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/*****************************************************************************
* McPAT/CACTI
* SOFTWARE LICENSE AGREEMENT
* Copyright 2012 Hewlett-Packard Development Company, L.P.
* Copyright (c) 2010-2013 Advanced Micro Devices, Inc.
* All Rights Reserved
*
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* notice, this list of conditions and the following disclaimer in the
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* 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,
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* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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***************************************************************************/
#include <cmath>
#include <iostream>
#include "uca.h"
UCA::UCA(const DynamicParameter & dyn_p)
: dp(dyn_p), bank(dp), nbanks(g_ip->nbanks), refresh_power(0) {
int num_banks_ver_dir = 1 << ((bank.area.h > bank.area.w) ? _log2(nbanks)
/ 2 : (_log2(nbanks) - _log2(nbanks) / 2));
int num_banks_hor_dir = nbanks / num_banks_ver_dir;
if (dp.use_inp_params) {
RWP = dp.num_rw_ports;
ERP = dp.num_rd_ports;
EWP = dp.num_wr_ports;
SCHP = dp.num_search_ports;
} else {
RWP = g_ip->num_rw_ports;
ERP = g_ip->num_rd_ports;
EWP = g_ip->num_wr_ports;
SCHP = g_ip->num_search_ports;
}
num_addr_b_bank = (dp.number_addr_bits_mat + dp.number_subbanks_decode) *
(RWP + ERP + EWP);
num_di_b_bank = dp.num_di_b_bank_per_port * (RWP + EWP);
num_do_b_bank = dp.num_do_b_bank_per_port * (RWP + ERP);
num_si_b_bank = dp.num_si_b_bank_per_port * SCHP;
num_so_b_bank = dp.num_so_b_bank_per_port * SCHP;
if (!dp.fully_assoc && !dp.pure_cam) {
if (g_ip->fast_access && dp.is_tag == false) {
num_do_b_bank *= g_ip->data_assoc;
}
htree_in_add = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank, 0,
num_do_b_bank, 0, num_banks_ver_dir * 2,
num_banks_hor_dir * 2, Add_htree, true);
htree_in_data = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank, 0,
num_do_b_bank, 0, num_banks_ver_dir * 2,
num_banks_hor_dir * 2, Data_in_htree, true);
htree_out_data = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank, 0,
num_do_b_bank, 0, num_banks_ver_dir * 2,
num_banks_hor_dir * 2, Data_out_htree, true);
}
else {
htree_in_add = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank,
num_si_b_bank, num_do_b_bank, num_so_b_bank,
num_banks_ver_dir * 2, num_banks_hor_dir * 2,
Add_htree, true);
htree_in_data = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank,
num_si_b_bank, num_do_b_bank, num_so_b_bank,
num_banks_ver_dir * 2, num_banks_hor_dir * 2,
Data_in_htree, true);
htree_out_data = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank,
num_si_b_bank, num_do_b_bank,
num_so_b_bank, num_banks_ver_dir * 2,
num_banks_hor_dir * 2, Data_out_htree, true);
htree_in_search = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank,
num_si_b_bank, num_do_b_bank,
num_so_b_bank, num_banks_ver_dir * 2,
num_banks_hor_dir * 2, Data_in_htree, true);
htree_out_search = new Htree2(g_ip->wt, bank.area.w, bank.area.h,
num_addr_b_bank, num_di_b_bank,
num_si_b_bank, num_do_b_bank,
num_so_b_bank, num_banks_ver_dir * 2,
