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# Copyright (c) 2012-2013 ARM Limited
# All rights reserved.
#
# The license below extends only to copyright in the software and shall
# not be construed as granting a license to any other intellectual
# property including but not limited to intellectual property relating
# to a hardware implementation of the functionality of the software
# licensed hereunder. You may use the software subject to the license
# terms below provided that you ensure that this notice is replicated
# unmodified and in its entirety in all distributions of the software,
# modified or unmodified, in source code or in binary form.
#
# Copyright (c) 2015 The University of Bologna
# 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: Erfan Azarkhish
# Abdul Mutaal Ahmad
# A Simplified model of a complete HMC device. Based on:
# [1] http://www.hybridmemorycube.org/specification-download/
# [2] High performance AXI-4.0 based interconnect for extensible smart memory
# cubes(E. Azarkhish et. al)
# [3] Low-Power Hybrid Memory Cubes With Link Power Management and Two-Level
# Prefetching (J. Ahn et. al)
# [4] Memory-centric system interconnect design with Hybrid Memory Cubes
# (G. Kim et. al)
# [5] Near Data Processing, Are we there yet? (M. Gokhale)
# http://www.cs.utah.edu/wondp/gokhale.pdf
# [6] openHMC - A Configurable Open-Source Hybrid Memory Cube Controller
# (J. Schmidt)
# [7] Hybrid Memory Cube performance characterization on data-centric
# workloads (M. Gokhale)
#
# This script builds a complete HMC device composed of vault controllers,
# serial links, the main internal crossbar, and an external hmc controller.
#
# - VAULT CONTROLLERS:
# Instances of the HMC_2500_1x32 class with their functionality specified in
# dram_ctrl.cc
#
# - THE MAIN XBAR:
# This component is simply an instance of the NoncoherentXBar class, and its
# parameters are tuned to [2].
#
# - SERIAL LINKS CONTROLLER:
# SerialLink is a simple variation of the Bridge class, with the ability to
# account for the latency of packet serialization and controller latency. We
# assume that the serializer component at the transmitter side does not need
# to receive the whole packet to start the serialization. But the
# deserializer waits for the complete packet to check its integrity first.
#
# * Bandwidth of the serial links is not modeled in the SerialLink component
# itself.
#
# * Latency of serial link controller is composed of SerDes latency + link
# controller
#
# * It is inferred from the standard [1] and the literature [3] that serial
# links share the same address range and packets can travel over any of
# them so a load distribution mechanism is required among them.
#
# -----------------------------------------
# | Host/HMC Controller |
# | ---------------------- |
# | | Link Aggregator | opt |
# | ---------------------- |
# | ---------------------- |
# | | Serial Link + Ser | * 4 |
# | ---------------------- |
# |---------------------------------------
# -----------------------------------------
# | Device
# | ---------------------- |
# | | Xbar | * 4 |
# | ---------------------- |
# | ---------------------- |
# | | Vault Controller | * 16 |
# | ---------------------- |
# | ---------------------- |
# | | Memory | |
# | ---------------------- |
# |---------------------------------------|
#
# In this version we have present 3 different HMC archiecture along with
# alongwith their corresponding test script.
#
# same: It has 4 crossbars in HMC memory. All the crossbars are connected
# to each other, providing complete memory range. This archicture also covers
# the added latency for sending a request to non-local vault(bridge in b/t
# crossbars). All the 4 serial links can access complete memory. So each
# link can be connected to separate processor.
#
# distributed: It has 4 crossbars inside the HMC. Crossbars are not
# connected.Through each crossbar only local vaults can be accessed. But to
# support this architecture we need a crossbar between serial links and
# processor.
#
# mixed: This is a hybrid architecture. It has 4 crossbars inside the HMC.
# 2 Crossbars are connected to only local vaults. From other 2 crossbar, a
# request can be forwarded to any other vault.
import optparse
