); - } - gzprintf(power_trace_file, "\n"); - - gzsetparams(metric_trace_file, g_power_trace_zlevel, Z_DEFAULT_STRATEGY); - for (unsigned i = 0; i < num_perf_counters; i++) { - gzprintf(metric_trace_file, perf_count_label[i]); - } - gzprintf(metric_trace_file, "\n"); - - gzclose(power_trace_file); - gzclose(metric_trace_file); - } - if (g_steady_power_levels_enabled) { - steady_state_tacking_file = gzopen(g_steady_state_tracking_filename, "w"); - if ((steady_state_tacking_file == NULL)) { - printf("error - could not open trace files \n"); - exit(1); - } - gzsetparams(steady_state_tacking_file, g_power_trace_zlevel, - Z_DEFAULT_STRATEGY); - gzprintf(steady_state_tacking_file, "start,end,power,IPC,"); - for (unsigned i = 0; i < num_perf_counters; i++) { - gzprintf(steady_state_tacking_file, perf_count_label[i]); - } - gzprintf(steady_state_tacking_file, "\n"); - - gzclose(steady_state_tacking_file); - } +void gpgpu_sim_wrapper::init_mcpat(char* xmlfile, char* powerfilename, char* power_trace_filename,char* metric_trace_filename, + char * steady_state_filename, bool power_sim_enabled,bool trace_enabled, + bool steady_state_enabled,bool power_per_cycle_dump,double steady_power_deviation, + double steady_min_period, int zlevel, double init_val,int stat_sample_freq ){ + // Write File Headers for (-metrics trace, -power trace) + + reset_counters(); + static bool mcpat_init=true; + + // initialize file name if it is not set + time_t curr_time; + time(&curr_time); + char *date = ctime(&curr_time); + char *s = date; + while (*s) { + if (*s == ' ' || *s == '\t' || *s == ':') *s = '-'; + if (*s == '\n' || *s == '\r' ) *s = 0; + s++; + } + + if(mcpat_init){ + g_power_filename = powerfilename; + g_power_trace_filename =power_trace_filename; + g_metric_trace_filename = metric_trace_filename; + g_steady_state_tracking_filename = steady_state_filename; + xml_filename=xmlfile; + g_power_simulation_enabled=power_sim_enabled; + g_power_trace_enabled=trace_enabled; + g_steady_power_levels_enabled=steady_state_enabled; + g_power_trace_zlevel=zlevel; + g_power_per_cycle_dump=power_per_cycle_dump; + gpu_steady_power_deviation=steady_power_deviation; + gpu_steady_min_period=steady_min_period; + + gpu_stat_sample_freq=stat_sample_freq; + + //p->sys.total_cycles=gpu_stat_sample_freq*4; + p->sys.total_cycles=gpu_stat_sample_freq; + power_trace_file = NULL; + metric_trace_file = NULL; + steady_state_tacking_file = NULL; + + + if (g_power_trace_enabled ){ + power_trace_file = gzopen(g_power_trace_filename, "w"); + metric_trace_file = gzopen(g_metric_trace_filename, "w"); + if ((power_trace_file == NULL) || (metric_trace_file == NULL)) { + printf("error - could not open trace files \n"); + exit(1); + } + gzsetparams(power_trace_file, g_power_trace_zlevel, Z_DEFAULT_STRATEGY); + + gzprintf(power_trace_file,"power,"); + for(unsigned i=0; i init; - for (unsigned i = 0; i < num_perf_counters; ++i) { - sample_perf_counters[i] = 0; - kernel_cmp_perf_counters[i] = init; - } - for (unsigned i = 0; i < num_pwr_cmps; ++i) { - sample_cmp_pwr[i] = 0; - kernel_cmp_pwr[i] = init; - } - - // Reset per-kernel counters - kernel_sample_count = 0; - kernel_tot_power = 0; - kernel_power = init; - - return; +void gpgpu_sim_wrapper::reset_counters(){ + + avg_max_min_counters init; + for(unsigned i=0; isys.core[0].gpgpu_clock_gated_lanes = clk_gated_lanes; - p->sys.core[0].total_cycles = tot_cycles; - p->sys.core[0].busy_cycles = busy_cycles; - p->sys.core[0].total_instructions = - tot_inst * p->sys.scaling_coefficients[TOT_INST]; - p->sys.core[0].int_instructions = - int_inst * p->sys.scaling_coefficients[FP_INT]; - p->sys.core[0].fp_instructions = - fp_inst * p->sys.scaling_coefficients[FP_INT]; - p->sys.core[0].load_instructions = load_inst; - p->sys.core[0].store_instructions = store_inst; - p->sys.core[0].committed_instructions = committed_inst; - sample_perf_counters[FP_INT] = int_inst + fp_inst; - sample_perf_counters[TOT_INST] = tot_inst; +void gpgpu_sim_wrapper::set_inst_power(bool clk_gated_lanes, double tot_cycles, double busy_cycles, double tot_inst, double int_inst, double fp_inst, double load_inst, double store_inst, double committed_inst) +{ + p->sys.core[0].gpgpu_clock_gated_lanes = clk_gated_lanes; + p->sys.core[0].total_cycles = tot_cycles; + p->sys.core[0].busy_cycles = busy_cycles; + p->sys.core[0].total_instructions = tot_inst * p->sys.scaling_coefficients[TOT_INST]; + p->sys.core[0].int_instructions = int_inst * p->sys.scaling_coefficients[FP_INT]; + p->sys.core[0].fp_instructions = fp_inst * p->sys.scaling_coefficients[FP_INT]; + p->sys.core[0].load_instructions = load_inst; + p->sys.core[0].store_instructions = store_inst; + p->sys.core[0].committed_instructions = committed_inst; + sample_perf_counters[FP_INT]=int_inst+fp_inst; + sample_perf_counters[TOT_INST]=tot_inst; } -void gpgpu_sim_wrapper::set_regfile_power(double reads, double writes, - double ops) { - p->sys.core[0].int_regfile_reads = - reads * p->sys.scaling_coefficients[REG_RD]; - p->sys.core[0].int_regfile_writes = - writes * p->sys.scaling_coefficients[REG_WR]; - p->sys.core[0].non_rf_operands = - ops * p->sys.scaling_coefficients[NON_REG_OPs]; - sample_perf_counters[REG_RD] = reads; - sample_perf_counters[REG_WR] = writes; - sample_perf_counters[NON_REG_OPs] = ops; +void gpgpu_sim_wrapper::set_regfile_power(double reads, double writes,double ops) +{ + p->sys.core[0].int_regfile_reads = reads * p->sys.scaling_coefficients[REG_RD]; + p->sys.core[0].int_regfile_writes = writes * p->sys.scaling_coefficients[REG_WR]; + p->sys.core[0].non_rf_operands = ops *p->sys.scaling_coefficients[NON_REG_OPs]; + sample_perf_counters[REG_RD]=reads; + sample_perf_counters[REG_WR]=writes; + sample_perf_counters[NON_REG_OPs]=ops; + + + } -void gpgpu_sim_wrapper::set_icache_power(double hits, double misses) { - p->sys.core[0].icache.read_accesses = - hits * p->sys.scaling_coefficients[IC_H] + - misses * p->sys.scaling_coefficients[IC_M]; - p->sys.core[0].icache.read_misses = - misses * p->sys.scaling_coefficients[IC_M]; - sample_perf_counters[IC_H] = hits; - sample_perf_counters[IC_M] = misses; +void gpgpu_sim_wrapper::set_icache_power(double hits, double misses) +{ + p->sys.core[0].icache.read_accesses = hits * p->sys.scaling_coefficients[IC_H]+misses * p->sys.scaling_coefficients[IC_M]; + p->sys.core[0].icache.read_misses = misses * p->sys.scaling_coefficients[IC_M]; + sample_perf_counters[IC_H]=hits; + sample_perf_counters[IC_M]=misses; + + } -void gpgpu_sim_wrapper::set_ccache_power(double hits, double misses) { - p->sys.core[0].ccache.read_accesses = - hits * p->sys.scaling_coefficients[CC_H] + - misses * p->sys.scaling_coefficients[CC_M]; - p->sys.core[0].ccache.read_misses = - misses * p->sys.scaling_coefficients[CC_M]; - sample_perf_counters[CC_H] = hits; - sample_perf_counters[CC_M] = misses; - // TODO: coalescing logic is counted as part of the caches power (this is not - // valid for no-caches architectures) +void gpgpu_sim_wrapper::set_ccache_power(double hits, double misses) +{ + p->sys.core[0].ccache.read_accesses = hits * p->sys.scaling_coefficients[CC_H]+misses * p->sys.scaling_coefficients[CC_M]; + p->sys.core[0].ccache.read_misses = misses * p->sys.scaling_coefficients[CC_M]; + sample_perf_counters[CC_H]=hits; + sample_perf_counters[CC_M]=misses; + // TODO: coalescing logic is counted as part of the caches power (this is not valid for no-caches architectures) + } -void gpgpu_sim_wrapper::set_tcache_power(double hits, double misses) { - p->sys.core[0].tcache.read_accesses = - hits * p->sys.scaling_coefficients[TC_H] + - misses * p->sys.scaling_coefficients[TC_M]; - p->sys.core[0].tcache.read_misses = - misses * p->sys.scaling_coefficients[TC_M]; - sample_perf_counters[TC_H] = hits; - sample_perf_counters[TC_M] = misses; - // TODO: coalescing logic is counted as part of the caches power (this is not - // valid for no-caches architectures) +void gpgpu_sim_wrapper::set_tcache_power(double hits, double misses) +{ + p->sys.core[0].tcache.read_accesses = hits * p->sys.scaling_coefficients[TC_H]+misses * p->sys.scaling_coefficients[TC_M]; + p->sys.core[0].tcache.read_misses = misses* p->sys.scaling_coefficients[TC_M]; + sample_perf_counters[TC_H]=hits; + sample_perf_counters[TC_M]=misses; + // TODO: coalescing logic is counted as part of the caches power (this is not valid for no-caches architectures) } -void gpgpu_sim_wrapper::set_shrd_mem_power(double accesses) { - p->sys.core[0].sharedmemory.read_accesses = - accesses * p->sys.scaling_coefficients[SHRD_ACC]; - sample_perf_counters[SHRD_ACC] = accesses; +void gpgpu_sim_wrapper::set_shrd_mem_power(double accesses) +{ + p->sys.core[0].sharedmemory.read_accesses = accesses * p->sys.scaling_coefficients[SHRD_ACC]; + sample_perf_counters[SHRD_ACC]=accesses; + + } -void gpgpu_sim_wrapper::set_l1cache_power(double read_hits, double read_misses, - double write_hits, - double write_misses) { - p->sys.core[0].dcache.read_accesses = - read_hits * p->sys.scaling_coefficients[DC_RH] + - read_misses * p->sys.scaling_coefficients[DC_RM]; - p->sys.core[0].dcache.read_misses = - read_misses * p->sys.scaling_coefficients[DC_RM]; - p->sys.core[0].dcache.write_accesses = - write_hits * p->sys.scaling_coefficients[DC_WH] + - write_misses * p->sys.scaling_coefficients[DC_WM]; - p->sys.core[0].dcache.write_misses = - write_misses * p->sys.scaling_coefficients[DC_WM]; - sample_perf_counters[DC_RH] = read_hits; - sample_perf_counters[DC_RM] = read_misses; - sample_perf_counters[DC_WH] = write_hits; - sample_perf_counters[DC_WM] = write_misses; - // TODO: coalescing logic is counted as part of the caches power (this is not - // valid for no-caches architectures) +void gpgpu_sim_wrapper::set_l1cache_power(double read_hits, double read_misses, double write_hits, double write_misses) +{ + p->sys.core[0].dcache.read_accesses = read_hits * p->sys.scaling_coefficients[DC_RH] +read_misses * p->sys.scaling_coefficients[DC_RM]; + p->sys.core[0].dcache.read_misses = read_misses * p->sys.scaling_coefficients[DC_RM]; + p->sys.core[0].dcache.write_accesses = write_hits * p->sys.scaling_coefficients[DC_WH]+write_misses * p->sys.scaling_coefficients[DC_WM]; + p->sys.core[0].dcache.write_misses = write_misses * p->sys.scaling_coefficients[DC_WM]; + sample_perf_counters[DC_RH]=read_hits; + sample_perf_counters[DC_RM]=read_misses; + sample_perf_counters[DC_WH]=write_hits; + sample_perf_counters[DC_WM]=write_misses; + // TODO: coalescing logic is counted as part of the caches power (this is not valid for no-caches architectures) + + + } -void gpgpu_sim_wrapper::set_l2cache_power(double read_hits, double read_misses, - double write_hits, - double write_misses) { - p->sys.l2.total_accesses = read_hits * p->sys.scaling_coefficients[L2_RH] + - read_misses * p->sys.scaling_coefficients[L2_RM] + - write_hits * p->sys.scaling_coefficients[L2_WH] + - write_misses * p->sys.scaling_coefficients[L2_WM]; - p->sys.l2.read_accesses = read_hits * p->sys.scaling_coefficients[L2_RH] + - read_misses * p->sys.scaling_coefficients[L2_RM]; - p->sys.l2.write_accesses = write_hits * p->sys.scaling_coefficients[L2_WH] + - write_misses * p->sys.scaling_coefficients[L2_WM]; - p->sys.l2.read_hits = read_hits * p->sys.scaling_coefficients[L2_RH]; - p->sys.l2.read_misses = read_misses * p->sys.scaling_coefficients[L2_RM]; - p->sys.l2.write_hits = write_hits * p->sys.scaling_coefficients[L2_WH]; - p->sys.l2.write_misses = write_misses * p->sys.scaling_coefficients[L2_WM]; - sample_perf_counters[L2_RH] = read_hits; - sample_perf_counters[L2_RM] = read_misses; - sample_perf_counters[L2_WH] = write_hits; - sample_perf_counters[L2_WM] = write_misses; +void gpgpu_sim_wrapper::set_l2cache_power(double read_hits, double read_misses, double write_hits, double write_misses) +{ + p->sys.l2.total_accesses = read_hits* p->sys.scaling_coefficients[L2_RH]+read_misses * p->sys.scaling_coefficients[L2_RM]+ write_hits * p->sys.scaling_coefficients[L2_WH]+write_misses * p->sys.scaling_coefficients[L2_WM]; + p->sys.l2.read_accesses = read_hits* p->sys.scaling_coefficients[L2_RH]+read_misses* p->sys.scaling_coefficients[L2_RM]; + p->sys.l2.write_accesses = write_hits * p->sys.scaling_coefficients[L2_WH]+write_misses * p->sys.scaling_coefficients[L2_WM]; + p->sys.l2.read_hits = read_hits * p->sys.scaling_coefficients[L2_RH]; + p->sys.l2.read_misses = read_misses * p->sys.scaling_coefficients[L2_RM]; + p->sys.l2.write_hits =write_hits * p->sys.scaling_coefficients[L2_WH]; + p->sys.l2.write_misses = write_misses * p->sys.scaling_coefficients[L2_WM]; + sample_perf_counters[L2_RH]=read_hits; + sample_perf_counters[L2_RM]=read_misses; + sample_perf_counters[L2_WH]=write_hits; + sample_perf_counters[L2_WM]=write_misses; } -void gpgpu_sim_wrapper::set_idle_core_power(double num_idle_core) { - p->sys.num_idle_cores = num_idle_core; - sample_perf_counters[IDLE_CORE_N] = num_idle_core; +void gpgpu_sim_wrapper::set_idle_core_power(double num_idle_core) +{ + p->sys.num_idle_cores = num_idle_core; + sample_perf_counters[IDLE_CORE_N]=num_idle_core; } -void gpgpu_sim_wrapper::set_duty_cycle_power(double duty_cycle) { - p->sys.core[0].pipeline_duty_cycle = - duty_cycle * p->sys.scaling_coefficients[PIPE_A]; - sample_perf_counters[PIPE_A] = duty_cycle; +void gpgpu_sim_wrapper::set_duty_cycle_power(double duty_cycle) +{ + p->sys.core[0].pipeline_duty_cycle = duty_cycle * p->sys.scaling_coefficients[PIPE_A]; + sample_perf_counters[PIPE_A]=duty_cycle; + } -void gpgpu_sim_wrapper::set_mem_ctrl_power(double reads, double writes, - double dram_precharge) { - p->sys.mc.memory_accesses = reads * p->sys.scaling_coefficients[MEM_RD] + - writes * p->sys.scaling_coefficients[MEM_WR]; - p->sys.mc.memory_reads = reads * p->sys.scaling_coefficients[MEM_RD]; - p->sys.mc.memory_writes = writes * p->sys.scaling_coefficients[MEM_WR]; - p->sys.mc.dram_pre = dram_precharge * p->sys.scaling_coefficients[MEM_PRE]; - sample_perf_counters[MEM_RD] = reads; - sample_perf_counters[MEM_WR] = writes; - sample_perf_counters[MEM_PRE] = dram_precharge; +void gpgpu_sim_wrapper::set_mem_ctrl_power(double reads, double writes, double dram_precharge) +{ + p->sys.mc.memory_accesses = reads * p->sys.scaling_coefficients[MEM_RD]+ writes * p->sys.scaling_coefficients[MEM_WR]; + p->sys.mc.memory_reads = reads *p->sys.scaling_coefficients[MEM_RD]; + p->sys.mc.memory_writes = writes*p->sys.scaling_coefficients[MEM_WR]; + p->sys.mc.dram_pre = dram_precharge*p->sys.scaling_coefficients[MEM_PRE]; + sample_perf_counters[MEM_RD]=reads; + sample_perf_counters[MEM_WR]=writes; + sample_perf_counters[MEM_PRE]=dram_precharge; + } -void gpgpu_sim_wrapper::set_exec_unit_power(double fpu_accesses, - double ialu_accesses, - double sfu_accesses) { - p->sys.core[0].fpu_accesses = - fpu_accesses * p->sys.scaling_coefficients[FPU_ACC]; - // Integer ALU (not present in Tesla) - p->sys.core[0].ialu_accesses = - ialu_accesses * p->sys.scaling_coefficients[SP_ACC]; - // Sfu accesses - p->sys.core[0].mul_accesses = - sfu_accesses * p->sys.scaling_coefficients[SFU_ACC]; - - sample_perf_counters[SP_ACC] = ialu_accesses; - sample_perf_counters[SFU_ACC] = sfu_accesses; - sample_perf_counters[FPU_ACC] = fpu_accesses; +void gpgpu_sim_wrapper::set_exec_unit_power(double fpu_accesses, double ialu_accesses, double sfu_accesses) +{ + p->sys.core[0].fpu_accesses = fpu_accesses*p->sys.scaling_coefficients[FPU_ACC]; + //Integer ALU (not present in Tesla) + p->sys.core[0].ialu_accesses = ialu_accesses*p->sys.scaling_coefficients[SP_ACC]; + //Sfu accesses + p->sys.core[0].mul_accesses = sfu_accesses*p->sys.scaling_coefficients[SFU_ACC]; + + sample_perf_counters[SP_ACC]=ialu_accesses; + sample_perf_counters[SFU_ACC]=sfu_accesses; + sample_perf_counters[FPU_ACC]=fpu_accesses; + + } -void gpgpu_sim_wrapper::set_active_lanes_power(double sp_avg_active_lane, - double sfu_avg_active_lane) { - p->sys.core[0].sp_average_active_lanes = sp_avg_active_lane; - p->sys.core[0].sfu_average_active_lanes = sfu_avg_active_lane; +void gpgpu_sim_wrapper::set_active_lanes_power(double sp_avg_active_lane, double sfu_avg_active_lane) +{ + p->sys.core[0].sp_average_active_lanes = sp_avg_active_lane; + p->sys.core[0].sfu_average_active_lanes = sfu_avg_active_lane; } -void gpgpu_sim_wrapper::set_NoC_power(double