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authorAnthony Gutierrez <atgutier@umich.edu>2014-04-01 12:44:30 -0400
committerAnthony Gutierrez <atgutier@umich.edu>2014-04-01 12:44:30 -0400
commite553a7bfa7f0eb47b78632cd63e6e1e814025c9a (patch)
treef69a8e3e0ed55b95bf276b6f857793b9ef7b6490 /ext/mcpat/cacti/parameter.cc
parent8d665ee166bf5476bb9b73a0016843ff9953c266 (diff)
downloadgem5-e553a7bfa7f0eb47b78632cd63e6e1e814025c9a.tar.xz
ext: add McPAT source
this patch adds the source for mcpat, a power, area, and timing modeling framework.
Diffstat (limited to 'ext/mcpat/cacti/parameter.cc')
-rw-r--r--ext/mcpat/cacti/parameter.cc713
1 files changed, 713 insertions, 0 deletions
diff --git a/ext/mcpat/cacti/parameter.cc b/ext/mcpat/cacti/parameter.cc
new file mode 100644
index 000000000..b71640c19
--- /dev/null
+++ b/ext/mcpat/cacti/parameter.cc
@@ -0,0 +1,713 @@
+/*****************************************************************************
+ * McPAT/CACTI
+ * SOFTWARE LICENSE AGREEMENT
+ * Copyright 2012 Hewlett-Packard Development Company, L.P.
+ * 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.”
+ *
+ ***************************************************************************/
+
+
+
+#include <iomanip>
+#include <iostream>
+#include <string>
+
+#include "area.h"
+#include "parameter.h"
+
+using namespace std;
+
+
+InputParameter * g_ip;
+TechnologyParameter g_tp;
+
+
+
+void TechnologyParameter::DeviceType::display(uint32_t indent)
+{
+ string indent_str(indent, ' ');
+
+ cout << indent_str << "C_g_ideal = " << setw(12) << C_g_ideal << " F/um" << endl;
+ cout << indent_str << "C_fringe = " << setw(12) << C_fringe << " F/um" << endl;
+ cout << indent_str << "C_overlap = " << setw(12) << C_overlap << " F/um" << endl;
+ cout << indent_str << "C_junc = " << setw(12) << C_junc << " F/um^2" << endl;
+ cout << indent_str << "l_phy = " << setw(12) << l_phy << " um" << endl;
+ cout << indent_str << "l_elec = " << setw(12) << l_elec << " um" << endl;
+ cout << indent_str << "R_nch_on = " << setw(12) << R_nch_on << " ohm-um" << endl;
+ cout << indent_str << "R_pch_on = " << setw(12) << R_pch_on << " ohm-um" << endl;
+ cout << indent_str << "Vdd = " << setw(12) << Vdd << " V" << endl;
+ cout << indent_str << "Vth = " << setw(12) << Vth << " V" << endl;
+ cout << indent_str << "I_on_n = " << setw(12) << I_on_n << " A/um" << endl;
+ cout << indent_str << "I_on_p = " << setw(12) << I_on_p << " A/um" << endl;
+ cout << indent_str << "I_off_n = " << setw(12) << I_off_n << " A/um" << endl;
+ cout << indent_str << "I_off_p = " << setw(12) << I_off_p << " A/um" << endl;
+ cout << indent_str << "C_ox = " << setw(12) << C_ox << " F/um^2" << endl;
+ cout << indent_str << "t_ox = " << setw(12) << t_ox << " um" << endl;
+ cout << indent_str << "n_to_p_eff_curr_drv_ratio = " << n_to_p_eff_curr_drv_ratio << endl;
+}
+
+
+
+void TechnologyParameter::InterconnectType::display(uint32_t indent)
+{
+ string indent_str(indent, ' ');
+
+ cout << indent_str << "pitch = " << setw(12) << pitch << " um" << endl;
+ cout << indent_str << "R_per_um = " << setw(12) << R_per_um << " ohm/um" << endl;
