ext/mcpat/cachearray.cc - amd/gem5 - Git at Google

 /*****************************************************************************
  *                                McPAT
  *                      SOFTWARE LICENSE AGREEMENT
  *            Copyright (c) 2010-2013 Advanced Micro Devices, Inc.
  *                          All Rights Reserved
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are
  * met: 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 list of conditions and the following disclaimer in the
  * documentation and/or other materials provided with the distribution;
  * neither the name of the copyright holders 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 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
  * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  *
  * Authors: Joel Hestness
  *          Yasuko Eckert
  *
  ***************************************************************************/

 #include <cmath>
 #include <iostream>

 #include "area.h"
 #include "cachearray.h"
 #include "common.h"
 #include "decoder.h"
 #include "parameter.h"

 using namespace std;

 double CacheArray::area_efficiency_threshold = 20.0;
 int CacheArray::ed = 0;
 //Fixed number, make sure timing can be satisfied.
 int CacheArray::delay_wt = 100;
 int CacheArray::cycle_time_wt = 1000;
 //Fixed number, This is used to exhaustive search for individual components.
 int CacheArray::area_wt = 10;
 //Fixed number, This is used to exhaustive search for individual components.
 int CacheArray::dynamic_power_wt = 10;
 int CacheArray::leakage_power_wt = 10;
 //Fixed number, make sure timing can be satisfied.
 int CacheArray::delay_dev = 1000000;
 int CacheArray::cycle_time_dev = 100;
 //Fixed number, This is used to exhaustive search for individual components.
 int CacheArray::area_dev = 1000000;
 //Fixed number, This is used to exhaustive search for individual components.
 int CacheArray::dynamic_power_dev = 1000000;
 int CacheArray::leakage_power_dev = 1000000;
 int CacheArray::cycle_time_dev_threshold = 10;

 CacheArray::CacheArray(XMLNode* _xml_data,
                  const InputParameter *configure_interface, string _name,
                  enum Device_ty device_ty_, double _clockRate,
                  bool opt_local_, enum Core_type core_ty_, bool _is_default)
         : McPATComponent(_xml_data), l_ip(*configure_interface),
         device_ty(device_ty_), opt_local(opt_local_), core_ty(core_ty_),
         is_default(_is_default), sbt_dir_overhead(0) {
     name = _name;
     clockRate = _clockRate;
     if (l_ip.cache_sz < MIN_BUFFER_SIZE) {
         l_ip.cache_sz = MIN_BUFFER_SIZE;
     }

     if (!l_ip.error_checking(name)) {
         exit(1);
     }

     sbt_tdp_stats.reset();
     sbt_rtp_stats.reset();

     // Compute initial search point
     local_result.valid = false;
     compute_base_power();

     // Set up the cache by searching design space with cacti
     list<uca_org_t > candidate_solutions(0);
     list<uca_org_t >::iterator candidate_iter, min_dynamic_energy_iter;
     uca_org_t* temp_res = NULL;
     double throughput = l_ip.throughput;
     double latency = l_ip.latency;
     bool throughput_overflow = true;
     bool latency_overflow = true;

     if ((local_result.cycle_time - throughput) <= 1e-10 )
         throughput_overflow = false;
     if ((local_result.access_time - latency) <= 1e-10)
         latency_overflow = false;

     if (opt_for_clk && opt_local) {
         if (throughput_overflow || latency_overflow) {
             l_ip.ed = ed;

             l_ip.delay_wt = delay_wt;
             l_ip.cycle_time_wt = cycle_time_wt;

             l_ip.area_wt = area_wt;
             l_ip.dynamic_power_wt = dynamic_power_wt;
             l_ip.leakage_power_wt = leakage_power_wt;

             l_ip.delay_dev = delay_dev;
             l_ip.cycle_time_dev = cycle_time_dev;

             l_ip.area_dev = area_dev;
             l_ip.dynamic_power_dev = dynamic_power_dev;
             l_ip.leakage_power_dev = leakage_power_dev;

