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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.
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#include <cassert>
#include <iostream>
#include "htree2.h"
#include "wire.h"
Htree2::Htree2(
enum Wire_type wire_model, double mat_w, double mat_h,
int a_bits, int d_inbits, int search_data_in, int d_outbits,
int search_data_out, int bl, int wl, enum Htree_type htree_type,
bool uca_tree_, bool search_tree_, TechnologyParameter::DeviceType *dt)
: in_rise_time(0), out_rise_time(0),
tree_type(htree_type), mat_width(mat_w), mat_height(mat_h),
add_bits(a_bits), data_in_bits(d_inbits),
search_data_in_bits(search_data_in), data_out_bits(d_outbits),
search_data_out_bits(search_data_out), ndbl(bl), ndwl(wl),
uca_tree(uca_tree_), search_tree(search_tree_), wt(wire_model),
deviceType(dt) {
assert(ndbl >= 2 && ndwl >= 2);
// if (ndbl == 1 && ndwl == 1)
// {
// delay = 0;
// power.readOp.dynamic = 0;
// power.readOp.leakage = 0;
// area.w = mat_w;
// area.h = mat_h;
// return;
// }
// if (ndwl == 1) ndwl++;
// if (ndbl == 1) ndbl++;
max_unpipelined_link_delay = 0; //TODO
min_w_nmos = g_tp.min_w_nmos_;
min_w_pmos = deviceType->n_to_p_eff_curr_drv_ratio * min_w_nmos;
switch (htree_type) {
case Add_htree:
wire_bw = init_wire_bw = add_bits;
in_htree();
break;
case Data_in_htree:
wire_bw = init_wire_bw = data_in_bits;
in_htree();
break;
case Data_out_htree:
wire_bw = init_wire_bw = data_out_bits;
out_htree();
break;
case Search_in_htree:
wire_bw = init_wire_bw = search_data_in_bits;//in_search_tree is broad cast, out_htree is not.
in_htree();
break;
case Search_out_htree:
wire_bw = init_wire_bw = search_data_out_bits;
out_htree();
break;
default:
assert(0);
break;
}
power_bit = power;
power.readOp.dynamic *= init_wire_bw;
assert(power.readOp.dynamic >= 0);
assert(power.readOp.leakage >= 0);
}
// nand gate sizing calculation
void Htree2::input_nand(double s1, double s2, double l_eff) {
Wire w1(wt, l_eff);
double pton_size = deviceType->n_to_p_eff_curr_drv_ratio;
// input capacitance of a repeater = input capacitance of nand.
double nsize = s1 * (1 + pton_size) / (2 + pton_size);
nsize = (nsize < 1) ? 1 : nsize;
double tc = 2 * tr_R_on(nsize * min_w_nmos, NCH, 1) *
(drain_C_(nsize * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def) * 2 +
2 * gate_C(s2 * (min_w_nmos + min_w_pmos), 0));
delay += horowitz(w1.out_rise_time, tc,
deviceType->Vth / deviceType->Vdd, deviceType->Vth /
deviceType->Vdd, RISE);
power.readOp.dynamic += 0.5 *
(2 * drain_C_(pton_size * nsize * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ drain_C_(nsize * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)
+ 2 * gate_C(s2 * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd;
power.searchOp.dynamic += 0.5 *
(2 * drain_C_(pton_size * nsize * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ drain_C_(nsize * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)
+ 2 * gate_C(s2 * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd * wire_bw ;
power.readOp.leakage += (wire_bw *
cmos_Isub_leakage(min_w_nmos * (nsize * 2),
min_w_pmos * nsize * 2, 2,
nand)) * deviceType->Vdd;
power.readOp.gate_leakage += (wire_bw *
cmos_Ig_leakage(min_w_nmos * (nsize * 2),
min_w_pmos * nsize * 2, 2,
nand)) * deviceType->Vdd;
}
// tristate buffer model consisting of not, nand, nor, and driver transistors
void Htree2::output_buffer(double s1, double s2, double l_eff) {
Wire w1(wt, l_eff);
double pton_size = deviceType->n_to_p_eff_curr_drv_ratio;
// input capacitance of repeater = input capacitance of nand + nor.