num_banks_hor_dir * 2, Data_out_htree,
true);
}
area.w = htree_in_data->area.w;
area.h = htree_in_data->area.h;
area_all_dataramcells = bank.mat.subarray.get_total_cell_area() * dp.num_subarrays * g_ip->nbanks;
// cout<<"area cell"<<area_all_dataramcells<<endl;
// cout<<area.get_area()<<endl;
// delay calculation
double inrisetime = 0.0;
compute_delays(inrisetime);
compute_power_energy();
}
UCA::~UCA() {
delete htree_in_add;
delete htree_in_data;
delete htree_out_data;
}
double UCA::compute_delays(double inrisetime) {
double outrisetime = bank.compute_delays(inrisetime);
double delay_array_to_mat = htree_in_add->delay + bank.htree_in_add->delay;
double max_delay_before_row_decoder = delay_array_to_mat + bank.mat.r_predec->delay;
delay_array_to_sa_mux_lev_1_decoder = delay_array_to_mat +
bank.mat.sa_mux_lev_1_predec->delay +
bank.mat.sa_mux_lev_1_dec->delay;
delay_array_to_sa_mux_lev_2_decoder = delay_array_to_mat +
bank.mat.sa_mux_lev_2_predec->delay +
bank.mat.sa_mux_lev_2_dec->delay;
double delay_inside_mat = bank.mat.row_dec->delay + bank.mat.delay_bitline + bank.mat.delay_sa;
delay_before_subarray_output_driver =
MAX(MAX(max_delay_before_row_decoder + delay_inside_mat, // row_path
delay_array_to_mat + bank.mat.b_mux_predec->delay + bank.mat.bit_mux_dec->delay + bank.mat.delay_sa), // col_path
MAX(delay_array_to_sa_mux_lev_1_decoder, // sa_mux_lev_1_path
delay_array_to_sa_mux_lev_2_decoder)); // sa_mux_lev_2_path
delay_from_subarray_out_drv_to_out = bank.mat.delay_subarray_out_drv_htree +
bank.htree_out_data->delay + htree_out_data->delay;
access_time = bank.mat.delay_comparator;
double ram_delay_inside_mat;
if (dp.fully_assoc) {
//delay of FA contains both CAM tag and RAM data
{ //delay of CAM
ram_delay_inside_mat = bank.mat.delay_bitline + bank.mat.delay_matchchline;
access_time = htree_in_add->delay + bank.htree_in_add->delay;
//delay of fully-associative data array
access_time += ram_delay_inside_mat + delay_from_subarray_out_drv_to_out;
}
} else {
access_time = delay_before_subarray_output_driver + delay_from_subarray_out_drv_to_out; //data_acc_path
}
if (dp.is_main_mem) {
double t_rcd = max_delay_before_row_decoder + delay_inside_mat;
double cas_latency = MAX(delay_array_to_sa_mux_lev_1_decoder, delay_array_to_sa_mux_lev_2_decoder) +
delay_from_subarray_out_drv_to_out;
access_time = t_rcd + cas_latency;
}
double temp;
if (!dp.fully_assoc) {
temp = delay_inside_mat + bank.mat.delay_wl_reset + bank.mat.delay_bl_restore;//TODO: Sheng: revisit
if (dp.is_dram) {
temp += bank.mat.delay_writeback; // temp stores random cycle time
}
temp = MAX(temp, bank.mat.r_predec->delay);
temp = MAX(temp, bank.mat.b_mux_predec->delay);
temp = MAX(temp, bank.mat.sa_mux_lev_1_predec->delay);
temp = MAX(temp, bank.mat.sa_mux_lev_2_predec->delay);
} else {
ram_delay_inside_mat = bank.mat.delay_bitline + bank.mat.delay_matchchline;
temp = ram_delay_inside_mat + bank.mat.delay_cam_sl_restore + bank.mat.delay_cam_ml_reset + bank.mat.delay_bl_restore
+ bank.mat.delay_hit_miss_reset + bank.mat.delay_wl_reset;
temp = MAX(temp, bank.mat.b_mux_predec->delay);//TODO: Sheng revisit whether distinguish cam and ram bitline etc.