+ cout << indent_str << "C_per_um = " << setw(12) << C_per_um << " F/um" << endl;
+}
+
+void TechnologyParameter::ScalingFactor::display(uint32_t indent)
+{
+ string indent_str(indent, ' ');
+
+ cout << indent_str << "logic_scaling_co_eff = " << setw(12) << logic_scaling_co_eff << endl;
+ cout << indent_str << "curr_core_tx_density = " << setw(12) << core_tx_density << " # of tx/um^2" << endl;
+}
+
+void TechnologyParameter::MemoryType::display(uint32_t indent)
+{
+ string indent_str(indent, ' ');
+
+ cout << indent_str << "b_w = " << setw(12) << b_w << " um" << endl;
+ cout << indent_str << "b_h = " << setw(12) << b_h << " um" << endl;
+ cout << indent_str << "cell_a_w = " << setw(12) << cell_a_w << " um" << endl;
+ cout << indent_str << "cell_pmos_w = " << setw(12) << cell_pmos_w << " um" << endl;
+ cout << indent_str << "cell_nmos_w = " << setw(12) << cell_nmos_w << " um" << endl;
+ cout << indent_str << "Vbitpre = " << setw(12) << Vbitpre << " V" << endl;
+}
+
+
+
+void TechnologyParameter::display(uint32_t indent)
+{
+ string indent_str(indent, ' ');
+
+ cout << indent_str << "ram_wl_stitching_overhead_ = " << setw(12) << ram_wl_stitching_overhead_ << " um" << endl;
+ cout << indent_str << "min_w_nmos_ = " << setw(12) << min_w_nmos_ << " um" << endl;
+ cout << indent_str << "max_w_nmos_ = " << setw(12) << max_w_nmos_ << " um" << endl;
+ cout << indent_str << "unit_len_wire_del = " << setw(12) << unit_len_wire_del << " s/um^2" << endl;
+ cout << indent_str << "FO4 = " << setw(12) << FO4 << " s" << endl;
+ cout << indent_str << "kinv = " << setw(12) << kinv << " s" << endl;
+ cout << indent_str << "vpp = " << setw(12) << vpp << " V" << endl;
+ cout << indent_str << "w_sense_en = " << setw(12) << w_sense_en << " um" << endl;
+ cout << indent_str << "w_sense_n = " << setw(12) << w_sense_n << " um" << endl;
+ cout << indent_str << "w_sense_p = " << setw(12) << w_sense_p << " um" << endl;
+ cout << indent_str << "w_iso = " << setw(12) << w_iso << " um" << endl;
+ cout << indent_str << "w_poly_contact = " << setw(12) << w_poly_contact << " um" << endl;
+ cout << indent_str << "spacing_poly_to_poly = " << setw(12) << spacing_poly_to_poly << " um" << endl;
+ cout << indent_str << "spacing_poly_to_contact = " << setw(12) << spacing_poly_to_contact << " um" << endl;
+ cout << endl;
+ cout << indent_str << "w_comp_inv_p1 = " << setw(12) << w_comp_inv_p1 << " um" << endl;
+ cout << indent_str << "w_comp_inv_p2 = " << setw(12) << w_comp_inv_p2 << " um" << endl;
+ cout << indent_str << "w_comp_inv_p3 = " << setw(12) << w_comp_inv_p3 << " um" << endl;
+ cout << indent_str << "w_comp_inv_n1 = " << setw(12) << w_comp_inv_n1 << " um" << endl;
+ cout << indent_str << "w_comp_inv_n2 = " << setw(12) << w_comp_inv_n2 << " um" << endl;
+ cout << indent_str << "w_comp_inv_n3 = " << setw(12) << w_comp_inv_n3 << " um" << endl;
+ cout << indent_str << "w_eval_inv_p = " << setw(12) << w_eval_inv_p << " um" << endl;
+ cout << indent_str << "w_eval_inv_n = " << setw(12) << w_eval_inv_n << " um" << endl;
+ cout << indent_str << "w_comp_n = " << setw(12) << w_comp_n << " um" << endl;
+ cout << indent_str << "w_comp_p = " << setw(12) << w_comp_p << " um" << endl;