double size = s1 * (1 + pton_size) / (2 + pton_size + 1 + 2 * pton_size);
double s_eff = //stage eff of a repeater in a wire
(gate_C(s2 * (min_w_nmos + min_w_pmos), 0) + w1.wire_cap(l_eff * 1e-6,
true)) /
gate_C(s2 * (min_w_nmos + min_w_pmos), 0);
double tr_size = gate_C(s1 * (min_w_nmos + min_w_pmos), 0) * 1 / 2 /
(s_eff * gate_C(min_w_pmos, 0));
size = (size < 1) ? 1 : size;
double res_nor = 2 * tr_R_on(size * min_w_pmos, PCH, 1);
double res_ptrans = tr_R_on(tr_size * min_w_nmos, NCH, 1);
double cap_nand_out =
drain_C_(size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def) +
drain_C_(size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def) * 2 +
gate_C(tr_size * min_w_pmos, 0);
double cap_ptrans_out = 2 *
(drain_C_(tr_size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def) +
drain_C_(tr_size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)) +
gate_C(s1 * (min_w_nmos + min_w_pmos), 0);
double tc = res_nor * cap_nand_out + (res_nor + res_ptrans) * cap_ptrans_out;
delay += horowitz(w1.out_rise_time, tc,
deviceType->Vth / deviceType->Vdd, deviceType->Vth /
deviceType->Vdd, RISE);
//nand
power.readOp.dynamic += 0.5 *
(2 * drain_C_(size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def) +
drain_C_(size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def) +
gate_C(tr_size * (min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd;
power.searchOp.dynamic += 0.5 *
(2 * drain_C_(size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def) +
drain_C_(size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def) +
gate_C(tr_size * (min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd * init_wire_bw;
//not
power.readOp.dynamic += 0.5 *
(drain_C_(size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ drain_C_(size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)
+ gate_C(size * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd;
power.searchOp.dynamic += 0.5 *
(drain_C_(size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ drain_C_(size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)
+ gate_C(size * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd * init_wire_bw;
//nor
power.readOp.dynamic += 0.5 *
(drain_C_(size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ 2 * drain_C_(size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)
+ gate_C(tr_size * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd;
power.searchOp.dynamic += 0.5 *
(drain_C_(size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ 2 * drain_C_(size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)
+ gate_C(tr_size * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd * init_wire_bw;
//output transistor
power.readOp.dynamic += 0.5 *
((drain_C_(tr_size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ drain_C_(tr_size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)) * 2
+ gate_C(s1 * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd;
power.searchOp.dynamic += 0.5 *
((drain_C_(tr_size * min_w_pmos, PCH, 1, 1, g_tp.cell_h_def)
+ drain_C_(tr_size * min_w_nmos, NCH, 1, 1, g_tp.cell_h_def)) * 2
+ gate_C(s1 * (min_w_nmos + min_w_pmos), 0)) *
deviceType->Vdd * deviceType->Vdd * init_wire_bw;
if (uca_tree) {
power.readOp.leakage +=
cmos_Isub_leakage(min_w_nmos * tr_size * 2, min_w_pmos * tr_size *
2, 1, inv) *
deviceType->Vdd * wire_bw;/*inverter + output tr*/
power.readOp.leakage +=
cmos_Isub_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nand) * deviceType->Vdd * wire_bw;//nand
power.readOp.leakage +=