temp = MAX(temp, bank.mat.sa_mux_lev_1_predec->delay);
temp = MAX(temp, bank.mat.sa_mux_lev_2_predec->delay);
}
// The following is true only if the input parameter "repeaters_in_htree" is set to false --Nav
if (g_ip->rpters_in_htree == false) {
temp = MAX(temp, bank.htree_in_add->max_unpipelined_link_delay);
}
cycle_time = temp;
double delay_req_network = max_delay_before_row_decoder;
double delay_rep_network = delay_from_subarray_out_drv_to_out;
multisubbank_interleave_cycle_time = MAX(delay_req_network, delay_rep_network);
if (dp.is_main_mem) {
multisubbank_interleave_cycle_time = htree_in_add->delay;
precharge_delay = htree_in_add->delay +
bank.htree_in_add->delay + bank.mat.delay_writeback +
bank.mat.delay_wl_reset + bank.mat.delay_bl_restore;
cycle_time = access_time + precharge_delay;
} else {
precharge_delay = 0;
}
double dram_array_availability = 0;
if (dp.is_dram) {
dram_array_availability = (1 - dp.num_r_subarray * cycle_time / dp.dram_refresh_period) * 100;
}
return outrisetime;
}
// note: currently, power numbers are for a bank of an array
void UCA::compute_power_energy() {
bank.compute_power_energy();
power = bank.power;
power_routing_to_bank.readOp.dynamic = htree_in_add->power.readOp.dynamic + htree_out_data->power.readOp.dynamic;
power_routing_to_bank.writeOp.dynamic = htree_in_add->power.readOp.dynamic + htree_in_data->power.readOp.dynamic;
if (dp.fully_assoc || dp.pure_cam)
power_routing_to_bank.searchOp.dynamic =
htree_in_search->power.searchOp.dynamic +
htree_out_search->power.searchOp.dynamic;
power_routing_to_bank.readOp.leakage +=
htree_in_add->power.readOp.leakage +
htree_in_data->power.readOp.leakage +
htree_out_data->power.readOp.leakage;
power_routing_to_bank.readOp.gate_leakage +=
htree_in_add->power.readOp.gate_leakage +
htree_in_data->power.readOp.gate_leakage +
htree_out_data->power.readOp.gate_leakage;
if (dp.fully_assoc || dp.pure_cam) {
power_routing_to_bank.readOp.leakage += htree_in_search->power.readOp.leakage + htree_out_search->power.readOp.leakage;
power_routing_to_bank.readOp.gate_leakage += htree_in_search->power.readOp.gate_leakage + htree_out_search->power.readOp.gate_leakage;
}
power.searchOp.dynamic += power_routing_to_bank.searchOp.dynamic;
power.readOp.dynamic += power_routing_to_bank.readOp.dynamic;
power.readOp.leakage += power_routing_to_bank.readOp.leakage;
power.readOp.gate_leakage += power_routing_to_bank.readOp.gate_leakage;
// calculate total write energy per access
power.writeOp.dynamic = power.readOp.dynamic
- bank.mat.power_bitline.readOp.dynamic * dp.num_act_mats_hor_dir
+ bank.mat.power_bitline.writeOp.dynamic * dp.num_act_mats_hor_dir
- power_routing_to_bank.readOp.dynamic
+ power_routing_to_bank.writeOp.dynamic
+ bank.htree_in_data->power.readOp.dynamic
- bank.htree_out_data->power.readOp.dynamic;
if (dp.is_dram == false) {
power.writeOp.dynamic -= bank.mat.power_sa.readOp.dynamic * dp.num_act_mats_hor_dir;
}
dyn_read_energy_from_closed_page = power.readOp.dynamic;
dyn_read_energy_from_open_page = power.readOp.dynamic -
(bank.mat.r_predec->power.readOp.dynamic +
bank.mat.power_row_decoders.readOp.dynamic +
bank.mat.power_bl_precharge_eq_drv.readOp.dynamic +
bank.mat.power_sa.readOp.dynamic +
bank.mat.power_bitline.readOp.dynamic) * dp.num_act_mats_hor_dir;
dyn_read_energy_remaining_words_in_burst =