+ cout << endl;
+ cout << indent_str << "dram_cell_I_on = " << setw(12) << dram_cell_I_on << " A/um" << endl;
+ cout << indent_str << "dram_cell_Vdd = " << setw(12) << dram_cell_Vdd << " V" << endl;
+ cout << indent_str << "dram_cell_I_off_worst_case_len_temp = " << setw(12) << dram_cell_I_off_worst_case_len_temp << " A/um" << endl;
+ cout << indent_str << "dram_cell_C = " << setw(12) << dram_cell_C << " F" << endl;
+ cout << indent_str << "gm_sense_amp_latch = " << setw(12) << gm_sense_amp_latch << " F/s" << endl;
+ cout << endl;
+ cout << indent_str << "w_nmos_b_mux = " << setw(12) << w_nmos_b_mux << " um" << endl;
+ cout << indent_str << "w_nmos_sa_mux = " << setw(12) << w_nmos_sa_mux << " um" << endl;
+ cout << indent_str << "w_pmos_bl_precharge = " << setw(12) << w_pmos_bl_precharge << " um" << endl;
+ cout << indent_str << "w_pmos_bl_eq = " << setw(12) << w_pmos_bl_eq << " um" << endl;
+ cout << indent_str << "MIN_GAP_BET_P_AND_N_DIFFS = " << setw(12) << MIN_GAP_BET_P_AND_N_DIFFS << " um" << endl;
+ cout << indent_str << "HPOWERRAIL = " << setw(12) << HPOWERRAIL << " um" << endl;
+ cout << indent_str << "cell_h_def = " << setw(12) << cell_h_def << " um" << endl;
+
+ cout << endl;
+ cout << indent_str << "SRAM cell transistor: " << endl;
+ sram_cell.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "DRAM access transistor: " << endl;
+ dram_acc.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "DRAM wordline transistor: " << endl;
+ dram_wl.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "peripheral global transistor: " << endl;
+ peri_global.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "wire local" << endl;
+ wire_local.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "wire inside mat" << endl;
+ wire_inside_mat.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "wire outside mat" << endl;
+ wire_outside_mat.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "SRAM" << endl;
+ sram.display(indent + 2);
+
+ cout << endl;
+ cout << indent_str << "DRAM" << endl;
+ dram.display(indent + 2);
+}
+
+
+DynamicParameter::DynamicParameter():
+ use_inp_params(0), cell(), is_valid(true)
+{
+}
+
+
+
+DynamicParameter::DynamicParameter(
+ bool is_tag_,
+ int pure_ram_,
+ int pure_cam_,
+ double Nspd_,
+ unsigned int Ndwl_,
+ unsigned int Ndbl_,
+ unsigned int Ndcm_,
+ unsigned int Ndsam_lev_1_,
+ unsigned int Ndsam_lev_2_,
+ bool is_main_mem_):
+ is_tag(is_tag_), pure_ram(pure_ram_), pure_cam(pure_cam_), tagbits(0), Nspd(Nspd_), Ndwl(Ndwl_), Ndbl(Ndbl_),Ndcm(Ndcm_),
+ Ndsam_lev_1(Ndsam_lev_1_), Ndsam_lev_2(Ndsam_lev_2_),
+ number_way_select_signals_mat(0), V_b_sense(0), use_inp_params(0),
+ is_main_mem(is_main_mem_), cell(), is_valid(false)
+{
+ ram_cell_tech_type = (is_tag) ? g_ip->tag_arr_ram_cell_tech_type : g_ip->data_arr_ram_cell_tech_type;
+ is_dram = ((ram_cell_tech_type == lp_dram) || (ram_cell_tech_type == comm_dram));
+
+ unsigned int capacity_per_die = g_ip->cache_sz / NUMBER_STACKED_DIE_LAYERS; // capacity per stacked die layer
+ const TechnologyParameter::InterconnectType & wire_local = g_tp.wire_local;
+ fully_assoc = (g_ip->fully_assoc) ? true : false;