             //Reset overflow flag before start optimization iterations
             throughput_overflow = true;
             latency_overflow = true;

             //Clean up the result for optimized for ED^2P
             temp_res = &local_result;
             temp_res->cleanup();
         }


         while ((throughput_overflow || latency_overflow) &&
                l_ip.cycle_time_dev > cycle_time_dev_threshold) {
             compute_base_power();

             //This is the time_dev to be used for next iteration
             l_ip.cycle_time_dev -= cycle_time_dev_threshold;

             //      from best area to worst area -->worst timing to best timing
             if ((((local_result.cycle_time - throughput) <= 1e-10 ) &&
                  (local_result.access_time - latency) <= 1e-10) ||
                 (local_result.data_array2->area_efficiency <
                  area_efficiency_threshold && l_ip.assoc == 0)) {
                 //if no satisfiable solution is found,the most aggressive one
                 //is left
                 candidate_solutions.push_back(local_result);
                 if (((local_result.cycle_time - throughput) <= 1e-10) &&
                     ((local_result.access_time - latency) <= 1e-10)) {
                     //ensure stop opt not because of cam
                     throughput_overflow = false;
                     latency_overflow = false;
                 }

             } else {
                 if ((local_result.cycle_time - throughput) <= 1e-10)
                     throughput_overflow = false;
                 if ((local_result.access_time - latency) <= 1e-10)
                     latency_overflow = false;

                 //if not >10 local_result is the last result, it cannot be
                 //cleaned up
                 if (l_ip.cycle_time_dev > cycle_time_dev_threshold) {
                     //Only solutions not saved in the list need to be
                     //cleaned up
                     temp_res = &local_result;
                     temp_res->cleanup();
                 }
             }
         }


         if (l_ip.assoc > 0) {
             //For array structures except CAM and FA, Give warning but still
             //provide a result with best timing found
             if (throughput_overflow == true)
                 cout << "Warning: " << name
                      << " array structure cannot satisfy throughput constraint."
                      << endl;
             if (latency_overflow == true)
                 cout << "Warning: " << name
                      << " array structure cannot satisfy latency constraint."
                      << endl;
         }

         double min_dynamic_energy = BIGNUM;
         if (candidate_solutions.empty() == false) {
             local_result.valid = true;
             for (candidate_iter = candidate_solutions.begin();
                  candidate_iter != candidate_solutions.end();
                  ++candidate_iter) {
                 if (min_dynamic_energy >
                     (candidate_iter)->power.readOp.dynamic) {
                     min_dynamic_energy =
                         (candidate_iter)->power.readOp.dynamic;
                     min_dynamic_energy_iter = candidate_iter;
                     local_result = *(min_dynamic_energy_iter);

                 } else {
                     candidate_iter->cleanup() ;
                 }

             }


         }
         candidate_solutions.clear();
     }

     double long_channel_device_reduction =
         longer_channel_device_reduction(device_ty, core_ty);

     double macro_layout_overhead = g_tp.macro_layout_overhead;
     double chip_PR_overhead = g_tp.chip_layout_overhead;
     double total_overhead = macro_layout_overhead * chip_PR_overhead;
     local_result.area *= total_overhead;

     //maintain constant power density
     double pppm_t[4]    = {total_overhead, 1, 1, total_overhead};

     double sckRation = g_tp.sckt_co_eff;
     local_result.power.readOp.dynamic *= sckRation;
     local_result.power.writeOp.dynamic *= sckRation;
     local_result.power.searchOp.dynamic *= sckRation;
     local_result.power.readOp.leakage *= l_ip.nbanks;
     local_result.power.readOp.longer_channel_leakage =
         local_result.power.readOp.leakage * long_channel_device_reduction;
     local_result.power = local_result.power * pppm_t;

