gem5/ext/mcpat/iocontrollers.cc
Yasuko Eckert 0deef376d9 ext: McPAT interface changes and fixes
This patch includes software engineering changes and some generic bug fixes
Joel Hestness and Yasuko Eckert made to McPAT 0.8. There are still known
issues/concernts we did not have a chance to address in this patch.

High-level changes in this patch include:
 1) Making XML parsing modular and hierarchical:
   - Shift parsing responsibility into the components
   - Read XML in a (mostly) context-free recursive manner so that McPAT input
     files can contain arbitrary component hierarchies
 2) Making power, energy, and area calculations a hierarchical and recursive
    process
   - Components track their subcomponents and recursively call compute
     functions in stages
   - Make C++ object hierarchy reflect inheritance of classes of components
     with similar structures
   - Simplify computeArea() and computeEnergy() functions to eliminate
     successive calls to calculate separate TDP vs. runtime energy
   - Remove Processor component (now unnecessary) and introduce a more abstract
     System component
 3) Standardizing McPAT output across all components
   - Use a single, common data structure for storing and printing McPAT output
   - Recursively call print functions through component hierarchy
 4) For caches, allow splitting data array and tag array reads and writes for
    better accuracy
 5) Improving the usability of CACTI by printing more helpful warning and error
    messages
 6) Minor: Impose more rigorous code style for clarity (more work still to be
    done)
Overall, these changes greatly reduce the amount of replicated code, and they
improve McPAT runtime and decrease memory footprint.
2014-06-03 13:32:59 -07:00

540 lines
22 KiB
C++

/*****************************************************************************
* McPAT
* SOFTWARE LICENSE AGREEMENT
* Copyright 2012 Hewlett-Packard Development Company, L.P.
* Copyright (c) 2010-2013 Advanced Micro Devices, Inc.
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* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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***************************************************************************/
#include <algorithm>
#include <cassert>
#include <cmath>
#include <iostream>
#include <string>
#include "basic_circuit.h"
#include "common.h"
#include "const.h"
#include "io.h"
#include "iocontrollers.h"
#include "logic.h"
/*
SUN Niagara 2 I/O power analysis:
total signal bits: 711
Total FBDIMM bits: (14+10)*2*8= 384
PCIe bits: (8 + 8)*2 = 32
10Gb NIC: (4*2+4*2)*2 = 32
Debug I/Os: 168
Other I/Os: 711- 32-32 - 384 - 168 = 95
According to "Implementation of an 8-Core, 64-Thread, Power-Efficient SPARC Server on a Chip"
90% of I/Os are SerDers (the calucaltion is 384+64/(711-168)=83% about the same as the 90% reported in the paper)
--> around 80Pins are common I/Os.
Common I/Os consumes 71mW/Gb/s according to Cadence ChipEstimate @65nm
Niagara 2 I/O clock is 1/4 of core clock. --> 87pin (<--((711-168)*17%)) * 71mW/Gb/s *0.25*1.4Ghz = 2.17W
Total dynamic power of FBDIMM, NIC, PCIe = 84*0.132 + 84*0.049*0.132 = 11.14 - 2.17 = 8.98
Further, if assuming I/O logic power is about 50% of I/Os then Total energy of FBDIMM, NIC, PCIe = 11.14 - 2.17*1.5 = 7.89
*/
/*
* A bug in Cadence ChipEstimator: After update the clock rate in the clock tab, a user
* need to re-select the IP clock (the same clk) and then click Estimate. if not reselect
* the new clock rate may not be propogate into the IPs.