cmos_Isub_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nor) * deviceType->Vdd * wire_bw;//nor
power.readOp.gate_leakage +=
cmos_Ig_leakage(min_w_nmos * tr_size * 2, min_w_pmos * tr_size * 2,
1, inv) *
deviceType->Vdd * wire_bw;/*inverter + output tr*/
power.readOp.gate_leakage +=
cmos_Ig_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nand) * deviceType->Vdd * wire_bw;//nand
power.readOp.gate_leakage +=
cmos_Ig_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nor) * deviceType->Vdd * wire_bw;//nor
} else {
power.readOp.leakage +=
cmos_Isub_leakage(min_w_nmos * tr_size * 2, min_w_pmos * tr_size *
2, 1, inv) *
deviceType->Vdd * wire_bw;/*inverter + output tr*/
power.readOp.leakage +=
cmos_Isub_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nand) * deviceType->Vdd * wire_bw;//nand
power.readOp.leakage +=
cmos_Isub_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nor) * deviceType->Vdd * wire_bw;//nor
power.readOp.gate_leakage +=
cmos_Ig_leakage(min_w_nmos * tr_size * 2, min_w_pmos * tr_size * 2,
1, inv) *
deviceType->Vdd * wire_bw;/*inverter + output tr*/
power.readOp.gate_leakage +=
cmos_Ig_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nand) * deviceType->Vdd * wire_bw;//nand
power.readOp.gate_leakage +=
cmos_Ig_leakage(min_w_nmos * size * 3, min_w_pmos * size * 3, 2,
nor) * deviceType->Vdd * wire_bw;//nor
}
}
/* calculates the input h-tree delay/power
* A nand gate is used at each node to
* limit the signal
* The area of an unbalanced htree (rows != columns)
* depends on how data is traversed.
* In the following function, if ( no. of rows < no. of columns),
* then data first traverse in excess hor. links until vertical
* and horizontal nodes are same.
* If no. of rows is bigger, then data traverse in
* a hor. link followed by a ver. link in a repeated
* fashion (similar to a balanced tree) until there are no
* hor. links left. After this it goes through the remaining vertical
* links.
*/
void
Htree2::in_htree() {
//temp var
double s1 = 0, s2 = 0, s3 = 0;
double l_eff = 0;
Wire *wtemp1 = 0, *wtemp2 = 0, *wtemp3 = 0;
double len = 0, ht = 0;
int option = 0;
int h = (int) _log2(ndwl / 2); // horizontal nodes
int v = (int) _log2(ndbl / 2); // vertical nodes
double len_temp;
double ht_temp;
if (uca_tree) {
//Sheng: this computation do not consider the wires that route from
//edge to middle.
ht_temp = (mat_height * ndbl / 2 +
/* since uca_tree models interbank tree,
mat_height => bank height */
((add_bits + data_in_bits + data_out_bits +
(search_data_in_bits + search_data_out_bits)) *
g_tp.wire_outside_mat.pitch *
2 * (1 - pow(0.5, h)))) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits + data_in_bits + data_out_bits +
(search_data_in_bits + search_data_out_bits)) *
g_tp.wire_outside_mat.pitch *
2 * (1 - pow(0.5, v)))) / 2;
} else {
if (ndwl == ndbl) {
ht_temp = ((mat_height * ndbl / 2) +
((add_bits + (search_data_in_bits +
search_data_out_bits)) * (ndbl / 2 - 1) *
g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * h)
) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits + (search_data_in_bits +
search_data_out_bits)) * (ndwl / 2 - 1) *
g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * v)) / 2;
} else if (ndwl > ndbl) {
double excess_part = (_log2(ndwl / 2) - _log2(ndbl / 2));
ht_temp = ((mat_height * ndbl / 2) +
((add_bits + + (search_data_in_bits +
search_data_out_bits)) *
((ndbl / 2 - 1) + excess_part) *
g_tp.wire_outside_mat.pitch) +
(data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch *
(2 * (1 - pow(0.5, h - v)) + pow(0.5, v - h) * v)) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits +
(search_data_in_bits + search_data_out_bits)) *
(ndwl / 2 - 1) * g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * v)) / 2;
} else {
double excess_part = (_log2(ndbl / 2) - _log2(ndwl / 2));
ht_temp = ((mat_height * ndbl / 2) +
((add_bits +
(search_data_in_bits + search_data_out_bits)) *
((ndwl / 2 - 1) + excess_part) *
g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * h)
) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits +
(search_data_in_bits + search_data_out_bits)) *
((ndwl / 2 - 1) + excess_part) *
g_tp.wire_outside_mat.pitch) +
(data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch *
(h + 2 * (1 - pow(0.5, v - h)))) / 2;
}
}
area.h = ht_temp * 2;
area.w = len_temp * 2;
delay = 0;
power.readOp.dynamic = 0;
power.readOp.leakage = 0;
power.searchOp.dynamic = 0;
len = len_temp;
ht = ht_temp / 2;
while (v > 0 || h > 0) {
if (wtemp1) delete wtemp1;
if (wtemp2) delete wtemp2;
if (wtemp3) delete wtemp3;
if (h > v) {
//the iteration considers only one horizontal link
wtemp1 = new Wire(wt, len); // hor
wtemp2 = new Wire(wt, len / 2); // ver
len_temp = len;
len /= 2;
wtemp3 = 0;
h--;
option = 0;
} else if (v > 0 && h > 0) {
//considers one horizontal link and one vertical link
wtemp1 = new Wire(wt, len); // hor
wtemp2 = new Wire(wt, ht); // ver
wtemp3 = new Wire(wt, len / 2); // next hor
len_temp = len;
ht_temp = ht;
len /= 2;
ht /= 2;
v--;
h--;
option = 1;
} else {
// considers only one vertical link
assert(h == 0);
wtemp1 = new Wire(wt, ht); // ver
wtemp2 = new Wire(wt, ht / 2); // hor
ht_temp = ht;
ht /= 2;
wtemp3 = 0;
v--;
option = 2;
}
delay += wtemp1->delay;
power.readOp.dynamic += wtemp1->power.readOp.dynamic;
power.searchOp.dynamic += wtemp1->power.readOp.dynamic * wire_bw;
power.readOp.leakage += wtemp1->power.readOp.leakage * wire_bw;
power.readOp.gate_leakage += wtemp1->power.readOp.gate_leakage * wire_bw;
if ((uca_tree == false && option == 2) || search_tree == true) {
wire_bw *= 2; // wire bandwidth doubles only for vertical branches
}
if (uca_tree == false) {
if (len_temp > wtemp1->repeater_spacing) {
s1 = wtemp1->repeater_size;
l_eff = wtemp1->repeater_spacing;
} else {
s1 = (len_temp / wtemp1->repeater_spacing) *
wtemp1->repeater_size;
l_eff = len_temp;
}
if (ht_temp > wtemp2->repeater_spacing) {
s2 = wtemp2->repeater_size;
} else {
s2 = (len_temp / wtemp2->repeater_spacing) *
wtemp2->repeater_size;
}
// first level
input_nand(s1, s2, l_eff);
}
if (option != 1) {
continue;
}
// second level
delay += wtemp2->delay;
power.readOp.dynamic += wtemp2->power.readOp.dynamic;
power.searchOp.dynamic += wtemp2->power.readOp.dynamic * wire_bw;
power.readOp.leakage += wtemp2->power.readOp.leakage * wire_bw;
power.readOp.gate_leakage += wtemp2->power.readOp.gate_leakage * wire_bw;
if (uca_tree) {
power.readOp.leakage += (wtemp2->power.readOp.leakage * wire_bw);
power.readOp.gate_leakage +=
wtemp2->power.readOp.gate_leakage * wire_bw;
} else {
power.readOp.leakage += (wtemp2->power.readOp.leakage * wire_bw);
power.readOp.gate_leakage +=
wtemp2->power.readOp.gate_leakage * wire_bw;
wire_bw *= 2;
if (ht_temp > wtemp3->repeater_spacing) {
s3 = wtemp3->repeater_size;
l_eff = wtemp3->repeater_spacing;
} else {
s3 = (len_temp / wtemp3->repeater_spacing) *
wtemp3->repeater_size;
l_eff = ht_temp;
}
input_nand(s2, s3, l_eff);
}
}
if (wtemp1) delete wtemp1;
if (wtemp2) delete wtemp2;
if (wtemp3) delete wtemp3;
}
/* a tristate buffer is used to handle fan-ins
* The area of an unbalanced htree (rows != columns)
* depends on how data is traversed.