     local_result.data_array2->power.readOp.dynamic *= sckRation;
     local_result.data_array2->power.writeOp.dynamic *= sckRation;
     local_result.data_array2->power.searchOp.dynamic *= sckRation;
     local_result.data_array2->power.readOp.leakage *= l_ip.nbanks;
     local_result.data_array2->power.readOp.longer_channel_leakage =
         local_result.data_array2->power.readOp.leakage *
         long_channel_device_reduction;
     local_result.data_array2->power = local_result.data_array2->power * pppm_t;


     if (!(l_ip.pure_cam || l_ip.pure_ram || l_ip.fully_assoc) && l_ip.is_cache) {
         local_result.tag_array2->power.readOp.dynamic *= sckRation;
         local_result.tag_array2->power.writeOp.dynamic *= sckRation;
         local_result.tag_array2->power.searchOp.dynamic *= sckRation;
         local_result.tag_array2->power.readOp.leakage *= l_ip.nbanks;
         local_result.tag_array2->power.readOp.longer_channel_leakage =
             local_result.tag_array2->power.readOp.leakage *
             long_channel_device_reduction;
         local_result.tag_array2->power =
             local_result.tag_array2->power * pppm_t;
     }
 }

 void CacheArray::compute_base_power() {
     local_result = cacti_interface(&l_ip);
 }

 void CacheArray::computeArea() {
     area.set_area(local_result.area);
     output_data.area = local_result.area / 1e6;
 }

 void CacheArray::computeEnergy() {
     // Set the leakage power numbers
     output_data.subthreshold_leakage_power = local_result.power.readOp.leakage;
     output_data.gate_leakage_power = local_result.power.readOp.gate_leakage;

     if (l_ip.assoc && l_ip.is_cache) {
         // This is a standard cache array with data and tags
         // Calculate peak dynamic power
         output_data.peak_dynamic_power =
             (local_result.tag_array2->power.readOp.dynamic +
              local_result.data_array2->power.readOp.dynamic) *
             tdp_stats.readAc.hit +
             (local_result.tag_array2->power.readOp.dynamic) *
             tdp_stats.readAc.miss +
             (local_result.tag_array2->power.readOp.dynamic +
              local_result.data_array2->power.writeOp.dynamic) *
             tdp_stats.writeAc.hit +
             (local_result.tag_array2->power.readOp.dynamic) *
             tdp_stats.writeAc.miss;
         output_data.peak_dynamic_power *= clockRate;

         // Calculate the runtime dynamic power
         output_data.runtime_dynamic_energy =
             local_result.data_array2->power.readOp.dynamic *
             rtp_stats.dataReadAc.access +
             local_result.data_array2->power.writeOp.dynamic *
             rtp_stats.dataWriteAc.access +
             (local_result.tag_array2->power.readOp.dynamic *
              rtp_stats.tagReadAc.access +
              local_result.tag_array2->power.writeOp.dynamic *
              rtp_stats.tagWriteAc.access) * l_ip.assoc;
     } else {
         // Calculate peak dynamic power
         output_data.peak_dynamic_power =
                 local_result.power.readOp.dynamic * tdp_stats.readAc.access +
                 local_result.power.writeOp.dynamic * tdp_stats.writeAc.access +
                 local_result.power.searchOp.dynamic * tdp_stats.searchAc.access;
         output_data.peak_dynamic_power *= clockRate;

         // Calculate the runtime dynamic power
         output_data.runtime_dynamic_energy =
                 local_result.power.readOp.dynamic * rtp_stats.readAc.access +
                 local_result.power.writeOp.dynamic * rtp_stats.writeAc.access +
                 local_result.power.searchOp.dynamic * rtp_stats.searchAc.access;
     }

     // An SBT directory has more dynamic power
     if (sbt_dir_overhead > 0) {
         // Calculate peak dynamic power
         output_data.peak_dynamic_power +=
             (computeSBTDynEnergy(&sbt_tdp_stats) * clockRate);

         // Calculate the runtime dynamic power
         output_data.runtime_dynamic_energy +=
             computeSBTDynEnergy(&sbt_rtp_stats);
     }
 }

