3.1. Running a Single Node Simulation¶
Now that we’ve completed the setup of our manager instance, it’s time to run
a simulation! In this section, we will simulate 1 target node, for which we
will need a single f1.2xlarge
(1 FPGA) instance.
Make sure you are ssh
or mosh
’d into your manager instance and have sourced
sourceme-f1-manager.sh
before running any of these commands.
3.1.1. Building target software¶
In these instructions, we’ll assume that you want to boot Linux on your simulated node. To do so, we’ll need to build our FireSim-compatible RISC-V Linux distro. For this tutorial, we will use a simple buildroot-based distribution. You can do this like so:
cd firesim/sw/firesim-software
./init-submodules.sh
./marshal -v build br-base.json
This process will take about 10 to 15 minutes on a c5.4xlarge
instance.
Once this is completed, you’ll have the following files:
firesim/sw/firesim-software/images/br-base-bin
- a bootloader + Linux kernel image for the nodes we will simulate.firesim/sw/firesim-software/images/br-base.img
- a disk image for each the nodes we will simulate
These files will be used to form base images to either build more complicated workloads (see the Defining Custom Workloads section) or to copy around for deploying.
3.1.2. Setting up the manager configuration¶
All runtime configuration options for the manager are set in a file called
firesim/deploy/config_runtime.ini
. In this guide, we will explain only the
parts of this file necessary for our purposes. You can find full descriptions of
all of the parameters in the Manager Configuration Files section.
If you open up this file, you will see the following default config (assuming you have not modified it):
# RUNTIME configuration for the FireSim Simulation Manager
# See docs/Advanced-Usage/Manager/Manager-Configuration-Files.rst for
# documentation of all of these params.
[runfarm]
runfarmtag=mainrunfarm
always_expand_runfarm=yes
f1_16xlarges=1
m4_16xlarges=0
f1_4xlarges=0
f1_2xlarges=0
launch_instances_timeout_minutes=60
runinstancemarket=ondemand
spotinterruptionbehavior=terminate
spotmaxprice=ondemand
[targetconfig]
#Set topology=no_net_config to run without a network simulation
topology=example_8config
no_net_num_nodes=2
linklatency=6405
switchinglatency=10
netbandwidth=200
profileinterval=-1
# This references a section from config_build_recipes.ini
# In homogeneous configurations, use this to set the hardware config deployed
# for all simulators
defaulthwconfig=firesim-rocket-quadcore-nic-l2-llc4mb-ddr3
[tracing]
enable=no
# Trace output formats. Only enabled if "enable" is set to "yes" above
# 0 = human readable; 1 = binary (compressed raw data); 2 = flamegraph (stack
# unwinding -> Flame Graph)
output_format=0
# Trigger selector.
# 0 = no trigger; 1 = cycle count trigger; 2 = program counter trigger; 3 =
# instruction trigger
selector=1
start=0
end=-1
[autocounter]
readrate=0
[workload]
workloadname=linux-uniform.json
terminateoncompletion=no
suffixtag=
[hostdebug]
# When enabled (=yes), Zeros-out FPGA-attached DRAM before simulations
# begin (takes 2-5 minutes).
# In general, this is not required to produce deterministic simulations on
# target machines running linux. Enable if you observe simulation non-determinism.
zerooutdram=no
# If disable_synth_asserts=no, simulation will print assertion message and
# terminate simulation if synthesized assertion fires.
# If disable_synth_asserts=yes, simulation ignores assertion firing and
# continues simulation.
disable_synth_asserts=no
[synthprint]
# Start and end cycles for outputting synthesized prints.
# They are given in terms of the base clock and will be converted
# for each clock domain.
start=0
end=-1
# When enabled (=yes), prefix print output with the target cycle at which the print was triggered
cycleprefix=yes
We’ll need to modify a couple of these lines.
First, let’s tell the manager to use the correct numbers and types of instances.
You’ll notice that in the [runfarm]
section, the manager is configured to
launch a Run Farm named mainrunfarm
, consisting of one f1.16xlarge
and
no m4.16xlarge
s, f1.4xlarge
s, or f1.2xlarge
s. The tag specified here allows the
manager to differentiate amongst many parallel run farms (each running
a workload) that you may be operating – but more on that later.