* In the following function, if ( no. of rows < no. of columns),
* then data first traverse in excess hor. links until vertical
* and horizontal nodes are same.
* If no. of rows is bigger, then data traverse in
* a hor. link followed by a ver. link in a repeated
* fashion (similar to a balanced tree) until there are no
* hor. links left. After this it goes through the remaining vertical
* links.
*/
void Htree2::out_htree() {
//temp var
double s1 = 0, s2 = 0, s3 = 0;
double l_eff = 0;
Wire *wtemp1 = 0, *wtemp2 = 0, *wtemp3 = 0;
double len = 0, ht = 0;
int option = 0;
int h = (int) _log2(ndwl / 2);
int v = (int) _log2(ndbl / 2);
double len_temp;
double ht_temp;
if (uca_tree) {
ht_temp = (mat_height * ndbl / 2 +
/* since uca_tree models interbank tree,
mat_height => bank height */
((add_bits + data_in_bits + data_out_bits +
(search_data_in_bits + search_data_out_bits)) *
g_tp.wire_outside_mat.pitch *
2 * (1 - pow(0.5, h)))) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits + data_in_bits + data_out_bits +
(search_data_in_bits + search_data_out_bits)) *
g_tp.wire_outside_mat.pitch *
2 * (1 - pow(0.5, v)))) / 2;
} else {
if (ndwl == ndbl) {
ht_temp = ((mat_height * ndbl / 2) +
((add_bits + (search_data_in_bits +
search_data_out_bits)) *
(ndbl / 2 - 1) * g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * h)
) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits + (search_data_in_bits +
search_data_out_bits)) * (ndwl / 2 - 1) *
g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * v)) / 2;
} else if (ndwl > ndbl) {
double excess_part = (_log2(ndwl / 2) - _log2(ndbl / 2));
ht_temp = ((mat_height * ndbl / 2) +
((add_bits +
(search_data_in_bits + search_data_out_bits)) *
((ndbl / 2 - 1) + excess_part) *
g_tp.wire_outside_mat.pitch) +
(data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch *
(2 * (1 - pow(0.5, h - v)) + pow(0.5, v - h) * v)) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits +
(search_data_in_bits + search_data_out_bits)) *
(ndwl / 2 - 1) * g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * v)) / 2;
} else {
double excess_part = (_log2(ndbl / 2) - _log2(ndwl / 2));
ht_temp = ((mat_height * ndbl / 2) +
((add_bits +
(search_data_in_bits + search_data_out_bits)) *
((ndwl / 2 - 1) + excess_part) *
g_tp.wire_outside_mat.pitch) +
((data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch * h)
) / 2;
len_temp = (mat_width * ndwl / 2 +
((add_bits + (search_data_in_bits +
search_data_out_bits)) *
((ndwl / 2 - 1) + excess_part) *
g_tp.wire_outside_mat.pitch) +
(data_in_bits + data_out_bits) *
g_tp.wire_outside_mat.pitch *
(h + 2 * (1 - pow(0.5, v - h)))) / 2;
}
}
area.h = ht_temp * 2;
area.w = len_temp * 2;
delay = 0;
power.readOp.dynamic = 0;
power.readOp.leakage = 0;
power.readOp.gate_leakage = 0;
//cout<<"power.readOp.gate_leakage"<<power.readOp.gate_leakage<<endl;
len = len_temp;