 CacheArray::~CacheArray() {
     local_result.cleanup();
 }
	/*****************************************************************************
	* McPAT
	* SOFTWARE LICENSE AGREEMENT
	* Copyright (c) 2010-2013 Advanced Micro Devices, Inc.
	* All Rights Reserved
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are
	* met: 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 list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution;
	* neither the name of the copyright holders 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 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
	* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*
	* Authors: Joel Hestness
	* Yasuko Eckert
	*
	***************************************************************************/

	#include <cmath>
	#include <iostream>

	#include "area.h"
	#include "cachearray.h"
	#include "common.h"
	#include "decoder.h"
	#include "parameter.h"

	using namespace std;

	double CacheArray::area_efficiency_threshold = 20.0;
	int CacheArray::ed = 0;
	//Fixed number, make sure timing can be satisfied.
	int CacheArray::delay_wt = 100;
	int CacheArray::cycle_time_wt = 1000;
	//Fixed number, This is used to exhaustive search for individual components.
	int CacheArray::area_wt = 10;
	//Fixed number, This is used to exhaustive search for individual components.
	int CacheArray::dynamic_power_wt = 10;
	int CacheArray::leakage_power_wt = 10;
	//Fixed number, make sure timing can be satisfied.
	int CacheArray::delay_dev = 1000000;
	int CacheArray::cycle_time_dev = 100;
	//Fixed number, This is used to exhaustive search for individual components.
	int CacheArray::area_dev = 1000000;
	//Fixed number, This is used to exhaustive search for individual components.
	int CacheArray::dynamic_power_dev = 1000000;
	int CacheArray::leakage_power_dev = 1000000;
	int CacheArray::cycle_time_dev_threshold = 10;

	CacheArray::CacheArray(XMLNode* _xml_data,
	const InputParameter *configure_interface, string _name,
	enum Device_ty device_ty_, double _clockRate,
	bool opt_local_, enum Core_type core_ty_, bool _is_default)
	: McPATComponent(_xml_data), l_ip(*configure_interface),
	device_ty(device_ty_), opt_local(opt_local_), core_ty(core_ty_),
	is_default(_is_default), sbt_dir_overhead(0) {
	name = _name;
	clockRate = _clockRate;
	if (l_ip.cache_sz < MIN_BUFFER_SIZE) {
	l_ip.cache_sz = MIN_BUFFER_SIZE;
	}

	if (!l_ip.error_checking(name)) {
	exit(1);
	}

	sbt_tdp_stats.reset();
	sbt_rtp_stats.reset();

	// Compute initial search point
	local_result.valid = false;
	compute_base_power();

	// Set up the cache by searching design space with cacti
	list<uca_org_t > candidate_solutions(0);
	list<uca_org_t >::iterator candidate_iter, min_dynamic_energy_iter;
	uca_org_t* temp_res = NULL;
	double throughput = l_ip.throughput;
	double latency = l_ip.latency;
	bool throughput_overflow = true;
	bool latency_overflow = true;

	if ((local_result.cycle_time - throughput) <= 1e-10 )
	throughput_overflow = false;
	if ((local_result.access_time - latency) <= 1e-10)
	latency_overflow = false;

	if (opt_for_clk && opt_local) {
	if (throughput_overflow \|\| latency_overflow) {
	l_ip.ed = ed;

	l_ip.delay_wt = delay_wt;
	l_ip.cycle_time_wt = cycle_time_wt;

	l_ip.area_wt = area_wt;
	l_ip.dynamic_power_wt = dynamic_power_wt;
	l_ip.leakage_power_wt = leakage_power_wt;

	l_ip.delay_dev = delay_dev;
	l_ip.cycle_time_dev = cycle_time_dev;

	l_ip.area_dev = area_dev;
	l_ip.dynamic_power_dev = dynamic_power_dev;
	l_ip.leakage_power_dev = leakage_power_dev;