+
+ if (fully_assoc || pure_cam)
+ { // fully-assocative cache -- ref: CACTi 2.0 report
+ if (Ndwl != 1 || //Ndwl is fixed to 1 for FA
+ Ndcm != 1 || //Ndcm is fixed to 1 for FA
+ Nspd < 1 || Nspd > 1 || //Nspd is fixed to 1 for FA
+ Ndsam_lev_1 != 1 || //Ndsam_lev_1 is fixed to one
+ Ndsam_lev_2 != 1 || //Ndsam_lev_2 is fixed to one
+ Ndbl < 2)
+ {
+ return;
+ }
+ }
+
+ if ((is_dram) && (!is_tag) && (Ndcm > 1))
+ {
+ return; // For a DRAM array, each bitline has its own sense-amp
+ }
+
+ // If it's not an FA tag/data array, Ndwl should be at least two and Ndbl should be
+ // at least two because an array is assumed to have at least one mat. And a mat
+ // is formed out of two horizontal subarrays and two vertical subarrays
+ if (fully_assoc == false && (Ndwl < 1 || Ndbl < 1))
+ {
+ return;
+ }
+
+ //***********compute row, col of an subarray
+ if (!(fully_assoc || pure_cam))//Not fully_asso nor cam
+ {
+ // if data array, let tagbits = 0
+ if (is_tag)
+ {
+ if (g_ip->specific_tag)
+ {
+ tagbits = g_ip->tag_w;
+ }
+ else
+ {
+ tagbits = ADDRESS_BITS + EXTRA_TAG_BITS - _log2(capacity_per_die) +
+ _log2(g_ip->tag_assoc*2 - 1) - _log2(g_ip->nbanks);
+
+ }
+ tagbits = (((tagbits + 3) >> 2) << 2);
+
+ num_r_subarray = (int)ceil(capacity_per_die / (g_ip->nbanks *
+ g_ip->block_sz * g_ip->tag_assoc * Ndbl * Nspd));// + EPSILON);
+ num_c_subarray = (int)ceil((tagbits * g_ip->tag_assoc * Nspd / Ndwl));// + EPSILON);
+ //burst_length = 1;
+ }
+ else
+ {
+ num_r_subarray = (int)ceil(capacity_per_die / (g_ip->nbanks *
+ g_ip->block_sz * g_ip->data_assoc * Ndbl * Nspd));// + EPSILON);
+ num_c_subarray = (int)ceil((8 * g_ip->block_sz * g_ip->data_assoc * Nspd / Ndwl));// + EPSILON); + EPSILON);
+ // burst_length = g_ip->block_sz * 8 / g_ip->out_w;
+ }
+
+ if (num_r_subarray < MINSUBARRAYROWS) return;
+ if (num_r_subarray == 0) return;
+ if (num_r_subarray > MAXSUBARRAYROWS) return;
+ if (num_c_subarray < MINSUBARRAYCOLS) return;
+ if (num_c_subarray > MAXSUBARRAYCOLS) return;
+
+ }
+
+ else
+ {//either fully-asso or cam
+ if (pure_cam)
+ {
+ if (g_ip->specific_tag)
+ {
+ tagbits = int(ceil(g_ip->tag_w/8.0)*8);
+ }
+ else
+ {
+ tagbits = int(ceil((ADDRESS_BITS + EXTRA_TAG_BITS)/8.0)*8);
+// cout<<"Pure CAM needs tag width to be specified"<<endl;
+// exit(0);
+ }
+ //tagbits = (((tagbits + 3) >> 2) << 2);
+
+ tag_num_r_subarray = (int)ceil(capacity_per_die / (g_ip->nbanks*tagbits/8.0 * Ndbl));//TODO: error check input of tagbits and blocksize //TODO: for pure CAM, g_ip->block should be number of entries.
+ //tag_num_c_subarray = (int)(tagbits + EPSILON);
+ tag_num_c_subarray = tagbits;
+ if (tag_num_r_subarray == 0) return;
+ if (tag_num_r_subarray > MAXSUBARRAYROWS) return;
+ if (tag_num_c_subarray < MINSUBARRAYCOLS) return;
+ if (tag_num_c_subarray > MAXSUBARRAYCOLS) return;
+ num_r_subarray = tag_num_r_subarray;
+ }
+ else //fully associative
+ {
+ if (g_ip->specific_tag)
+ {
+ tagbits = g_ip->tag_w;
+ }
+ else
+ {
+ tagbits = ADDRESS_BITS + EXTRA_TAG_BITS - _log2(g_ip->block_sz);//TODO: should be the page_offset=log2(page size), but this info is not avail with CACTI, for McPAT this is no problem.