Since we only want to simulate a single node, let’s switch to using one
f1.2xlarge
and no f1.16xlarge
s. To do so, change this section to:
[runfarm]
# per aws restrictions, this tag cannot be longer than 255 chars
runfarmtag=mainrunfarm
f1_16xlarges=0
f1_4xlarges=0
m4_16xlarges=0
f1_2xlarges=1
You’ll see other parameters here, like runinstancemarket
,
spotinterruptionbehavior
, and spotmaxprice
. If you’re an experienced
AWS user, you can see what these do by looking at the
Manager Configuration Files section. Otherwise, don’t change them.
Now, let’s change the [targetconfig]
section to model the correct target design.
By default, it is set to model an 8-node cluster with a cycle-accurate network.
Instead, we want to model a single-node with no network. To do so, we will need
to change a few items in this section:
[targetconfig]
topology=no_net_config
no_net_num_nodes=1
linklatency=6405
switchinglatency=10
netbandwidth=200
profileinterval=-1
# This references a section from config_hwconfigs.ini
# In homogeneous configurations, use this to set the hardware config deployed
# for all simulators
defaulthwconfig=firesim-rocket-quadcore-no-nic-l2-llc4mb-ddr3
Note that we changed three of the parameters here: topology
is now set to
no_net_config
, indicating that we do not want a network. Then,
no_net_num_nodes
is set to 1
, indicating that we only want to simulate
one node. Lastly, we changed defaulthwconfig
from
firesim-rocket-quadcore-nic-l2-llc4mb-ddr3
to
firesim-rocket-quadcore-no-nic-l2-llc4mb-ddr3
. Notice the subtle difference in this
last option? All we did is switch to a hardware configuration that does not
have a NIC. This hardware configuration models a Quad-core Rocket Chip with 4
MB of L2 cache and 16 GB of DDR3, and no network interface card.
We will leave the last section ([workload]
) unchanged here, since we do
want to run the buildroot-based Linux on our simulated system. The terminateoncompletion
feature is an advanced feature that you can learn more about in the
Manager Configuration Files section.
As a final sanity check, your config_runtime.ini
file should now look like this:
# RUNTIME configuration for the FireSim Simulation Manager
# See docs/Configuration-Details.rst for documentation of all of these params.
[runfarm]
runfarmtag=mainrunfarm
f1_16xlarges=0
f1_4xlarges=0
m4_16xlarges=0
f1_2xlarges=1
runinstancemarket=ondemand
spotinterruptionbehavior=terminate
spotmaxprice=ondemand
[targetconfig]
topology=no_net_config
no_net_num_nodes=1
linklatency=6405
switchinglatency=10
netbandwidth=200
profileinterval=-1
# This references a section from config_hwconfigs.ini
# In homogeneous configurations, use this to set the hardware config deployed
# for all simulators
defaulthwconfig=firesim-rocket-quadcore-no-nic-l2-llc4mb-ddr3
[workload]
workloadname=linux-uniform.json
terminateoncompletion=no
Attention
[Advanced users] Simulating BOOM instead of Rocket Chip: If you would like to simulate a single-core BOOM as a target, set defaulthwconfig
to firesim-boom-singlecore-no-nic-l2-llc4mb-ddr3
.
3.1.3. Launching a Simulation!¶
Now that we’ve told the manager everything it needs to know in order to run our single-node simulation, let’s actually launch an instance and run it!
3.1.3.1. Starting the Run Farm¶
First, we will tell the manager to launch our Run Farm, as we specified above. When you do this, you will start getting charged for the running EC2 instances (in addition to your manager).
To do launch your run farm, run:
firesim launchrunfarm
You should expect output like the following:
centos@ip-172-30-2-111.us-west-2.compute.internal:~/firesim-new/deploy$ firesim launchrunfarm
FireSim Manager. Docs: http://docs.fires.im
Running: launchrunfarm
Waiting for instance boots: f1.16xlarges
Waiting for instance boots: f1.4xlarges
Waiting for instance boots: m4.16xlarges
Waiting for instance boots: f1.2xlarges
i-0d6c29ac507139163 booted!
The full log of this run is:
/home/centos/firesim-new/deploy/logs/2018-05-19--00-19-43-launchrunfarm-B4Q2ROAK0JN9EDE4.log
The output will rapidly progress to Waiting for instance boots: f1.2xlarges
and then take a minute or two while your f1.2xlarge
instance launches.