	//Reset overflow flag before start optimization iterations
	throughput_overflow = true;
	latency_overflow = true;

	//Clean up the result for optimized for ED^2P
	temp_res = &local_result;
	temp_res->cleanup();
	}


	while ((throughput_overflow \|\| latency_overflow) &&
	l_ip.cycle_time_dev > cycle_time_dev_threshold) {
	compute_base_power();

	//This is the time_dev to be used for next iteration
	l_ip.cycle_time_dev -= cycle_time_dev_threshold;

	// from best area to worst area -->worst timing to best timing
	if ((((local_result.cycle_time - throughput) <= 1e-10 ) &&
	(local_result.access_time - latency) <= 1e-10) \|\|
	(local_result.data_array2->area_efficiency <
	area_efficiency_threshold && l_ip.assoc == 0)) {
	//if no satisfiable solution is found,the most aggressive one
	//is left
	candidate_solutions.push_back(local_result);
	if (((local_result.cycle_time - throughput) <= 1e-10) &&
	((local_result.access_time - latency) <= 1e-10)) {
	//ensure stop opt not because of cam
	throughput_overflow = false;
	latency_overflow = false;
	}

	} else {
	if ((local_result.cycle_time - throughput) <= 1e-10)
	throughput_overflow = false;
	if ((local_result.access_time - latency) <= 1e-10)
	latency_overflow = false;

	//if not >10 local_result is the last result, it cannot be
	//cleaned up
	if (l_ip.cycle_time_dev > cycle_time_dev_threshold) {
	//Only solutions not saved in the list need to be
	//cleaned up
	temp_res = &local_result;
	temp_res->cleanup();
	}
	}
	}


	if (l_ip.assoc > 0) {
	//For array structures except CAM and FA, Give warning but still
	//provide a result with best timing found
	if (throughput_overflow == true)
	cout << "Warning: " << name
	<< " array structure cannot satisfy throughput constraint."
	<< endl;
	if (latency_overflow == true)
	cout << "Warning: " << name
	<< " array structure cannot satisfy latency constraint."
	<< endl;
	}

	double min_dynamic_energy = BIGNUM;
	if (candidate_solutions.empty() == false) {
	local_result.valid = true;
	for (candidate_iter = candidate_solutions.begin();
	candidate_iter != candidate_solutions.end();
	++candidate_iter) {
	if (min_dynamic_energy >
	(candidate_iter)->power.readOp.dynamic) {
	min_dynamic_energy =
	(candidate_iter)->power.readOp.dynamic;
	min_dynamic_energy_iter = candidate_iter;
	local_result = *(min_dynamic_energy_iter);

	} else {
	candidate_iter->cleanup() ;
	}

	}


	}
	candidate_solutions.clear();
	}

	double long_channel_device_reduction =
	longer_channel_device_reduction(device_ty, core_ty);

	double macro_layout_overhead = g_tp.macro_layout_overhead;
	double chip_PR_overhead = g_tp.chip_layout_overhead;
	double total_overhead = macro_layout_overhead * chip_PR_overhead;
	local_result.area *= total_overhead;

	//maintain constant power density
	double pppm_t[4] = {total_overhead, 1, 1, total_overhead};

	double sckRation = g_tp.sckt_co_eff;
	local_result.power.readOp.dynamic *= sckRation;
	local_result.power.writeOp.dynamic *= sckRation;
	local_result.power.searchOp.dynamic *= sckRation;
	local_result.power.readOp.leakage *= l_ip.nbanks;
	local_result.power.readOp.longer_channel_leakage =
	local_result.power.readOp.leakage * long_channel_device_reduction;
	local_result.power = local_result.power * pppm_t;

	local_result.data_array2->power.readOp.dynamic *= sckRation;
	local_result.data_array2->power.writeOp.dynamic *= sckRation;
	local_result.data_array2->power.searchOp.dynamic *= sckRation;
	local_result.data_array2->power.readOp.leakage *= l_ip.nbanks;
	local_result.data_array2->power.readOp.longer_channel_leakage =
	local_result.data_array2->power.readOp.leakage *
	long_channel_device_reduction;
	local_result.data_array2->power = local_result.data_array2->power * pppm_t;