+ }
+ tagbits = (((tagbits + 3) >> 2) << 2);
+
+ tag_num_r_subarray = (int)(capacity_per_die / (g_ip->nbanks*g_ip->block_sz * Ndbl));
+ tag_num_c_subarray = (int)ceil((tagbits * Nspd / Ndwl));// + EPSILON);
+ if (tag_num_r_subarray == 0) return;
+ if (tag_num_r_subarray > MAXSUBARRAYROWS) return;
+ if (tag_num_c_subarray < MINSUBARRAYCOLS) return;
+ if (tag_num_c_subarray > MAXSUBARRAYCOLS) return;
+
+ data_num_r_subarray = tag_num_r_subarray;
+ data_num_c_subarray = 8 * g_ip->block_sz;
+ if (data_num_r_subarray == 0) return;
+ if (data_num_r_subarray > MAXSUBARRAYROWS) return;
+ if (data_num_c_subarray < MINSUBARRAYCOLS) return;
+ if (data_num_c_subarray > MAXSUBARRAYCOLS) return;
+ num_r_subarray = tag_num_r_subarray;
+ }
+ }
+
+ num_subarrays = Ndwl * Ndbl;
+ //****************end of computation of row, col of an subarray
+
+ // calculate wire parameters
+ if (fully_assoc || pure_cam)
+ {
+ cam_cell.h = g_tp.cam.b_h + 2 * wire_local.pitch * (g_ip->num_rw_ports-1 + g_ip->num_rd_ports + g_ip->num_wr_ports)
+ + 2 * wire_local.pitch*(g_ip->num_search_ports-1) + wire_local.pitch * g_ip->num_se_rd_ports;
+ cam_cell.w = g_tp.cam.b_w + 2 * wire_local.pitch * (g_ip->num_rw_ports-1 + g_ip->num_rd_ports + g_ip->num_wr_ports)
+ + 2 * wire_local.pitch*(g_ip->num_search_ports-1) + wire_local.pitch * g_ip->num_se_rd_ports;
+
+ cell.h = g_tp.sram.b_h + 2 * wire_local.pitch * (g_ip->num_wr_ports +g_ip->num_rw_ports-1 + g_ip->num_rd_ports)
+ + 2 * wire_local.pitch*(g_ip->num_search_ports-1);
+ cell.w = g_tp.sram.b_w + 2 * wire_local.pitch * (g_ip->num_rw_ports -1 + (g_ip->num_rd_ports - g_ip->num_se_rd_ports)
+ + g_ip->num_wr_ports) + g_tp.wire_local.pitch * g_ip->num_se_rd_ports + 2 * wire_local.pitch*(g_ip->num_search_ports-1);
+ }
+ else
+ {
+ if(is_tag)
+ {
+ cell.h = g_tp.sram.b_h + 2 * wire_local.pitch * (g_ip->num_rw_ports - 1 + g_ip->num_rd_ports +
+ g_ip->num_wr_ports);
+ cell.w = g_tp.sram.b_w + 2 * wire_local.pitch * (g_ip->num_rw_ports - 1 + g_ip->num_wr_ports +
+ (g_ip->num_rd_ports - g_ip->num_se_rd_ports)) +
+ wire_local.pitch * g_ip->num_se_rd_ports;
+ }
+ else
+ {
+ if (is_dram)
+ {
+ cell.h = g_tp.dram.b_h;
+ cell.w = g_tp.dram.b_w;
+ }
+ else
+ {
+ cell.h = g_tp.sram.b_h + 2 * wire_local.pitch * (g_ip->num_wr_ports +
+ g_ip->num_rw_ports - 1 + g_ip->num_rd_ports);
+ cell.w = g_tp.sram.b_w + 2 * wire_local.pitch * (g_ip->num_rw_ports - 1 +
+ (g_ip->num_rd_ports - g_ip->num_se_rd_ports) +
+ g_ip->num_wr_ports) + g_tp.wire_local.pitch * g_ip->num_se_rd_ports;
+ }
+ }
+ }
+
+ double c_b_metal = cell.h * wire_local.C_per_um;
+ double C_bl;
+
+ if (!(fully_assoc || pure_cam))
+ {
+ if (is_dram)
+ {
+ deg_bl_muxing = 1;
+ if (ram_cell_tech_type == comm_dram)
+ {
+ C_bl = num_r_subarray * c_b_metal;
+ V_b_sense = (g_tp.dram_cell_Vdd/2) * g_tp.dram_cell_C / (g_tp.dram_cell_C + C_bl);
+ if (V_b_sense < VBITSENSEMIN)
+ {
+ return;
+ }
+ V_b_sense = VBITSENSEMIN; // in any case, we fix sense amp input signal to a constant value
+ dram_refresh_period = 64e-3;
+ }
+ else
+ {
+ double Cbitrow_drain_cap = drain_C_(g_tp.dram.cell_a_w, NCH, 1, 0, cell.w, true, true) / 2.0;
+ C_bl = num_r_subarray * (Cbitrow_drain_cap + c_b_metal);
+ V_b_sense = (g_tp.dram_cell_Vdd/2) * g_tp.dram_cell_C /(g_tp.dram_cell_C + C_bl);