(MAX((g_ip->burst_len / g_ip->int_prefetch_w), 1) - 1) *
((bank.mat.sa_mux_lev_1_predec->power.readOp.dynamic +
bank.mat.sa_mux_lev_2_predec->power.readOp.dynamic +
bank.mat.power_sa_mux_lev_1_decoders.readOp.dynamic +
bank.mat.power_sa_mux_lev_2_decoders.readOp.dynamic +
bank.mat.power_subarray_out_drv.readOp.dynamic) * dp.num_act_mats_hor_dir +
bank.htree_out_data->power.readOp.dynamic +
power_routing_to_bank.readOp.dynamic);
dyn_read_energy_from_closed_page += dyn_read_energy_remaining_words_in_burst;
dyn_read_energy_from_open_page += dyn_read_energy_remaining_words_in_burst;
activate_energy = htree_in_add->power.readOp.dynamic +
bank.htree_in_add->power_bit.readOp.dynamic * bank.num_addr_b_routed_to_mat_for_act +
(bank.mat.r_predec->power.readOp.dynamic +
bank.mat.power_row_decoders.readOp.dynamic +
bank.mat.power_sa.readOp.dynamic) * dp.num_act_mats_hor_dir;
read_energy = (htree_in_add->power.readOp.dynamic +
bank.htree_in_add->power_bit.readOp.dynamic * bank.num_addr_b_routed_to_mat_for_rd_or_wr +
(bank.mat.sa_mux_lev_1_predec->power.readOp.dynamic +
bank.mat.sa_mux_lev_2_predec->power.readOp.dynamic +
bank.mat.power_sa_mux_lev_1_decoders.readOp.dynamic +
bank.mat.power_sa_mux_lev_2_decoders.readOp.dynamic +
bank.mat.power_subarray_out_drv.readOp.dynamic) * dp.num_act_mats_hor_dir +
bank.htree_out_data->power.readOp.dynamic +
htree_in_data->power.readOp.dynamic) * g_ip->burst_len;
write_energy = (htree_in_add->power.readOp.dynamic +
bank.htree_in_add->power_bit.readOp.dynamic * bank.num_addr_b_routed_to_mat_for_rd_or_wr +
htree_in_data->power.readOp.dynamic +
bank.htree_in_data->power.readOp.dynamic +
(bank.mat.sa_mux_lev_1_predec->power.readOp.dynamic +
bank.mat.sa_mux_lev_2_predec->power.readOp.dynamic +
bank.mat.power_sa_mux_lev_1_decoders.readOp.dynamic +
bank.mat.power_sa_mux_lev_2_decoders.readOp.dynamic) * dp.num_act_mats_hor_dir) * g_ip->burst_len;
precharge_energy = (bank.mat.power_bitline.readOp.dynamic +
bank.mat.power_bl_precharge_eq_drv.readOp.dynamic) * dp.num_act_mats_hor_dir;
leak_power_subbank_closed_page =
(bank.mat.r_predec->power.readOp.leakage +
bank.mat.b_mux_predec->power.readOp.leakage +
bank.mat.sa_mux_lev_1_predec->power.readOp.leakage +
bank.mat.sa_mux_lev_2_predec->power.readOp.leakage +
bank.mat.power_row_decoders.readOp.leakage +
bank.mat.power_bit_mux_decoders.readOp.leakage +
bank.mat.power_sa_mux_lev_1_decoders.readOp.leakage +
bank.mat.power_sa_mux_lev_2_decoders.readOp.leakage +
bank.mat.leak_power_sense_amps_closed_page_state) * dp.num_act_mats_hor_dir;
leak_power_subbank_closed_page +=
(bank.mat.r_predec->power.readOp.gate_leakage +
bank.mat.b_mux_predec->power.readOp.gate_leakage +
bank.mat.sa_mux_lev_1_predec->power.readOp.gate_leakage +
bank.mat.sa_mux_lev_2_predec->power.readOp.gate_leakage +
bank.mat.power_row_decoders.readOp.gate_leakage +
bank.mat.power_bit_mux_decoders.readOp.gate_leakage +
bank.mat.power_sa_mux_lev_1_decoders.readOp.gate_leakage +
bank.mat.power_sa_mux_lev_2_decoders.readOp.gate_leakage) * dp.num_act_mats_hor_dir; //+
//bank.mat.leak_power_sense_amps_closed_page_state) * dp.num_act_mats_hor_dir;
leak_power_subbank_open_page =
(bank.mat.r_predec->power.readOp.leakage +
bank.mat.b_mux_predec->power.readOp.leakage +
bank.mat.sa_mux_lev_1_predec->power.readOp.leakage +