*
*/
NIUController::NIUController(XMLNode* _xml_data,InputParameter* interface_ip_)
: McPATComponent(_xml_data, interface_ip_) {
name = "NIU";
set_niu_param();
}
void NIUController::computeArea() {
double mac_area;
double frontend_area;
double SerDer_area;
if (niup.type == 0) { //high performance NIU
//Area estimation based on average of die photo from Niagara 2 and
//Cadence ChipEstimate using 65nm.
mac_area = (1.53 + 0.3) / 2 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);
//Area estimation based on average of die photo from Niagara 2, ISSCC
//"An 800mW 10Gb Ethernet Transceiver in 0.13μm CMOS"
//and"A 1.2-V-Only 900-mW 10 Gb Ethernet Transceiver and XAUI Interface
//With Robust VCO Tuning Technique" Frontend is PCS
frontend_area = (9.8 + (6 + 18) * 65 / 130 * 65 / 130) / 3 *
(interface_ip.F_sz_um / 0.065) * (interface_ip.F_sz_um / 0.065);
//Area estimation based on average of die photo from Niagara 2 and
//Cadence ChipEstimate hard IP @65nm.
//SerDer is very hard to scale
SerDer_area = (1.39 + 0.36) * (interface_ip.F_sz_um /
0.065);//* (interface_ip.F_sz_um/0.065);
} else {
//Low power implementations are mostly from Cadence ChipEstimator;
//Ignore the multiple IP effect
// ---When there are multiple IP (same kind or not) selected, Cadence
//ChipEstimator results are not a simple summation of all IPs.
//Ignore this effect
mac_area = 0.24 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);
frontend_area = 0.1 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);//Frontend is the PCS layer
SerDer_area = 0.35 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um/0.065);
//Compare 130um implementation in "A 1.2-V-Only 900-mW 10 Gb Ethernet
//Transceiver and XAUI Interface With Robust VCO Tuning Technique"
//and the ChipEstimator XAUI PHY hard IP, confirm that even PHY can
//scale perfectly with the technology
}
//total area
output_data.area = (mac_area + frontend_area + SerDer_area) * 1e6;
}
void NIUController::computeEnergy() {
double mac_dyn;
double frontend_dyn;
double SerDer_dyn;
double frontend_gates;
double mac_gates;
double SerDer_gates;
double NMOS_sizing;
double PMOS_sizing;
double pmos_to_nmos_sizing_r = pmos_to_nmos_sz_ratio();
if (niup.type == 0) { //high performance NIU
//Power
//Cadence ChipEstimate using 65nm (mac, front_end are all energy.
//E=P*T = P/F = 1.37/1Ghz = 1.37e-9);
//2.19W@1GHz fully active according to Cadence ChipEstimate @65nm
mac_dyn = 2.19e-9 * g_tp.peri_global.Vdd / 1.1 * g_tp.peri_global.Vdd /
1.1 * (interface_ip.F_sz_nm / 65.0);//niup.clockRate;
//Cadence ChipEstimate using 65nm soft IP;
frontend_dyn = 0.27e-9 * g_tp.peri_global.Vdd / 1.1 *
g_tp.peri_global.Vdd / 1.1 * (interface_ip.F_sz_nm / 65.0);
//according to "A 100mW 9.6Gb/s Transceiver in 90nm CMOS..." ISSCC 2006
//SerDer_dyn is power not energy, scaling from 10mw/Gb/s @90nm
SerDer_dyn = 0.01 * 10 * sqrt(interface_ip.F_sz_um / 0.09) *
g_tp.peri_global.Vdd / 1.2 * g_tp.peri_global.Vdd / 1.2;
//Cadence ChipEstimate using 65nm
mac_gates = 111700;
frontend_gates = 320000;
SerDer_gates = 200000;
NMOS_sizing = 5 * g_tp.min_w_nmos_;
PMOS_sizing = 5 * g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r;
} else {
//Power
//Cadence ChipEstimate using 65nm (mac, front_end are all energy.