+
+ if (V_b_sense < VBITSENSEMIN)
+ {
+ return; //Sense amp input signal is smaller that minimum allowable sense amp input signal
+ }
+ V_b_sense = VBITSENSEMIN; // in any case, we fix sense amp input signal to a constant value
+ //v_storage_worst = g_tp.dram_cell_Vdd / 2 - VBITSENSEMIN * (g_tp.dram_cell_C + C_bl) / g_tp.dram_cell_C;
+ //dram_refresh_period = 1.1 * g_tp.dram_cell_C * v_storage_worst / g_tp.dram_cell_I_off_worst_case_len_temp;
+ dram_refresh_period = 0.9 * g_tp.dram_cell_C * VDD_STORAGE_LOSS_FRACTION_WORST * g_tp.dram_cell_Vdd / g_tp.dram_cell_I_off_worst_case_len_temp;
+ }
+ }
+ else
+ { //SRAM
+ V_b_sense = (0.05 * g_tp.sram_cell.Vdd > VBITSENSEMIN) ? 0.05 * g_tp.sram_cell.Vdd : VBITSENSEMIN;
+ deg_bl_muxing = Ndcm;
+ // "/ 2.0" below is due to the fact that two adjacent access transistors share drain
+ // contacts in a physical layout
+ double Cbitrow_drain_cap = drain_C_(g_tp.sram.cell_a_w, NCH, 1, 0, cell.w, false, true) / 2.0;
+ C_bl = num_r_subarray * (Cbitrow_drain_cap + c_b_metal);
+ dram_refresh_period = 0;
+ }
+ }
+ else
+ {
+ c_b_metal = cam_cell.h * wire_local.C_per_um;//IBM and SUN design, SRAM array uses dummy cells to fill the blank space due to mismatch on CAM-RAM
+ V_b_sense = (0.05 * g_tp.sram_cell.Vdd > VBITSENSEMIN) ? 0.05 * g_tp.sram_cell.Vdd : VBITSENSEMIN;
+ deg_bl_muxing = 1;//FA fix as 1
+ // "/ 2.0" below is due to the fact that two adjacent access transistors share drain
+ // contacts in a physical layout
+ double Cbitrow_drain_cap = drain_C_(g_tp.cam.cell_a_w, NCH, 1, 0, cam_cell.w, false, true) / 2.0;//TODO: comment out these two lines
+ C_bl = num_r_subarray * (Cbitrow_drain_cap + c_b_metal);
+ dram_refresh_period = 0;
+ }
+
+
+ // do/di: data in/out, for fully associative they are the data width for normal read and write
+ // so/si: search data in/out, for fully associative they are the data width for the search ops
+ // for CAM, si=di, but so = matching address. do = data out = di (for normal read/write)
+ // so/si needs broadcase while do/di do not
+
+ if (fully_assoc || pure_cam)
+ {
+ switch (Ndbl) {
+ case (0):
+ cout << " Invalid Ndbl \n"<<endl;
+ exit(0);
+ break;
+ case (1):
+ num_mats_h_dir = 1;//one subarray per mat
+ num_mats_v_dir = 1;
+ break;
+ case (2):
+ num_mats_h_dir = 1;//two subarrays per mat
+ num_mats_v_dir = 1;
+ break;
+ default:
+ num_mats_h_dir = int(floor(sqrt(Ndbl/4.0)));//4 subbarrys per mat
+ num_mats_v_dir = int(Ndbl/4.0 / num_mats_h_dir);
+ }
+ num_mats = num_mats_h_dir * num_mats_v_dir;
+
+ if (fully_assoc)
+ {
+ num_so_b_mat = data_num_c_subarray;
+ num_do_b_mat = data_num_c_subarray + tagbits;
+ }
+ else
+ {
+ num_so_b_mat = int(ceil(log2(num_r_subarray)) + ceil(log2(num_subarrays)));//the address contains the matched data
+ num_do_b_mat = tagbits;
+ }
+ }
+ else
+ {
+ num_mats_h_dir = MAX(Ndwl / 2, 1);
+ num_mats_v_dir = MAX(Ndbl / 2, 1);
+ num_mats = num_mats_h_dir * num_mats_v_dir;
+ num_do_b_mat = MAX((num_subarrays/num_mats) * num_c_subarray / (deg_bl_muxing * Ndsam_lev_1 * Ndsam_lev_2), 1);
+ }
+
+ if (!(fully_assoc|| pure_cam) && (num_do_b_mat < (num_subarrays/num_mats)))
+ {
+ return;
+ }
+
+
+ int deg_sa_mux_l1_non_assoc;
+ //TODO:the i/o for subbank is not necessary and should be removed.