import m5
from m5.objects import *
# A single Hybrid Memory Cube (HMC)
class HMCSystem(SubSystem):
#*****************************CROSSBAR PARAMETERS*************************
# Flit size of the main interconnect [1]
xbar_width = Param.Unsigned(32, "Data width of the main XBar (Bytes)")
# Clock frequency of the main interconnect [1]
# This crossbar, is placed on the logic-based of the HMC and it has its
# own voltage and clock domains, different from the DRAM dies or from the
# host.
xbar_frequency = Param.Frequency('1GHz', "Clock Frequency of the main "
"XBar")
# Arbitration latency of the HMC XBar [1]
xbar_frontend_latency = Param.Cycles(1, "Arbitration latency of the XBar")
# Latency to forward a packet via the interconnect [1](two levels of FIFOs
# at the input and output of the inteconnect)
xbar_forward_latency = Param.Cycles(2, "Forward latency of the XBar")
# Latency to forward a response via the interconnect [1](two levels of
# FIFOs at the input and output of the inteconnect)
xbar_response_latency = Param.Cycles(2, "Response latency of the XBar")
# number of cross which connects 16 Vaults to serial link[7]
number_mem_crossbar = Param.Unsigned(4, "Number of crossbar in HMC"
)
#*****************************SERIAL LINK PARAMETERS***********************
# Number of serial links controllers [1]
num_links_controllers = Param.Unsigned(4, "Number of serial links")
# Number of packets (not flits) to store at the request side of the serial
# link. This number should be adjusted to achive required bandwidth
link_buffer_size_req = Param.Unsigned(10, "Number of packets to buffer "
"at the request side of the serial link")
# Number of packets (not flits) to store at the response side of the serial
# link. This number should be adjusted to achive required bandwidth
link_buffer_size_rsp = Param.Unsigned(10, "Number of packets to buffer "
"at the response side of the serial link")
# Latency of the serial link composed by SER/DES latency (1.6ns [4]) plus
# the PCB trace latency (3ns Estimated based on [5])
link_latency = Param.Latency('4.6ns', "Latency of the serial links")
# Clock frequency of the each serial link(SerDes) [1]
link_frequency = Param.Frequency('10GHz', "Clock Frequency of the serial"
"links")
# Clock frequency of serial link Controller[6]
# clk_hmc[Mhz]= num_lanes_per_link * lane_speed [Gbits/s] /
# data_path_width * 10^6
# clk_hmc[Mhz]= 16 * 10 Gbps / 256 * 10^6 = 625 Mhz
link_controller_frequency = Param.Frequency('625MHz',
"Clock Frequency of the link controller")
# Latency of the serial link controller to process the packets[1][6]
# (ClockDomain = 625 Mhz )
# used here for calculations only
link_ctrl_latency = Param.Cycles(4, "The number of cycles required for the"
"controller to process the packet")
# total_ctrl_latency = link_ctrl_latency + link_latency
# total_ctrl_latency = 4(Cycles) * 1.6 ns + 4.6 ns
total_ctrl_latency = Param.Latency('11ns', "The latency experienced by"
"every packet regardless of size of packet")
# Number of parallel lanes in each serial link [1]
num_lanes_per_link = Param.Unsigned( 16, "Number of lanes per each link")
# Number of serial links [1]
num_serial_links = Param.Unsigned(4, "Number of serial links")
# speed of each lane of serial link - SerDes serial interface 10 Gb/s
serial_link_speed = Param.UInt64(10, "Gbs/s speed of each lane of"
"serial link")
#*****************************PERFORMANCE MONITORING************************