///E=P*T = P/F = 1.37/1Ghz = 1.37e-9);
//2.19W@1GHz fully active according to Cadence ChipEstimate @65nm
mac_dyn = 1.257e-9 * g_tp.peri_global.Vdd / 1.1 * g_tp.peri_global.Vdd
/ 1.1 * (interface_ip.F_sz_nm / 65.0);//niup.clockRate;
//Cadence ChipEstimate using 65nm soft IP;
frontend_dyn = 0.6e-9 * g_tp.peri_global.Vdd / 1.1 *
g_tp.peri_global.Vdd / 1.1 * (interface_ip.F_sz_nm / 65.0);
//SerDer_dyn is power not energy, scaling from 216mw/10Gb/s @130nm
SerDer_dyn = 0.0216 * 10 * (interface_ip.F_sz_um / 0.13) *
g_tp.peri_global.Vdd / 1.2 * g_tp.peri_global.Vdd / 1.2;
mac_gates = 111700;
frontend_gates = 52000;
SerDer_gates = 199260;
NMOS_sizing = g_tp.min_w_nmos_;
PMOS_sizing = g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r;
}
//covert to energy per clock cycle of whole NIU
SerDer_dyn /= niup.clockRate;
power.readOp.dynamic = mac_dyn + frontend_dyn + SerDer_dyn;
power.readOp.leakage = (mac_gates + frontend_gates + frontend_gates) *
cmos_Isub_leakage(NMOS_sizing, PMOS_sizing, 2, nand) *
g_tp.peri_global.Vdd;//unit W
double long_channel_device_reduction =
longer_channel_device_reduction(Uncore_device);
power.readOp.longer_channel_leakage =
power.readOp.leakage * long_channel_device_reduction;
power.readOp.gate_leakage = (mac_gates + frontend_gates + frontend_gates) *
cmos_Ig_leakage(NMOS_sizing, PMOS_sizing, 2, nand) *
g_tp.peri_global.Vdd;//unit W
// Output power
output_data.subthreshold_leakage_power =
longer_channel_device ? power.readOp.longer_channel_leakage :
power.readOp.leakage;
output_data.gate_leakage_power = power.readOp.gate_leakage;
output_data.peak_dynamic_power = power.readOp.dynamic * nius.duty_cycle;
output_data.runtime_dynamic_energy = power.readOp.dynamic * nius.perc_load;
}
void NIUController::set_niu_param() {
int num_children = xml_data->nChildNode("param");
int i;
for (i = 0; i < num_children; i++) {
XMLNode* paramNode = xml_data->getChildNodePtr("param", &i);
XMLCSTR node_name = paramNode->getAttribute("name");
XMLCSTR value = paramNode->getAttribute("value");
if (!node_name)
warnMissingParamName(paramNode->getAttribute("id"));
ASSIGN_FP_IF("niu_clockRate", niup.clockRate);
ASSIGN_INT_IF("num_units", niup.num_units);
ASSIGN_INT_IF("type", niup.type);
else {
warnUnrecognizedParam(node_name);
}
}
// Change from MHz to Hz
niup.clockRate *= 1e6;
num_children = xml_data->nChildNode("stat");
for (i = 0; i < num_children; i++) {
XMLNode* statNode = xml_data->getChildNodePtr("stat", &i);
XMLCSTR node_name = statNode->getAttribute("name");
XMLCSTR value = statNode->getAttribute("value");
if (!node_name)
warnMissingStatName(statNode->getAttribute("id"));
ASSIGN_FP_IF("duty_cycle", nius.duty_cycle);
ASSIGN_FP_IF("perc_load", nius.perc_load);
else {
warnUnrecognizedStat(node_name);
}
}
}
PCIeController::PCIeController(XMLNode* _xml_data,
InputParameter* interface_ip_)
: McPATComponent(_xml_data, interface_ip_) {
name = "PCIe";
set_pcie_param();
}
void PCIeController::computeArea() {
double ctrl_area;
double SerDer_area;
/* Assuming PCIe is bit-slice based architecture
* This is the reason for /8 in both area and power calculation
* to get per lane numbers
*/
if (pciep.type == 0) { //high performance PCIe
//Area estimation based on average of die photo from Niagara 2 and
//Cadence ChipEstimate @ 65nm.
ctrl_area = (5.2 + 0.5) / 2 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);
//Area estimation based on average of die photo from Niagara 2 and
//Cadence ChipEstimate hard IP @65nm.