bank.mat.sa_mux_lev_2_predec->power.readOp.leakage +
bank.mat.power_row_decoders.readOp.leakage +
bank.mat.power_bit_mux_decoders.readOp.leakage +
bank.mat.power_sa_mux_lev_1_decoders.readOp.leakage +
bank.mat.power_sa_mux_lev_2_decoders.readOp.leakage +
bank.mat.leak_power_sense_amps_open_page_state) * dp.num_act_mats_hor_dir;
leak_power_subbank_open_page +=
(bank.mat.r_predec->power.readOp.gate_leakage +
bank.mat.b_mux_predec->power.readOp.gate_leakage +
bank.mat.sa_mux_lev_1_predec->power.readOp.gate_leakage +
bank.mat.sa_mux_lev_2_predec->power.readOp.gate_leakage +
bank.mat.power_row_decoders.readOp.gate_leakage +
bank.mat.power_bit_mux_decoders.readOp.gate_leakage +
bank.mat.power_sa_mux_lev_1_decoders.readOp.gate_leakage +
bank.mat.power_sa_mux_lev_2_decoders.readOp.gate_leakage ) * dp.num_act_mats_hor_dir;
//bank.mat.leak_power_sense_amps_open_page_state) * dp.num_act_mats_hor_dir;
leak_power_request_and_reply_networks =
power_routing_to_bank.readOp.leakage +
bank.htree_in_add->power.readOp.leakage +
bank.htree_in_data->power.readOp.leakage +
bank.htree_out_data->power.readOp.leakage;
leak_power_request_and_reply_networks +=
power_routing_to_bank.readOp.gate_leakage +
bank.htree_in_add->power.readOp.gate_leakage +
bank.htree_in_data->power.readOp.gate_leakage +
bank.htree_out_data->power.readOp.gate_leakage;
if (dp.fully_assoc || dp.pure_cam) {
leak_power_request_and_reply_networks += htree_in_search->power.readOp.leakage + htree_out_search->power.readOp.leakage;
leak_power_request_and_reply_networks += htree_in_search->power.readOp.gate_leakage + htree_out_search->power.readOp.gate_leakage;
}
// if DRAM, add contribution of power spent in row predecoder drivers,
// blocks and decoders to refresh power
if (dp.is_dram) {
refresh_power = (bank.mat.r_predec->power.readOp.dynamic * dp.num_act_mats_hor_dir +
bank.mat.row_dec->power.readOp.dynamic) * dp.num_r_subarray * dp.num_subarrays;
refresh_power += bank.mat.per_bitline_read_energy * dp.num_c_subarray * dp.num_r_subarray * dp.num_subarrays;
refresh_power += bank.mat.power_bl_precharge_eq_drv.readOp.dynamic * dp.num_act_mats_hor_dir;
refresh_power += bank.mat.power_sa.readOp.dynamic * dp.num_act_mats_hor_dir;
refresh_power /= dp.dram_refresh_period;
}
if (dp.is_tag == false) {
power.readOp.dynamic = dyn_read_energy_from_closed_page;
power.writeOp.dynamic = dyn_read_energy_from_closed_page
- dyn_read_energy_remaining_words_in_burst
- bank.mat.power_bitline.readOp.dynamic * dp.num_act_mats_hor_dir
+ bank.mat.power_bitline.writeOp.dynamic * dp.num_act_mats_hor_dir
+ (power_routing_to_bank.writeOp.dynamic -
power_routing_to_bank.readOp.dynamic -
bank.htree_out_data->power.readOp.dynamic +
bank.htree_in_data->power.readOp.dynamic) *
(MAX((g_ip->burst_len / g_ip->int_prefetch_w), 1) - 1); //FIXME
if (dp.is_dram == false) {
power.writeOp.dynamic -= bank.mat.power_sa.readOp.dynamic * dp.num_act_mats_hor_dir;
}
}
// if DRAM, add refresh power to total leakage
if (dp.is_dram) {
power.readOp.leakage += refresh_power;
}
// TODO: below should be avoided.
/*if (dp.is_main_mem)
{
power.readOp.leakage += MAIN_MEM_PER_CHIP_STANDBY_CURRENT_mA * 1e-3 * g_tp.peri_global.Vdd / g_ip->nbanks;
}*/
assert(power.readOp.dynamic > 0);
assert(power.writeOp.dynamic > 0);
assert(power.readOp.leakage > 0);
}