	if (!(l_ip.pure_cam \|\| l_ip.pure_ram \|\| l_ip.fully_assoc) && l_ip.is_cache) {
	local_result.tag_array2->power.readOp.dynamic *= sckRation;
	local_result.tag_array2->power.writeOp.dynamic *= sckRation;
	local_result.tag_array2->power.searchOp.dynamic *= sckRation;
	local_result.tag_array2->power.readOp.leakage *= l_ip.nbanks;
	local_result.tag_array2->power.readOp.longer_channel_leakage =
	local_result.tag_array2->power.readOp.leakage *
	long_channel_device_reduction;
	local_result.tag_array2->power =
	local_result.tag_array2->power * pppm_t;
	}
	}

	void CacheArray::compute_base_power() {
	local_result = cacti_interface(&l_ip);
	}

	void CacheArray::computeArea() {
	area.set_area(local_result.area);
	output_data.area = local_result.area / 1e6;
	}

	void CacheArray::computeEnergy() {
	// Set the leakage power numbers
	output_data.subthreshold_leakage_power = local_result.power.readOp.leakage;
	output_data.gate_leakage_power = local_result.power.readOp.gate_leakage;

	if (l_ip.assoc && l_ip.is_cache) {
	// This is a standard cache array with data and tags
	// Calculate peak dynamic power
	output_data.peak_dynamic_power =
	(local_result.tag_array2->power.readOp.dynamic +
	local_result.data_array2->power.readOp.dynamic) *
	tdp_stats.readAc.hit +
	(local_result.tag_array2->power.readOp.dynamic) *
	tdp_stats.readAc.miss +
	(local_result.tag_array2->power.readOp.dynamic +
	local_result.data_array2->power.writeOp.dynamic) *
	tdp_stats.writeAc.hit +
	(local_result.tag_array2->power.readOp.dynamic) *
	tdp_stats.writeAc.miss;
	output_data.peak_dynamic_power *= clockRate;

	// Calculate the runtime dynamic power
	output_data.runtime_dynamic_energy =
	local_result.data_array2->power.readOp.dynamic *
	rtp_stats.dataReadAc.access +
	local_result.data_array2->power.writeOp.dynamic *
	rtp_stats.dataWriteAc.access +
	(local_result.tag_array2->power.readOp.dynamic *
	rtp_stats.tagReadAc.access +
	local_result.tag_array2->power.writeOp.dynamic *
	rtp_stats.tagWriteAc.access) * l_ip.assoc;
	} else {
	// Calculate peak dynamic power
	output_data.peak_dynamic_power =
	local_result.power.readOp.dynamic * tdp_stats.readAc.access +
	local_result.power.writeOp.dynamic * tdp_stats.writeAc.access +
	local_result.power.searchOp.dynamic * tdp_stats.searchAc.access;
	output_data.peak_dynamic_power *= clockRate;

	// Calculate the runtime dynamic power
	output_data.runtime_dynamic_energy =
	local_result.power.readOp.dynamic * rtp_stats.readAc.access +
	local_result.power.writeOp.dynamic * rtp_stats.writeAc.access +
	local_result.power.searchOp.dynamic * rtp_stats.searchAc.access;
	}

	// An SBT directory has more dynamic power
	if (sbt_dir_overhead > 0) {
	// Calculate peak dynamic power
	output_data.peak_dynamic_power +=
	(computeSBTDynEnergy(&sbt_tdp_stats) * clockRate);

	// Calculate the runtime dynamic power
	output_data.runtime_dynamic_energy +=
	computeSBTDynEnergy(&sbt_rtp_stats);
	}
	}

	CacheArray::~CacheArray() {
	local_result.cleanup();
	}