noc_tot_reads, - double noc_tot_writes) { - p->sys.NoC[0].total_accesses = - noc_tot_reads * p->sys.scaling_coefficients[NOC_A] + - noc_tot_writes * p->sys.scaling_coefficients[NOC_A]; - sample_perf_counters[NOC_A] = noc_tot_reads + noc_tot_writes; +void gpgpu_sim_wrapper::set_NoC_power(double noc_tot_reads, double noc_tot_writes ) +{ + p->sys.NoC[0].total_accesses = noc_tot_reads * p->sys.scaling_coefficients[NOC_A] + noc_tot_writes * p->sys.scaling_coefficients[NOC_A]; + sample_perf_counters[NOC_A]=noc_tot_reads+noc_tot_writes; } -void gpgpu_sim_wrapper::power_metrics_calculations() { - total_sample_count++; - kernel_sample_count++; - - // Current sample power - double sample_power = - proc->rt_power.readOp.dynamic + sample_cmp_pwr[CONST_DYNAMICP]; - - // Average power - // Previous + new + constant dynamic power (e.g., dynamic clocking power) - kernel_tot_power += sample_power; - kernel_power.avg = kernel_tot_power / kernel_sample_count; - for (unsigned ind = 0; ind < num_pwr_cmps; ++ind) { - kernel_cmp_pwr[ind].avg += (double)sample_cmp_pwr[ind]; - } - - for (unsigned ind = 0; ind < num_perf_counters; ++ind) { - kernel_cmp_perf_counters[ind].avg += (double)sample_perf_counters[ind]; - } - - // Max Power - if (sample_power > kernel_power.max) { - kernel_power.max = sample_power; - for (unsigned ind = 0; ind < num_pwr_cmps; ++ind) { - kernel_cmp_pwr[ind].max = (double)sample_cmp_pwr[ind]; - } - for (unsigned ind = 0; ind < num_perf_counters; ++ind) { - kernel_cmp_perf_counters[ind].max = sample_perf_counters[ind]; - } - } - // Min Power - if (sample_power < kernel_power.min || (kernel_power.min == 0)) { - kernel_power.min = sample_power; - for (unsigned ind = 0; ind < num_pwr_cmps; ++ind) { - kernel_cmp_pwr[ind].min = (double)sample_cmp_pwr[ind]; - } - for (unsigned ind = 0; ind < num_perf_counters; ++ind) { - kernel_cmp_perf_counters[ind].min = sample_perf_counters[ind]; - } - } - - gpu_tot_power.avg = (gpu_tot_power.avg + sample_power); - gpu_tot_power.max = - (sample_power > gpu_tot_power.max) ? sample_power : gpu_tot_power.max; - gpu_tot_power.min = - ((sample_power < gpu_tot_power.min) || (gpu_tot_power.min == 0)) - ? sample_power - : gpu_tot_power.min; +void gpgpu_sim_wrapper::power_metrics_calculations() +{ + total_sample_count++; + kernel_sample_count++; + + // Current sample power + double sample_power = proc->rt_power.readOp.dynamic + sample_cmp_pwr[CONST_DYNAMICP]; + + // Average power + // Previous + new + constant dynamic power (e.g., dynamic clocking power) + kernel_tot_power += sample_power; + kernel_power.avg = kernel_tot_power / kernel_sample_count; + for(unsigned ind=0; ind kernel_power.max){ + kernel_power.max = sample_power; + for(unsigned ind=0; ind gpu_tot_power.max) ? sample_power : gpu_tot_power.max; + gpu_tot_power.min = ((sample_power < gpu_tot_power.min) || (gpu_tot_power.min == 0)) ? sample_power : gpu_tot_power.min; + } -void gpgpu_sim_wrapper::print_trace_files() { - open_files(); - for (unsigned i = 0; i < num_perf_counters; ++i) { - gzprintf(metric_trace_file, "%f,", sample_perf_counters[i]); - } - gzprintf(metric_trace_file, "\n"); +void gpgpu_sim_wrapper::print_trace_files() +{ + open_files(); - gzprintf(power_trace_file, "%f,", proc_power); - for (unsigned i = 0; i < num_pwr_cmps; ++i) { - gzprintf(power_trace_file, "%f,", sample_cmp_pwr[i]); - } - gzprintf(power_trace_file, "\n"); + for(unsigned i=0; icores[0]->get_coefficient_fpint_insts(); - effpower_coeff[FP_INT] = - initpower_coeff[FP_INT] * p->sys.scaling_coefficients[FP_INT]; - - initpower_coeff[TOT_INST] = proc->cores[0]->get_coefficient_tot_insts(); - effpower_coeff[TOT_INST] = - initpower_coeff[TOT_INST] * p->sys.scaling_coefficients[TOT_INST]; - - initpower_coeff[REG_RD] = - proc->cores[0]->get_coefficient_regreads_accesses() * - (proc->cores[0]->exu->rf_fu_clockRate / proc->cores[0]->exu->clockRate); - initpower_coeff[REG_WR] = - proc->cores[0]->get_coefficient_regwrites_accesses() * - (proc->cores[0]->exu->rf_fu_clockRate / proc->cores[0]->exu->clockRate); - initpower_coeff[NON_REG_OPs] = - proc->cores[0]->get_coefficient_noregfileops_accesses() * - (proc->cores[0]->exu->rf_fu_clockRate / proc->cores[0]->exu->clockRate); - effpower_coeff[REG_RD] = - initpower_coeff[REG_RD] * p->sys.scaling_coefficients[REG_RD]; - effpower_coeff[REG_WR] = - initpower_coeff[REG_WR] * p->sys.scaling_coefficients[REG_WR]; - effpower_coeff[NON_REG_OPs] = - initpower_coeff[NON_REG_OPs] * p->sys.scaling_coefficients[NON_REG_OPs]; - - initpower_coeff[IC_H] = proc->cores[0]->get_coefficient_icache_hits(); - initpower_coeff[IC_M] = proc->cores[0]->get_coefficient_icache_misses(); - effpower_coeff[IC_H] = - initpower_coeff[IC_H] * p->sys.scaling_coefficients[IC_H]; - effpower_coeff[IC_M] = - initpower_coeff[IC_M] * p->sys.scaling_coefficients[IC_M]; - - initpower_coeff[CC_H] = (proc->cores[0]->get_coefficient_ccache_readhits() + - proc->get_coefficient_readcoalescing()); - initpower_coeff[CC_M] = (proc->cores[0]->get_coefficient_ccache_readmisses() + - proc->get_coefficient_readcoalescing()); - effpower_coeff[CC_H] = - initpower_coeff[CC_H] * p->sys.scaling_coefficients[CC_H]; - effpower_coeff[CC_M] = - initpower_coeff[CC_M] * p->sys.scaling_coefficients[CC_M]; - - initpower_coeff[TC_H] = (proc->cores[0]->get_coefficient_tcache_readhits() + - proc->get_coefficient_readcoalescing()); - initpower_coeff[TC_M] = (proc->cores[0]->get_coefficient