//SerDer is very hard to scale
SerDer_area = (3.03 + 0.36) * (interface_ip.F_sz_um /
0.065);//* (interface_ip.F_sz_um/0.065);
} else {
ctrl_area = 0.412 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);
//Area estimation based on average of die photo from Niagara 2, and
//Cadence ChipEstimate @ 65nm.
SerDer_area = 0.36 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);
}
// Total area
output_data.area = ((ctrl_area + (pciep.withPHY ? SerDer_area : 0)) / 8 *
pciep.num_channels) * 1e6;
}
void PCIeController::computeEnergy() {
double ctrl_dyn;
double SerDer_dyn;
double ctrl_gates;
double SerDer_gates = 0;
double pmos_to_nmos_sizing_r = pmos_to_nmos_sz_ratio();
double NMOS_sizing;
double PMOS_sizing;
/* Assuming PCIe is bit-slice based architecture
* This is the reason for /8 in both area and power calculation
* to get per lane numbers
*/
if (pciep.type == 0) { //high performance PCIe
//Power
//Cadence ChipEstimate using 65nm the controller includes everything: the PHY, the data link and transaction layer
ctrl_dyn = 3.75e-9 / 8 * g_tp.peri_global.Vdd / 1.1 *
g_tp.peri_global.Vdd / 1.1 * (interface_ip.F_sz_nm / 65.0);
// //Cadence ChipEstimate using 65nm soft IP;
// frontend_dyn = 0.27e-9/8*g_tp.peri_global.Vdd/1.1*g_tp.peri_global.Vdd/1.1*(interface_ip.F_sz_nm/65.0);
//SerDer_dyn is power not energy, scaling from 10mw/Gb/s @90nm
//PCIe 2.0 max per lane speed is 4Gb/s
SerDer_dyn = 0.01 * 4 * (interface_ip.F_sz_um /0.09) *
g_tp.peri_global.Vdd / 1.2 * g_tp.peri_global.Vdd /1.2;
//Cadence ChipEstimate using 65nm
ctrl_gates = 900000 / 8 * pciep.num_channels;
// frontend_gates = 120000/8;
// SerDer_gates = 200000/8;
NMOS_sizing = 5 * g_tp.min_w_nmos_;
PMOS_sizing = 5 * g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r;
} else {
//Power
//Cadence ChipEstimate using 65nm the controller includes everything: the PHY, the data link and transaction layer
ctrl_dyn = 2.21e-9 / 8 * g_tp.peri_global.Vdd / 1.1 *
g_tp.peri_global.Vdd / 1.1 * (interface_ip.F_sz_nm / 65.0);
// //Cadence ChipEstimate using 65nm soft IP;
// frontend_dyn = 0.27e-9/8*g_tp.peri_global.Vdd/1.1*g_tp.peri_global.Vdd/1.1*(interface_ip.F_sz_nm/65.0);
//SerDer_dyn is power not energy, scaling from 10mw/Gb/s @90nm
//PCIe 2.0 max per lane speed is 4Gb/s
SerDer_dyn = 0.01 * 4 * (interface_ip.F_sz_um / 0.09) *
g_tp.peri_global.Vdd / 1.2 * g_tp.peri_global.Vdd /1.2;
//Cadence ChipEstimate using 65nm
ctrl_gates = 200000 / 8 * pciep.num_channels;
// frontend_gates = 120000/8;
SerDer_gates = 200000 / 8 * pciep.num_channels;
NMOS_sizing = g_tp.min_w_nmos_;
PMOS_sizing = g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r;
}
//covert to energy per clock cycle
SerDer_dyn /= pciep.clockRate;
power.readOp.dynamic = (ctrl_dyn + (pciep.withPHY ? SerDer_dyn : 0)) *
pciep.num_channels;
power.readOp.leakage = (ctrl_gates + (pciep.withPHY ? SerDer_gates : 0)) *
cmos_Isub_leakage(NMOS_sizing, PMOS_sizing, 2, nand) *
g_tp.peri_global.Vdd;//unit W
double long_channel_device_reduction =
longer_channel_device_reduction(Uncore_device);
power.readOp.longer_channel_leakage =
power.readOp.leakage * long_channel_device_reduction;
power.readOp.gate_leakage = (ctrl_gates +
(pciep.withPHY ? SerDer_gates : 0)) *
cmos_Ig_leakage(NMOS_sizing, PMOS_sizing, 2, nand) *
g_tp.peri_global.Vdd;//unit W
// Output power