# The main monitor behind the HMC Controller
enable_global_monitor = Param.Bool(False, "The main monitor behind the "
"HMC Controller")
# The link performance monitors
enable_link_monitor = Param.Bool(False, "The link monitors" )
# link aggregator enable - put a cross between buffers & links
enable_link_aggr = Param.Bool(False, "The crossbar between port and "
"Link Controller")
enable_buff_div = Param.Bool(True, "Memory Range of Buffer is"
"divided between total range")
#*****************************HMC ARCHITECTURE ************************
# Memory chunk for 16 vault - numbers of vault / number of crossbars
mem_chunk = Param.Unsigned(4, "Chunk of memory range for each cross bar "
"in arch 0")
# size of req buffer within crossbar, used for modelling extra latency
# when the reuqest go to non-local vault
xbar_buffer_size_req = Param.Unsigned(10, "Number of packets to buffer "
"at the request side of the crossbar")
# size of response buffer within crossbar, used for modelling extra latency
# when the response received from non-local vault
xbar_buffer_size_resp = Param.Unsigned(10, "Number of packets to buffer "
"at the response side of the crossbar")
# configure host system with Serial Links
def config_host_hmc(options, system):
system.hmc_host=HMCSystem()
try:
system.hmc_host.enable_global_monitor = options.enable_global_monitor
except:
pass;
try:
system.hmc_host.enable_link_monitor = options.enable_link_monitor
except:
pass;
# Serial link Controller with 16 SerDes links at 10 Gbps
# with serial link ranges w.r.t to architecture
system.hmc_host.seriallink = [SerialLink(ranges = options.ser_ranges[i],
req_size=system.hmc_host.link_buffer_size_req,
resp_size=system.hmc_host.link_buffer_size_rsp,
num_lanes=system.hmc_host.num_lanes_per_link,
link_speed=system.hmc_host.serial_link_speed,
delay=system.hmc_host.total_ctrl_latency)
for i in xrange(system.hmc_host.num_serial_links)]
# enable global monitor
if system.hmc_host.enable_global_monitor:
system.hmc_host.lmonitor = [ CommMonitor()
for i in xrange(system.hmc_host.num_serial_links)]
# set the clock frequency for serial link
for i in xrange(system.hmc_host.num_serial_links):
system.hmc_host.seriallink[i].clk_domain = SrcClockDomain(clock=system.
hmc_host.link_controller_frequency, voltage_domain=
VoltageDomain(voltage = '1V'))
# Connect membus/traffic gen to Serial Link Controller for differrent HMC
# architectures
if options.arch == "distributed":
for i in xrange(system.hmc_host.num_links_controllers):
if system.hmc_host.enable_global_monitor:
system.membus.master = system.hmc_host.lmonitor[i].slave
system.hmc_host.lmonitor[i].master = \
system.hmc_host.seriallink[i].slave
else:
system.membus.master = system.hmc_host.seriallink[i].slave
if options.arch == "mixed":
if system.hmc_host.enable_global_monitor:
system.membus.master = system.hmc_host.lmonitor[0].slave
system.hmc_host.lmonitor[0].master = \
system.hmc_host.seriallink[0].slave
system.membus.master = system.hmc_host.lmonitor[1].slave
system.hmc_host.lmonitor[1].master = \
system.hmc_host.seriallink[1].slave
system.tgen[2].port = system.hmc_host.lmonitor[2].slave
system.hmc_host.lmonitor[2].master = \
system.hmc_host.seriallink[2].slave
system.tgen[3].port = system.hmc_host.lmonitor[3].slave
system.hmc_host.lmonitor[3].master = \
system.hmc_host.seriallink[3].slave
else:
system.membus.master = system.hmc_host.seriallink[0].slave
system.membus.master = system.hmc_host.seriallink[1].slave
system.tgen[2].port = system.hmc_host.seriallink[2].slave
system.tgen[3].port = system.hmc_host.seriallink[3].slave
if options.arch == "same" :
for i in xrange(system.hmc_host.num_links_controllers):
if system.hmc_host.enable_global_monitor:
system.tgen[i].port = system.hmc_host.lmonitor[i].slave
system.hmc_host.lmonitor[i].master = \
system.hmc_host.seriallink[i].slave
else:
system.tgen[i].port = system.hmc_host.seriallink[i].slave
return system