_tcache_readmisses() + - proc->get_coefficient_readcoalescing()); - effpower_coeff[TC_H] = - initpower_coeff[TC_H] * p->sys.scaling_coefficients[TC_H]; - effpower_coeff[TC_M] = - initpower_coeff[TC_M] * p->sys.scaling_coefficients[TC_M]; - - initpower_coeff[SHRD_ACC] = - proc->cores[0]->get_coefficient_sharedmemory_readhits(); - effpower_coeff[SHRD_ACC] = - initpower_coeff[SHRD_ACC] * p->sys.scaling_coefficients[SHRD_ACC]; - - initpower_coeff[DC_RH] = (proc->cores[0]->get_coefficient_dcache_readhits() + - proc->get_coefficient_readcoalescing()); - initpower_coeff[DC_RM] = - (proc->cores[0]->get_coefficient_dcache_readmisses() + - proc->get_coefficient_readcoalescing()); - initpower_coeff[DC_WH] = (proc->cores[0]->get_coefficient_dcache_writehits() + - proc->get_coefficient_writecoalescing()); - initpower_coeff[DC_WM] = - (proc->cores[0]->get_coefficient_dcache_writemisses() + - proc->get_coefficient_writecoalescing()); - effpower_coeff[DC_RH] = - initpower_coeff[DC_RH] * p->sys.scaling_coefficients[DC_RH]; - effpower_coeff[DC_RM] = - initpower_coeff[DC_RM] * p->sys.scaling_coefficients[DC_RM]; - effpower_coeff[DC_WH] = - initpower_coeff[DC_WH] * p->sys.scaling_coefficients[DC_WH]; - effpower_coeff[DC_WM] = - initpower_coeff[DC_WM] * p->sys.scaling_coefficients[DC_WM]; - - initpower_coeff[L2_RH] = proc->get_coefficient_l2_read_hits(); - initpower_coeff[L2_RM] = proc->get_coefficient_l2_read_misses(); - initpower_coeff[L2_WH] = proc->get_coefficient_l2_write_hits(); - initpower_coeff[L2_WM] = proc->get_coefficient_l2_write_misses(); - effpower_coeff[L2_RH] = - initpower_coeff[L2_RH] * p->sys.scaling_coefficients[L2_RH]; - effpower_coeff[L2_RM] = - initpower_coeff[L2_RM] * p->sys.scaling_coefficients[L2_RM]; - effpower_coeff[L2_WH] = - initpower_coeff[L2_WH] * p->sys.scaling_coefficients[L2_WH]; - effpower_coeff[L2_WM] = - initpower_coeff[L2_WM] * p->sys.scaling_coefficients[L2_WM]; - - initpower_coeff[IDLE_CORE_N] = - p->sys.idle_core_power * proc->cores[0]->executionTime; - effpower_coeff[IDLE_CORE_N] = - initpower_coeff[IDLE_CORE_N] * p->sys.scaling_coefficients[IDLE_CORE_N]; - - initpower_coeff[PIPE_A] = proc->cores[0]->get_coefficient_duty_cycle(); - effpower_coeff[PIPE_A] = - initpower_coeff[PIPE_A] * p->sys.scaling_coefficients[PIPE_A]; - - initpower_coeff[MEM_RD] = proc->get_coefficient_mem_reads(); - initpower_coeff[MEM_WR] = proc->get_coefficient_mem_writes(); - initpower_coeff[MEM_PRE] = proc->get_coefficient_mem_pre(); - effpower_coeff[MEM_RD] = - initpower_coeff[MEM_RD] * p->sys.scaling_coefficients[MEM_RD]; - effpower_coeff[MEM_WR] = - initpower_coeff[MEM_WR] * p->sys.scaling_coefficients[MEM_WR]; - effpower_coeff[MEM_PRE] = - initpower_coeff[MEM_PRE] * p->sys.scaling_coefficients[MEM_PRE]; - - initpower_coeff[SP_ACC] = - proc->cores[0]->get_coefficient_ialu_accesses() * - (proc->cores[0]->exu->rf_fu_clockRate / proc->cores[0]->exu->clockRate); - ; - initpower_coeff[SFU_ACC] = proc->cores[0]->get_coefficient_sfu_accesses(); - initpower_coeff[FPU_ACC] = proc->cores[0]->get_coefficient_fpu_accesses(); - - effpower_coeff[SP_ACC] = - initpower_coeff[SP_ACC] * p->sys.scaling_coefficients[SP_ACC]; - effpower_coeff[SFU_ACC] = - initpower_coeff[SFU_ACC] * p->sys.scaling_coefficients[SFU_ACC]; - effpower_coeff[FPU_ACC] = - initpower_coeff[FPU_ACC] * p->sys.scaling_coefficients[FPU_ACC]; - - initpower_coeff[NOC_A] = proc->get_coefficient_noc_accesses(); - effpower_coeff[NOC_A] = - initpower_coeff[NOC_A] * p->sys.scaling_coefficients[NOC_A]; - - const_dynamic_power = - proc->get_const_dynamic_power() / (proc->cores[0]->executionTime); - - for (unsigned i = 0; i < num_perf_counters; i++) { - initpower_coeff[i] /= (proc->cores[0]->executionTime); - effpower_coeff[i] /= (proc->cores[0]->executionTime); - } } -void gpgpu_sim_wrapper::update_components_power() { - update_coefficients(); - - proc_power = proc->rt_power.readOp.dynamic; - - sample_cmp_pwr[IBP] = - (proc->cores[0]->ifu->IB->rt_power.readOp.dynamic + - proc->cores[0]->ifu->IB->rt_power.writeOp.dynamic + - proc->cores[0]->ifu->ID_misc->rt_power.readOp.dynamic + - proc->cores[0]->ifu->ID_operand->rt_power.readOp.dynamic + - proc->cores[0]->ifu->ID_inst->rt_power.readOp.dynamic) / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[ICP] = proc->cores[0]->ifu->icache.rt_power.readOp.dynamic / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[DCP] = proc->cores[0]->lsu->dcache.rt_power.readOp.dynamic / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[TCP] = proc->cores[0]->lsu->tcache.rt_power.readOp.dynamic / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[CCP] = proc->cores[0]->lsu->ccache.rt_power.readOp.dynamic / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[SHRDP] = - proc->cores[0]->lsu->sharedmemory.rt_power.readOp.dynamic / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[RFP] = - (proc->cores[0]->exu->rfu->rt_power.readOp.dynamic / - (proc->cores[0]->executionTime)) * - (proc->cores[0]->exu->rf_fu_clockRate / proc->cores[0]->exu->clockRate); - - sample_cmp_pwr[SPP] = - (proc->cores[0]->exu->exeu->rt_power.readOp.dynamic / - (proc->cores[0]->executionTime)) * - (proc->cores[0]->exu->rf_fu_clockRate / proc->cores[0]->exu->clockRate); - - sample_cmp_pwr[SFUP] = (proc->cores[0]->exu->mul->rt_power.readOp.dynamic / - (proc->cores[0]->executionTime)); - - sample_cmp_pwr[FPUP] = (proc->cores[0]->exu->fp_u->rt_power.readOp.dynamic / - (proc->cores[0]->executionTime)); - - sample_cmp_pwr[SCHEDP] = proc->cores[0]->exu->scheu->rt_power.readOp.dynamic / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[L2CP] = (proc->XML->sys.number_of_L2s > 0) - ? proc->l2array[0]->rt_power.readOp.dynamic / - (proc->cores[0]->executionTime) - : 0; - - sample_cmp_pwr[MCP] = (proc->mc->rt_power.readOp.dynamic - - proc->mc->dram->rt_power.readOp.dynamic) / - (proc->cores[0]->executionTime); - - sample_cmp_pwr[NOCP] = - proc->nocs[0]->rt_power.readOp.dynamic / (proc->cores[0]->executionTime); - - sample_cmp_pwr[DRAMP] = - proc->mc->dram->rt_power.readOp.dynamic / (proc->cores[0]->executionTime); - - sample_cmp_pwr[PIPEP] = - proc->cores[0]->Pipeline_energy / (proc->cores[0]->executionTime); - - sample_cmp_pwr[IDLE_COREP] = - proc->cores[0]->IdleCoreEnergy / (proc->cores[0]->executionTime); - - // This constant dynamic power (e.g., clock power) part is estimated via - // regression model. - sample_cmp_pwr[CONST_DYNAMICP] = 0; - double cnst_dyn = - proc->get_const_dynamic_power() / (proc->cores[0]->executionTime); - // If the regression scaling term is greater than the recorded constant - // dynamic power - // then use the difference (other portion already added to dynamic power). - // Else, - // all the constant dynamic power is accounted for, add nothing. - if (p->sys.scaling_coefficients[CONST_DYNAMICN] > cnst_dyn) - sample_cmp_pwr[CONST_DYNAMICP] = - (p->sys.scaling_coefficients[CONST_DYNAMICN] - cnst_dyn); - - proc_power += sample_cmp_pwr[CONST_DYNAMICP]; - - double sum_pwr_cmp = 0; - for (unsigned i = 0; i < num_pwr_cmps; i++) { - sum_pwr_cmp += sample_cmp_pwr[i]; - } - bool check = false; - check = sanity_check(sum_pwr_cmp, proc_power); - assert("Total Power does not equal the sum of the components\n" && (check)); +void gpgpu_sim_wrapper::update_coefficients() +{ + + initpower_coeff[FP_INT]=proc->cores[0]->get_coefficient_fpint_insts(); + effpower_coeff[FP_INT]=initpower_coeff[FP_INT] * p->sys.scaling_coefficients[FP_INT]; + + initpower_coeff[TOT_INST]=proc->cores[0]->get_coefficient_tot_insts(); + effpower_coeff[TOT_INST]=initpower_coeff[TOT_INST] * p->sys.scaling_coefficients[TOT_INST]; + + initpower_coeff[REG_RD]=proc->cores[0]->get_coefficient_regreads_accesses()*(proc->cores[0]->exu->rf_fu_clockRate/proc->cores[0]->exu->clockRate); + initpower_coeff[REG_WR]=proc->cores[0]->get_coefficient_regwrites_accesses()*(proc->cores[0]->exu->rf_fu_clockRate/proc->cores[0]->exu->clockRate); + initpower_coeff[NON_REG_OPs]=proc->cores[0]->get_coefficient_noregfileops_accesses()*(proc->cores[0]->exu->rf_fu_clockRate/proc->cores[0]->exu->clockRate); + effpower_coeff[REG_RD]=initpower_coeff[REG_RD]*p->sys.scaling_coefficients[REG_RD]; + effpower_coeff[REG_WR]=initpower_coeff[REG_WR]*p->sys.scaling_coefficients[REG_WR]; + effpower_coeff[NON_REG_OPs]=initpower_coeff[NON_REG_OPs]*p->sys.scaling_coefficients[NON_REG_OPs]; + + initpower_coeff[IC_H]=proc->cores[0]->get_coefficient_icache_hits(); + initpower_coeff[IC_M]=proc->cores[0]->get_coefficient_icache_misses(); + effpower_coeff[IC_H]=initpower_coeff[IC_H]*p->sys.scaling_coefficients[IC_H]; + effpower_coeff[IC_M]=initpower_coeff[IC_M]*p->sys.scaling_coefficients[IC_M]; + + initpower_coeff[CC_H]=(proc->cores[0]->get_coefficient_ccache_readhits()+proc->get_coefficient_readcoalescing()); + initpower_coeff[CC_M]=(proc->cores[0]->get_coefficient_ccache_readmisses()+proc->get_coefficient_readcoalescing()); + effpower_coeff[CC_H]=initpower_coeff[CC_H]*p->sys.scaling_coefficients[CC_H]; + effpower_coeff[CC_M]=initpower_coeff[CC_M]*p->sys.scaling_coefficients[CC_M]; + + initpower_coeff[TC_H]=(proc->cores[0]->get_coefficient_tcache_readhits()+proc->get_coefficient_readcoalescing()); + initpower_coeff[TC_M]=(proc->cores[0]->get_coefficient_tcache_readmisses()+proc->get_coefficient_readcoalescing()); + effpower_coeff[TC_H]=initpower_coeff[TC_H]*p->sys.scaling_coefficients[TC_H]; + effpower_coeff[TC_M]=initpower_coeff[TC_M]*p->sys.scaling_coefficients[TC_M]; + + initpower_coeff[SHRD_ACC]=proc->cores[0]->get_coefficient_sharedmemory_readhits(); + effpower_coeff[SHRD_ACC]=initpower_coeff[SHRD_ACC]*p->sys.scaling_coefficients[SHRD_ACC]; + + initpower_coeff[DC_RH]=(proc->cores[0]->get_coefficient_dcache_readhits() + proc->get_coefficient_readcoalescing()); + initpower_coeff[DC_RM]=(proc->cores[0]->get_coefficient_dcache_readmisses() + proc->get_coefficient_readcoalescing()); + initpower_coeff[DC_WH]=(proc->cores[0]->get_coefficient_dcache_writehits() + proc->get_coefficient_writecoalescing()); + initpower_coeff[DC_WM]=(proc->cores[0]->get_coefficient_dcache_writemisses() + proc->get_coefficient_writecoalescing()); + effpower_coeff[DC_RH]=initpower_coeff[DC_RH]*p->sys.scaling_coefficients[DC_RH]; + effpower_coeff[DC_RM]=initpower_coeff[DC_RM]*p->sys.scaling_coefficients[DC_RM]; + effpower_coeff[DC_WH]=initpower_coeff[DC_WH]*p->sys.scaling_coefficients[DC_WH]; + effpower_coeff[DC_WM]=initpower_coeff[DC_WM]*p->sys.scaling_coefficients[DC_WM]; + + initpower_coeff[L2_RH]=proc->get_coefficient_l2_read_hits(); + initpower_coeff[L2_RM]=proc->get_coefficient_l2_read_misses(); + initpower_coeff[L2_WH]=proc->get_coefficient_l2_write_hits(); + initpower_coeff[L2_WM]=proc->get_coefficient_l2_write_misses(); + effpower_coeff[L2_RH]=initpower_coeff[L2_RH]*p->sys.scaling_coefficients[L2_RH]; + effpower_coeff[L2_RM]=initpower_coeff[L2_RM]*p->sys.scaling_coefficients[L2_RM]; + effpower_coeff[L2_WH]=initpower_coeff[L2_WH]*p->sys.scaling_coefficients[L2_WH]; + effpower_coeff[L2_WM]=initpower_coeff[L2_WM]*p->sys.scaling_coefficients[L2_WM]; + + initpower_coeff[IDLE_CORE_N]=p->sys.idle_core_power * proc->cores[0]->executionTime; + effpower_coeff[IDLE_CORE_N]=initpower_coeff[IDLE_CORE_N]*p->sys.scaling_coefficients[IDLE_CORE_N]; + + initpower_coeff[PIPE_A]=proc->cores[0]->get_coefficient_duty_cycle(); + effpower_coeff[PIPE_A]=initpower_coeff[PIPE_A]*p->sys.scaling_coefficients[PIPE_A]; + + initpower_coeff[MEM_RD]=proc->get_coefficient_mem_reads(); + initpower_coeff[MEM_WR]=proc->get_coefficient_mem_writes(); + initpower_coeff[MEM_PRE]=proc->get_coefficient_mem_pre(); + effpower_coeff[MEM_RD]=initpower_coeff[MEM_RD]*p->sys.scaling_coefficients[MEM_RD]; + effpower_coeff[MEM_WR]=initpower_coeff[MEM_WR]*p->sys.scaling_coefficients[MEM_WR]; + effpower_coeff[MEM_PRE]=initpower_coeff[MEM_PRE]*p->sys.scaling_coefficients[MEM_PRE]; + + initpower_coeff[SP_ACC]=proc->cores[0]->get_coefficient_ialu_accesses()*(proc->cores[0]->exu->rf_fu_clockRate/proc->cores[0]->exu->clockRate);; + initpower_coeff[SFU_ACC]=proc->cores[0]->get_coefficient_sfu_accesses(); + initpower_coeff[FPU_ACC]=proc->cores[0]->get_coefficient_fpu_accesses(); + + effpower_coeff[SP_ACC]=initpower_coeff[SP_ACC]*p->sys.scaling_coefficients[SP_ACC]; + effpower_coeff[SFU_ACC]=initpower_coeff[SFU_ACC]*p->sys.scaling_coefficients[SFU_ACC]; + effpower_coeff[FPU_ACC]=initpower_coeff[FPU_ACC]*p->sys.scaling_coefficients[FPU_ACC]; + + initpower_coeff[NOC_A]=proc->get_coefficient_noc_accesses(); + effpower_coeff[NOC_A]=initpower_coeff[NOC_A]*p->sys.scaling_coefficients[NOC_A]; + + const_dynamic_power=proc->get_const_dynamic_power()/(proc->cores[0]->executionTime); + + for(unsigned i=0; icores[0]->executionTime); + effpower_coeff[i]/=(proc->cores[0]->executionTime); + } } -void gpgpu_sim_wrapper::compute() { proc->compute(); } -void gpgpu_sim_wrapper::print_power_kernel_stats( - double gpu_sim_cycle, double gpu_tot_sim_cycle, double init_value, - const std::string& kernel_info_string, bool print_trace) { - detect_print_steady_state(1, init_value); - if (g_power_simulation_enabled) { - powerfile << kernel_info_string << std::endl; - - sanity_check((kernel_power.avg * kernel_sample_count), kernel_tot_power); - powerfile << "Kernel Average Power Data:" << std::endl; - powerfile << "kernel_avg_power = " << kernel_power.avg << std::endl; - - for (unsigned i = 0; i < num_pwr_cmps; ++i) { - powerfile << "gpu_avg_" << pwr_cmp_label[i] << " = " - << kernel_cmp_pwr[i].avg / kernel_sample_count << std::endl; - } - for (unsigned i = 0; i < num_perf_counters; ++i) { - powerfile << "gpu_avg_" << perf_count_label[i] << " = " - << kernel_cmp_perf_counters[i].avg / kernel_sample_count - << std::endl; - } +void gpgpu_sim_wrapper::update_components_power() +{ - powerfile << std::endl << "Kernel Maximum Power Data:" << std::endl; - powerfile << "kernel_max_power = " << kernel_power.max << std::endl; - for (unsigned i = 0; i < num_pwr_cmps; ++i) { - powerfile << "gpu_max_" << pwr_cmp_label[i] << " = " - << kernel_cmp_pwr[i].max << std::endl; - } - for (unsigned i = 0; i < num_perf_counters; ++i) { - powerfile << "gpu_max_" << perf_count_label[i] << " = " - << kernel_cmp_perf_counters[i].max << std::endl; - } + update_coefficients(); - powerfile << std::endl << "Kernel Minimum Power Data:" << std::endl; - powerfile << "kernel_min_power = " << kernel_power.min << std::endl; - for (unsigned i = 0; i < num_pwr_cmps; ++i) { - powerfile << "gpu_min_" << pwr_cmp_label[i] << " = " - << kernel_cmp_pwr[i].min << std::endl; - } - for (unsigned i = 0; i < num_perf_counters; ++i) { - powerfile << "gpu_min_" << perf_count_label[i] << " = " - << kernel_cmp_perf_counters[i].min << std::endl; - } + proc_power=proc->rt_power.readOp.dynamic; + + sample_cmp_pwr[IBP]=(proc->cores[0]->ifu->IB->rt_power.readOp.dynamic + +proc->cores[0]->ifu->IB->rt_power.writeOp.dynamic + +proc->cores[0]->ifu->ID_misc->rt_power.readOp.dynamic + +proc->cores[0]->ifu->ID_operand->rt_power.readOp.dynamic + +proc->cores[0]->ifu->ID_inst->rt_power.readOp.dynamic)/(proc->cores[0]->executionTime); + + sample_cmp_pwr[ICP]=proc->cores[0]->ifu->icache.rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[DCP]=proc->cores[0]->lsu->dcache.rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[TCP]=proc->cores[0]->lsu->tcache.rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[CCP]=proc->cores[0]->lsu->ccache.rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[SHRDP]=proc->cores[0]->lsu->sharedmemory.rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[RFP]=(proc->cores[0]->exu->rfu->rt_power.readOp.dynamic/(proc->cores[0]->executionTime)) + *(proc->cores[0]->exu->rf_fu_clockRate/proc->cores[0]->exu->clockRate); + + sample_cmp_pwr[SPP]=(proc->cores[0]->exu->exeu->rt_power.readOp.dynamic/(proc->cores[0]->executionTime)) + *(proc->cores[0]->exu->rf_fu_clockRate/proc->cores[0]->exu->clockRate); + + sample_cmp_pwr[SFUP]=(proc->cores[0]->exu->mul->rt_power.readOp.dynamic/(proc->cores[0]->executionTime)); + + sample_cmp_pwr[FPUP]=(proc->cores[0]->exu->fp_u->rt_power.readOp.dynamic/(proc->cores[0]->executionTime)); + + sample_cmp_pwr[SCHEDP]=proc->cores[0]->exu->scheu->rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[L2CP]=(proc->XML->sys.number_of_L2s>0)? proc->l2array[0]->rt_power.readOp.dynamic/(proc->cores[0]->executionTime):0; + + sample_cmp_pwr[MCP]=(proc->mc->rt_power.readOp.dynamic-proc->mc->dram->rt_power.readOp.dynamic)/(proc->cores[0]->executionTime); + + sample_cmp_pwr[NOCP]=proc->nocs[0]->rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[DRAMP]=proc->mc->dram->rt_power.readOp.dynamic/(proc->cores[0]->executionTime); + + sample_cmp_pwr[PIPEP]=proc->cores[0]->Pipeline_energy/(proc->cores[0]->executionTime); + + sample_cmp_pwr[IDLE_COREP]=proc->cores[0]->IdleCoreEnergy/(proc->cores[0]->executionTime); + + // This