output_data.subthreshold_leakage_power =
longer_channel_device ? power.readOp.longer_channel_leakage :
power.readOp.leakage;
output_data.gate_leakage_power = power.readOp.gate_leakage;
output_data.peak_dynamic_power = power.readOp.dynamic * pcies.duty_cycle;
output_data.runtime_dynamic_energy =
power.readOp.dynamic * pcies.perc_load;
}
void PCIeController::set_pcie_param() {
int num_children = xml_data->nChildNode("param");
int i;
for (i = 0; i < num_children; i++) {
XMLNode* paramNode = xml_data->getChildNodePtr("param", &i);
XMLCSTR node_name = paramNode->getAttribute("name");
XMLCSTR value = paramNode->getAttribute("value");
if (!node_name)
warnMissingParamName(paramNode->getAttribute("id"));
ASSIGN_FP_IF("pcie_clockRate", pciep.clockRate);
ASSIGN_INT_IF("num_units", pciep.num_units);
ASSIGN_INT_IF("num_channels", pciep.num_channels);
ASSIGN_INT_IF("type", pciep.type);
ASSIGN_ENUM_IF("withPHY", pciep.withPHY, bool);
else {
warnUnrecognizedParam(node_name);
}
}
// Change from MHz to Hz
pciep.clockRate *= 1e6;
num_children = xml_data->nChildNode("stat");
for (i = 0; i < num_children; i++) {
XMLNode* statNode = xml_data->getChildNodePtr("stat", &i);
XMLCSTR node_name = statNode->getAttribute("name");
XMLCSTR value = statNode->getAttribute("value");
if (!node_name)
warnMissingStatName(statNode->getAttribute("id"));
ASSIGN_FP_IF("duty_cycle", pcies.duty_cycle);
ASSIGN_FP_IF("perc_load", pcies.perc_load);
else {
warnUnrecognizedStat(node_name);
}
}
}
FlashController::FlashController(XMLNode* _xml_data,
InputParameter* interface_ip_)
: McPATComponent(_xml_data, interface_ip_) {
name = "Flash Controller";
set_fc_param();
}
void FlashController::computeArea() {
double ctrl_area;
double SerDer_area;
/* Assuming Flash is bit-slice based architecture
* This is the reason for /8 in both area and power calculation
* to get per lane numbers
*/
if (fcp.type == 0) { //high performance flash controller
cout << "Current McPAT does not support high performance flash "
<< "controller since even low power designs are enough for "
<< "maintain throughput" <<endl;
exit(0);
} else {
ctrl_area = 0.243 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);
//Area estimation based on Cadence ChipEstimate @ 65nm: NANDFLASH-CTRL
//from CAST
SerDer_area = 0.36 / 8 * (interface_ip.F_sz_um / 0.065) *
(interface_ip.F_sz_um / 0.065);
}
double number_channel = 1 + (fcp.num_channels - 1) * 0.2;
output_data.area = (ctrl_area + (fcp.withPHY ? SerDer_area : 0)) *
1e6 * number_channel;
}
void FlashController::computeEnergy() {
double ctrl_dyn;
double SerDer_dyn;
double ctrl_gates;
double SerDer_gates;
double pmos_to_nmos_sizing_r = pmos_to_nmos_sz_ratio();
double NMOS_sizing;
double PMOS_sizing;
/* Assuming Flash is bit-slice based architecture
* This is the reason for /8 in both area and power calculation
* to get per lane numbers
*/
if (fcp.type == 0) { //high performance flash controller
cout << "Current McPAT does not support high performance flash "
<< "controller since even low power designs are enough for "
<< "maintain throughput" <<endl;
exit(0);
NMOS_sizing = 5 * g_tp.min_w_nmos_;
PMOS_sizing = 5 * g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r;
} else {
//based On PCIe PHY TSMC65GP from Cadence ChipEstimate @ 65nm, it
//support 8x lanes with each lane speed up to 250MB/s (PCIe1.1x).