+ if (!(fully_assoc || pure_cam))
+ {
+ if (!is_tag)
+ {
+ if (is_main_mem == true)
+ {
+ num_do_b_subbank = g_ip->int_prefetch_w * g_ip->out_w;
+ deg_sa_mux_l1_non_assoc = Ndsam_lev_1;
+ }
+ else
+ {
+ if (g_ip->fast_access == true)
+ {
+ num_do_b_subbank = g_ip->out_w * g_ip->data_assoc;
+ deg_sa_mux_l1_non_assoc = Ndsam_lev_1;
+ }
+ else
+ {
+
+ num_do_b_subbank = g_ip->out_w;
+ deg_sa_mux_l1_non_assoc = Ndsam_lev_1 / g_ip->data_assoc;
+ if (deg_sa_mux_l1_non_assoc < 1)
+ {
+ return;
+ }
+
+ }
+ }
+ }
+ else
+ {
+ num_do_b_subbank = tagbits * g_ip->tag_assoc;
+ if (num_do_b_mat < tagbits)
+ {
+ return;
+ }
+ deg_sa_mux_l1_non_assoc = Ndsam_lev_1;
+ //num_do_b_mat = g_ip->tag_assoc / num_mats_h_dir;
+ }
+ }
+ else
+ {
+ if (fully_assoc)
+ {
+ num_so_b_subbank = 8 * g_ip->block_sz;//TODO:internal perfetch should be considered also for fa
+ num_do_b_subbank = num_so_b_subbank + tag_num_c_subarray;
+ }
+ else
+ {
+ num_so_b_subbank = int(ceil(log2(num_r_subarray)) + ceil(log2(num_subarrays)));//the address contains the matched data
+ num_do_b_subbank = tag_num_c_subarray;
+ }
+
+ deg_sa_mux_l1_non_assoc = 1;
+ }
+
+ deg_senseamp_muxing_non_associativity = deg_sa_mux_l1_non_assoc;
+
+ if (fully_assoc || pure_cam)
+ {
+ num_act_mats_hor_dir = 1;
+ num_act_mats_hor_dir_sl = num_mats_h_dir;//TODO: this is unnecessary, since search op, num_mats is used
+ }
+ else
+ {
+ num_act_mats_hor_dir = num_do_b_subbank / num_do_b_mat;
+ if (num_act_mats_hor_dir == 0)
+ {
+ return;
+ }
+ }
+
+ //compute num_do_mat for tag
+ if (is_tag)
+ {
+ if (!(fully_assoc || pure_cam))
+ {
+ num_do_b_mat = g_ip->tag_assoc / num_act_mats_hor_dir;
+ num_do_b_subbank = num_act_mats_hor_dir * num_do_b_mat;
+ }
+ }
+
+ if ((g_ip->is_cache == false && is_main_mem == true) || (PAGE_MODE == 1 && is_dram))
+ {
+ if (num_act_mats_hor_dir * num_do_b_mat * Ndsam_lev_1 * Ndsam_lev_2 != (int)g_ip->page_sz_bits)
+ {
+ return;
+ }
+ }
+
+// if (is_tag == false && g_ip->is_cache == true && !fully_assoc && !pure_cam && //TODO: TODO burst transfer should also apply to RAM arrays
+ if (is_tag == false && g_ip->is_main_mem == true &&
+ num_act_mats_hor_dir*num_do_b_mat*Ndsam_lev_1*Ndsam_lev_2 < ((int) g_ip->out_w * (int) g_ip->burst_len * (int) g_ip->data_assoc))
+ {
+ return;
+ }
+
+ if (num_act_mats_hor_dir > num_mats_h_dir)
+ {
+ return;
+ }
+
+
+ //compute di for mat subbank and bank
+ if (!(fully_assoc ||pure_cam))
+ {
+ if(!is_tag)
+ {
+ if(g_ip->fast_access == true)
+ {
+ num_di_b_mat = num_do_b_mat / g_ip->data_assoc;
+ }
+ else
+ {
+ num_di_b_mat = num_do_b_mat;
+ }
+ }
+ else
+ {
+ num_di_b_mat = tagbits;
+ }
+ }
+ else
+ {
+ if (fully_assoc)
+ {
+ num_di_b_mat = num_do_b_mat;
+ //*num_subarrays/num_mats; bits per mat of CAM/FA is as same as cache,
+ //but inside the mat wire tracks need to be reserved for search data bus
+ num_si_b_mat = tagbits;
+ }
+ else
+ {
+ num_di_b_mat = tagbits;
+ num_si_b_mat = tagbits;//*num_subarrays/num_mats;