ht = ht_temp / 2;
while (v > 0 || h > 0) { //finds delay/power of each link in the tree
if (wtemp1) delete wtemp1;
if (wtemp2) delete wtemp2;
if (wtemp3) delete wtemp3;
if (h > v) {
//the iteration considers only one horizontal link
wtemp1 = new Wire(wt, len); // hor
wtemp2 = new Wire(wt, len / 2); // ver
len_temp = len;
len /= 2;
wtemp3 = 0;
h--;
option = 0;
} else if (v > 0 && h > 0) {
//considers one horizontal link and one vertical link
wtemp1 = new Wire(wt, len); // hor
wtemp2 = new Wire(wt, ht); // ver
wtemp3 = new Wire(wt, len / 2); // next hor
len_temp = len;
ht_temp = ht;
len /= 2;
ht /= 2;
v--;
h--;
option = 1;
} else {
// considers only one vertical link
assert(h == 0);
wtemp1 = new Wire(wt, ht); // hor
wtemp2 = new Wire(wt, ht / 2); // ver
ht_temp = ht;
ht /= 2;
wtemp3 = 0;
v--;
option = 2;
}
delay += wtemp1->delay;
power.readOp.dynamic += wtemp1->power.readOp.dynamic;
power.searchOp.dynamic += wtemp1->power.readOp.dynamic * init_wire_bw;
power.readOp.leakage += wtemp1->power.readOp.leakage * wire_bw;
power.readOp.gate_leakage += wtemp1->power.readOp.gate_leakage * wire_bw;
if ((uca_tree == false && option == 2) || search_tree == true) {
wire_bw *= 2;
}
if (uca_tree == false) {
if (len_temp > wtemp1->repeater_spacing) {
s1 = wtemp1->repeater_size;
l_eff = wtemp1->repeater_spacing;
} else {
s1 = (len_temp / wtemp1->repeater_spacing) *
wtemp1->repeater_size;
l_eff = len_temp;
}
if (ht_temp > wtemp2->repeater_spacing) {
s2 = wtemp2->repeater_size;
} else {
s2 = (len_temp / wtemp2->repeater_spacing) *
wtemp2->repeater_size;
}
// first level
output_buffer(s1, s2, l_eff);
}
if (option != 1) {
continue;
}
// second level
delay += wtemp2->delay;
power.readOp.dynamic += wtemp2->power.readOp.dynamic;
power.searchOp.dynamic += wtemp2->power.readOp.dynamic * init_wire_bw;
power.readOp.leakage += wtemp2->power.readOp.leakage * wire_bw;
power.readOp.gate_leakage += wtemp2->power.readOp.gate_leakage * wire_bw;
//cout<<"power.readOp.gate_leakage"<<power.readOp.gate_leakage<<endl;
if (uca_tree) {
power.readOp.leakage += (wtemp2->power.readOp.leakage * wire_bw);
power.readOp.gate_leakage +=
wtemp2->power.readOp.gate_leakage * wire_bw;
} else {
power.readOp.leakage += (wtemp2->power.readOp.leakage * wire_bw);
power.readOp.gate_leakage +=
wtemp2->power.readOp.gate_leakage * wire_bw;
wire_bw *= 2;
if (ht_temp > wtemp3->repeater_spacing) {
s3 = wtemp3->repeater_size;
l_eff = wtemp3->repeater_spacing;
} else {
s3 = (len_temp / wtemp3->repeater_spacing) *
wtemp3->repeater_size;
l_eff = ht_temp;
}
output_buffer(s2, s3, l_eff);
}
//cout<<"power.readOp.leakage"<<power.readOp.leakage<<endl;
//cout<<"power.readOp.gate_leakage"<<power.readOp.gate_leakage<<endl;
//cout<<"wtemp2->power.readOp.gate_leakage"<<wtemp2->power.readOp.gate_leakage<<endl;
}
if (wtemp1) delete wtemp1;
if (wtemp2) delete wtemp2;
if (wtemp3) delete wtemp3;
}