//This is already saturate the 200MB/s of the flash controller core
//above.
ctrl_gates = 129267;
SerDer_gates = 200000 / 8;
NMOS_sizing = g_tp.min_w_nmos_;
PMOS_sizing = g_tp.min_w_nmos_ * pmos_to_nmos_sizing_r;
//Power
//Cadence ChipEstimate using 65nm the controller 125mW for every
//200MB/s This is power not energy!
ctrl_dyn = 0.125 * g_tp.peri_global.Vdd / 1.1 * g_tp.peri_global.Vdd /
1.1 * (interface_ip.F_sz_nm / 65.0);
//SerDer_dyn is power not energy, scaling from 10mw/Gb/s @90nm
SerDer_dyn = 0.01 * 1.6 * (interface_ip.F_sz_um / 0.09) *
g_tp.peri_global.Vdd / 1.2 * g_tp.peri_global.Vdd / 1.2;
//max Per controller speed is 1.6Gb/s (200MB/s)
}
double number_channel = 1 + (fcp.num_channels - 1) * 0.2;
power.readOp.dynamic = (ctrl_dyn + (fcp.withPHY ? SerDer_dyn : 0)) *
number_channel;
power.readOp.leakage = ((ctrl_gates + (fcp.withPHY ? SerDer_gates : 0)) *
number_channel) *
cmos_Isub_leakage(NMOS_sizing, PMOS_sizing, 2, nand) *
g_tp.peri_global.Vdd;//unit W
double long_channel_device_reduction =
longer_channel_device_reduction(Uncore_device);
power.readOp.longer_channel_leakage =
power.readOp.leakage * long_channel_device_reduction;
power.readOp.gate_leakage =
((ctrl_gates + (fcp.withPHY ? SerDer_gates : 0)) * number_channel) *
cmos_Ig_leakage(NMOS_sizing, PMOS_sizing, 2, nand) *
g_tp.peri_global.Vdd;//unit W
// Output power
output_data.subthreshold_leakage_power =
longer_channel_device ? power.readOp.longer_channel_leakage :
power.readOp.leakage;
output_data.gate_leakage_power = power.readOp.gate_leakage;
output_data.peak_dynamic_power = power.readOp.dynamic * fcs.duty_cycle;
output_data.runtime_dynamic_energy = power.readOp.dynamic * fcs.perc_load;
}
void FlashController::set_fc_param()
{
int num_children = xml_data->nChildNode("param");
int i;
for (i = 0; i < num_children; i++) {
XMLNode* paramNode = xml_data->getChildNodePtr("param", &i);
XMLCSTR node_name = paramNode->getAttribute("name");
XMLCSTR value = paramNode->getAttribute("value");
if (!node_name)
warnMissingParamName(paramNode->getAttribute("id"));
ASSIGN_INT_IF("num_channels", fcp.num_channels);
ASSIGN_INT_IF("type", fcp.type);
ASSIGN_ENUM_IF("withPHY", fcp.withPHY, bool);
else {
warnUnrecognizedParam(node_name);
}
}
num_children = xml_data->nChildNode("stat");
for (i = 0; i < num_children; i++) {
XMLNode* statNode = xml_data->getChildNodePtr("stat", &i);
XMLCSTR node_name = statNode->getAttribute("name");
XMLCSTR value = statNode->getAttribute("value");
if (!node_name)
warnMissingStatName(statNode->getAttribute("id"));
ASSIGN_FP_IF("duty_cycle", fcs.duty_cycle);
ASSIGN_FP_IF("perc_load", fcs.perc_load);
else {
warnUnrecognizedStat(node_name);
}
}
}