+ }
+
+ }
+
+ num_di_b_subbank = num_di_b_mat * num_act_mats_hor_dir;//normal cache or normal r/w for FA
+ num_si_b_subbank = num_si_b_mat; //* num_act_mats_hor_dir_sl; inside the data is broadcast
+
+ int num_addr_b_row_dec = _log2(num_r_subarray);
+ if ((fully_assoc ||pure_cam))
+ num_addr_b_row_dec +=_log2(num_subarrays/num_mats);
+ int number_subbanks = num_mats / num_act_mats_hor_dir;
+ number_subbanks_decode = _log2(number_subbanks);//TODO: add log2(num_subarray_per_bank) to FA/CAM
+
+ num_rw_ports = g_ip->num_rw_ports;
+ num_rd_ports = g_ip->num_rd_ports;
+ num_wr_ports = g_ip->num_wr_ports;
+ num_se_rd_ports = g_ip->num_se_rd_ports;
+ num_search_ports = g_ip->num_search_ports;
+
+ if (is_dram && is_main_mem)
+ {
+ number_addr_bits_mat = MAX((unsigned int) num_addr_b_row_dec,
+ _log2(deg_bl_muxing) + _log2(deg_sa_mux_l1_non_assoc) + _log2(Ndsam_lev_2));
+ }
+ else
+ {
+ number_addr_bits_mat = num_addr_b_row_dec + _log2(deg_bl_muxing) +
+ _log2(deg_sa_mux_l1_non_assoc) + _log2(Ndsam_lev_2);
+ }
+
+ if (!(fully_assoc ||pure_cam))
+ {
+ if (is_tag)
+ {
+ num_di_b_bank_per_port = tagbits;
+ num_do_b_bank_per_port = g_ip->data_assoc;
+ }
+ else
+ {
+ num_di_b_bank_per_port = g_ip->out_w + g_ip->data_assoc;
+ num_do_b_bank_per_port = g_ip->out_w;
+ }
+ }
+ else
+ {
+ if (fully_assoc)
+ {
+ num_di_b_bank_per_port = g_ip->out_w + tagbits;//TODO: out_w or block_sz?
+ num_si_b_bank_per_port = tagbits;
+ num_do_b_bank_per_port = g_ip->out_w + tagbits;
+ num_so_b_bank_per_port = g_ip->out_w;
+ }
+ else
+ {
+ num_di_b_bank_per_port = tagbits;
+ num_si_b_bank_per_port = tagbits;
+ num_do_b_bank_per_port = tagbits;
+ num_so_b_bank_per_port = int(ceil(log2(num_r_subarray)) + ceil(log2(num_subarrays)));
+ }
+ }
+
+ if ((!is_tag) && (g_ip->data_assoc > 1) && (!g_ip->fast_access))
+ {
+ number_way_select_signals_mat = g_ip->data_assoc;
+ }
+
+ // add ECC adjustment to all data signals that traverse on H-trees.
+ if (g_ip->add_ecc_b_ == true)
+ {
+ num_do_b_mat += (int) (ceil(num_do_b_mat / num_bits_per_ecc_b_));
+ num_di_b_mat += (int) (ceil(num_di_b_mat / num_bits_per_ecc_b_));
+ num_di_b_subbank += (int) (ceil(num_di_b_subbank / num_bits_per_ecc_b_));
+ num_do_b_subbank += (int) (ceil(num_do_b_subbank / num_bits_per_ecc_b_));
+ num_di_b_bank_per_port += (int) (ceil(num_di_b_bank_per_port / num_bits_per_ecc_b_));
+ num_do_b_bank_per_port += (int) (ceil(num_do_b_bank_per_port / num_bits_per_ecc_b_));
+
+ num_so_b_mat += (int) (ceil(num_so_b_mat / num_bits_per_ecc_b_));
+ num_si_b_mat += (int) (ceil(num_si_b_mat / num_bits_per_ecc_b_));
+ num_si_b_subbank += (int) (ceil(num_si_b_subbank / num_bits_per_ecc_b_));
+ num_so_b_subbank += (int) (ceil(num_so_b_subbank / num_bits_per_ecc_b_));
+ num_si_b_bank_per_port += (int) (ceil(num_si_b_bank_per_port / num_bits_per_ecc_b_));
+ num_so_b_bank_per_port += (int) (ceil(num_so_b_bank_per_port / num_bits_per_ecc_b_));
+ }
+
+ is_valid = true;
+}
+