# Create an HMC device and attach it to the current system
def config_hmc(options, system, hmc_host):
# Create HMC device
system.hmc_dev = HMCSystem()
# Global monitor
try:
system.hmc_dev.enable_global_monitor = options.enable_global_monitor
except:
pass;
try:
system.hmc_dev.enable_link_monitor = options.enable_link_monitor
except:
pass;
if system.hmc_dev.enable_link_monitor:
system.hmc_dev.lmonitor = [ CommMonitor()
for i in xrange(system.hmc_dev.num_links_controllers)]
# 4 HMC Crossbars located in its logic-base (LoB)
system.hmc_dev.xbar = [ NoncoherentXBar(width=system.hmc_dev.xbar_width,
frontend_latency=system.hmc_dev.xbar_frontend_latency,
forward_latency=system.hmc_dev.xbar_forward_latency,
response_latency=system.hmc_dev.xbar_response_latency )
for i in xrange(system.hmc_host.number_mem_crossbar)]
for i in xrange(system.hmc_dev.number_mem_crossbar):
system.hmc_dev.xbar[i].clk_domain = SrcClockDomain(
clock=system.hmc_dev.xbar_frequency,voltage_domain=
VoltageDomain(voltage='1V'))
# Attach 4 serial link to 4 crossbar/s
for i in xrange(system.hmc_dev.num_serial_links):
if system.hmc_dev.enable_link_monitor:
system.hmc_host.seriallink[i].master = \
system.hmc_dev.lmonitor[i].slave
system.hmc_dev.lmonitor[i].master = system.hmc_dev.xbar[i].slave
else:
system.hmc_host.seriallink[i].master = system.hmc_dev.xbar[i].slave
# Connecting xbar with each other for request arriving at the wrong xbar,
# then it will be forward to correct xbar. Bridge is used to connect xbars
if options.arch == "same":
numx = len(system.hmc_dev.xbar)
# create a list of buffers
system.hmc_dev.buffers = [ Bridge(
req_size=system.hmc_dev.xbar_buffer_size_req,
resp_size=system.hmc_dev.xbar_buffer_size_resp)
for i in xrange(numx * (system.hmc_dev.mem_chunk - 1))]
# Buffer iterator
it = iter(range(len(system.hmc_dev.buffers)))
# necesarry to add system_port to one of the xbar
system.system_port = system.hmc_dev.xbar[3].slave
# iterate over all the crossbars and connect them as required
for i in range(numx):
for j in range(numx):
# connect xbar to all other xbars except itself
if i != j:
# get the next index of buffer
index = it.next()
# Change the default values for ranges of bridge
system.hmc_dev.buffers[index].ranges = system.mem_ranges[
j * int(system.hmc_dev.mem_chunk):
(j + 1) * int(system.hmc_dev.mem_chunk)]
# Connect the bridge between corssbars
system.hmc_dev.xbar[i].master = system.hmc_dev.buffers[
index].slave
system.hmc_dev.buffers[
index].master = system.hmc_dev.xbar[j].slave
else:
# Don't connect the xbar to itself
pass
# Two crossbars are connected to all other crossbars-Other 2 vault
# can only direct traffic to it local vaults
if options.arch == "mixed":
system.hmc_dev.buffer30 = Bridge(ranges=system.mem_ranges[0:4])
system.hmc_dev.xbar[3].master = system.hmc_dev.buffer30.slave
system.hmc_dev.buffer30.master = system.hmc_dev.xbar[0].slave
system.hmc_dev.buffer31 = Bridge(ranges=system.mem_ranges[4:8])
system.hmc_dev.xbar[3].master = system.hmc_dev.buffer31.slave
system.hmc_dev.buffer31.master = system.hmc_dev.xbar[1].slave
system.hmc_dev.buffer32 = Bridge(ranges=system.mem_ranges[8:12])
system.hmc_dev.xbar[3].master = system.hmc_dev.buffer32.slave
system.hmc_dev.buffer32.master = system.hmc_dev.xbar[2].slave
system.hmc_dev.buffer20 = Bridge(ranges=system.mem_ranges[0:4])
system.hmc_dev.xbar[2].master = system.hmc_dev.buffer20.slave
system.hmc_dev.buffer20.master = system.hmc_dev.xbar[0].slave
system.hmc_dev.buffer21 = Bridge(ranges=system.mem_ranges[4:8])
system.hmc_dev.xbar[2].master = system.hmc_dev.buffer21.slave
system.hmc_dev.buffer21.master = system.hmc_dev.xbar[1].slave
system.hmc_dev.buffer23 = Bridge(ranges=system.mem_ranges[12:16])
system.hmc_dev.xbar[2].master = system.hmc_dev.buffer23.slave
system.hmc_dev.buffer23.master = system.hmc_dev.xbar[3].slave
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