constant dynamic power (e.g., clock power) part is estimated via regression model. + sample_cmp_pwr[CONST_DYNAMICP]=0; + double cnst_dyn = proc->get_const_dynamic_power()/(proc->cores[0]->executionTime); + // If the regression scaling term is greater than the recorded constant dynamic power + // then use the difference (other portion already added to dynamic power). Else, + // all the constant dynamic power is accounted for, add nothing. + if(p->sys.scaling_coefficients[CONST_DYNAMICN] > cnst_dyn) + sample_cmp_pwr[CONST_DYNAMICP] = (p->sys.scaling_coefficients[CONST_DYNAMICN]-cnst_dyn); + + proc_power+=sample_cmp_pwr[CONST_DYNAMICP]; + + double sum_pwr_cmp=0; + for(unsigned i=0; idisplayEnergy(2,5); } -void gpgpu_sim_wrapper::detect_print_steady_state(int position, - double init_val) { - // Calculating Average - if (g_power_simulation_enabled && g_steady_power_levels_enabled) { - steady_state_tacking_file = gzopen(g_steady_state_tracking_filename, "a"); - if (position == 0) { - if (samples.size() == 0) { - // First sample - sample_start = total_sample_count; - sample_val = proc->rt_power.readOp.dynamic; - init_inst_val = init_val; - samples.push_back(proc->rt_power.readOp.dynamic); - assert(samples_counter.size() == 0); - assert(pwr_counter.size() == 0); - - for (unsigned i = 0; i < (num_perf_counters); ++i) { - samples_counter.push_back(sample_perf_counters[i]); - } +void gpgpu_sim_wrapper::print_steady_state(int position, double init_val){ + double temp_avg = sample_val / (double)samples.size() ; + double temp_ipc = (init_val-init_inst_val)/ (double) (samples.size()*gpu_stat_sample_freq); + + if((samples.size() > gpu_steady_min_period)){ // If steady state occurred for some time, print to file + has_written_avg=true; + gzprintf(steady_state_tacking_file,"%u,%d,%f,%f,",sample_start,total_sample_count,temp_avg,temp_ipc); + for(unsigned i=0; irt_power.readOp.dynamic - temp_avg) < - gpu_steady_power_deviation) { // Value is within threshold - sample_val += proc->rt_power.readOp.dynamic; - samples.push_back(proc->rt_power.readOp.dynamic); - for (unsigned i = 0; i < (num_perf_counters); ++i) { - samples_counter.at(i) += sample_perf_counters[i]; - } - - for (unsigned i = 0; i < (num_pwr_cmps); ++i) { - pwr_counter.at(i) += sample_cmp_pwr[i]; - } - - } else { // Value exceeds threshold, not considered steady state - print_steady_state(position, init_val); - } - } - } else { - print_steady_state(position, init_val); +void gpgpu_sim_wrapper::detect_print_steady_state(int position, double init_val) +{ + // Calculating Average + if(g_power_simulation_enabled && g_steady_power_levels_enabled){ + steady_state_tacking_file = gzopen(g_steady_state_tracking_filename,"a"); + if(position==0){ + if(samples.size() == 0){ + // First sample + sample_start = total_sample_count; + sample_val = proc->rt_power.readOp.dynamic; + init_inst_val=init_val; + samples.push_back(proc->rt_power.readOp.dynamic); + assert(samples_counter.size() == 0); + assert(pwr_counter.size() == 0); + + for(unsigned i=0; i<(num_perf_counters); ++i){ + samples_counter.push_back(sample_perf_counters[i]); + } + + for(unsigned i=0; i<(num_pwr_cmps); ++i){ + pwr_counter.push_back(sample_cmp_pwr[i]); + } + assert(pwr_counter.size() == (double)num_pwr_cmps); + assert(samples_counter.size() == (double)num_perf_counters); + }else{ + // Get current average + double temp_avg = sample_val / (double)samples.size() ; + + if( abs(proc->rt_power.readOp.dynamic-temp_avg) < gpu_steady_power_deviation){ // Value is within threshold + sample_val += proc->rt_power.readOp.dynamic; + samples.push_back(proc->rt_power.readOp.dynamic); + for(unsigned i=0; i<(num_perf_counters); ++i){ + samples_counter.at(i) += sample_perf_counters[i]; + } + + for(unsigned i=0; i<(num_pwr_cmps); ++i){ + pwr_counter.at(i) += sample_cmp_pwr[i]; + } + + }else{ // Value exceeds threshold, not considered steady state + print_steady_state(position, init_val); + } + } + }else{ + print_steady_state(position, init_val); + } + gzclose(steady_state_tacking_file); } - gzclose(steady_state_tacking_file); - } } -void gpgpu_sim_wrapper::open_files() { - if (g_power_simulation_enabled) { - if (g_power_trace_enabled) { - power_trace_file = gzopen(g_power_trace_filename, "a"); - metric_trace_file = gzopen(g_metric_trace_filename, "a"); +void gpgpu_sim_wrapper::open_files() +{ + if(g_power_simulation_enabled){ + if (g_power_trace_enabled ){ + power_trace_file = gzopen(g_power_trace_filename, "a"); + metric_trace_file = gzopen(g_metric_trace_filename, "a"); + } } - } } -void gpgpu_sim_wrapper::close_files() { - if (g_power_simulation_enabled) { - if (g_power_trace_enabled) { - gzclose(power_trace_file); - gzclose(metric_trace_file); - } - } +void gpgpu_sim_wrapper::close_files() +{ + if(g_power_simulation_enabled){ + if(g_power_trace_enabled){ + gzclose(power_trace_file); + gzclose(metric_trace_file); + } + } + } -- cgit v1.3