Once the launches complete, you should see the instance id printed and the instance
will also be visible in your AWS EC2 Management console. The manager will tag
the instances launched with this operation with the value you specified above
as the runfarmtag
parameter from the config_runtime.ini
file, which we left
set as mainrunfarm
. This value allows the manager to tell multiple Run Farms
apart – i.e., you can have multiple independent Run Farms running different
workloads/hardware configurations in parallel. This is detailed in the
Manager Configuration Files and the firesim launchrunfarm
sections – you do not need to be familiar with it here.
3.1.3.2. Setting up the simulation infrastructure¶
The manager will also take care of building and deploying all software components necessary to run your simulation. The manager will also handle flashing FPGAs. To tell the manager to setup our simulation infrastructure, let’s run:
firesim infrasetup
For a complete run, you should expect output like the following:
centos@ip-172-30-2-111.us-west-2.compute.internal:~/firesim-new/deploy$ firesim infrasetup
FireSim Manager. Docs: http://docs.fires.im
Running: infrasetup
Building FPGA software driver for FireSim-FireSimQuadRocketConfig-F90MHz_BaseF1Config
[172.30.2.174] Executing task 'instance_liveness'
[172.30.2.174] Checking if host instance is up...
[172.30.2.174] Executing task 'infrasetup_node_wrapper'
[172.30.2.174] Copying FPGA simulation infrastructure for slot: 0.
[172.30.2.174] Installing AWS FPGA SDK on remote nodes.
[172.30.2.174] Unloading XDMA/EDMA/XOCL Driver Kernel Module.
[172.30.2.174] Copying AWS FPGA XDMA driver to remote node.
[172.30.2.174] Loading XDMA Driver Kernel Module.
[172.30.2.174] Clearing FPGA Slot 0.
[172.30.2.174] Flashing FPGA Slot: 0 with agfi: agfi-0eaa90f6bb893c0f7.
[172.30.2.174] Unloading XDMA/EDMA/XOCL Driver Kernel Module.
[172.30.2.174] Loading XDMA Driver Kernel Module.
The full log of this run is:
/home/centos/firesim-new/deploy/logs/2018-05-19--00-32-02-infrasetup-9DJJCX29PF4GAIVL.log
Many of these tasks will take several minutes, especially on a clean copy of
the repo. The console output here contains the “user-friendly” version of the
output. If you want to see detailed progress as it happens, tail -f
the
latest logfile in firesim/deploy/logs/
.
At this point, the f1.2xlarge
instance in our Run Farm has all the infrastructure
necessary to run a simulation.
So, let’s launch our simulation!
3.1.3.3. Running a simulation!¶
Finally, let’s run our simulation! To do so, run:
firesim runworkload
This command boots up a simulation and prints out the live status of the simulated nodes every 10s. When you do this, you will initially see output like:
centos@ip-172-30-2-111.us-west-2.compute.internal:~/firesim-new/deploy$ firesim runworkload
FireSim Manager. Docs: http://docs.fires.im
Running: runworkload
Creating the directory: /home/centos/firesim-new/deploy/results-workload/2018-05-19--00-38-52-linux-uniform/
[172.30.2.174] Executing task 'instance_liveness'
[172.30.2.174] Checking if host instance is up...
[172.30.2.174] Executing task 'boot_simulation_wrapper'
[172.30.2.174] Starting FPGA simulation for slot: 0.
[172.30.2.174] Executing task 'monitor_jobs_wrapper'
If you don’t look quickly, you might miss it, since it will get replaced with a live status page:
FireSim Simulation Status @ 2018-05-19 00:38:56.062737
--------------------------------------------------------------------------------
This workload's output is located in:
/home/centos/firesim-new/deploy/results-workload/2018-05-19--00-38-52-linux-uniform/
This run's log is located in:
/home/centos/firesim-new/deploy/logs/2018-05-19--00-38-52-runworkload-JS5IGTV166X169DZ.log
This status will update every 10s.
--------------------------------------------------------------------------------
Instances
--------------------------------------------------------------------------------
Instance IP: 172.30.2.174 | Terminated: False
--------------------------------------------------------------------------------
Simulated Switches
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
Simulated Nodes/Jobs
--------------------------------------------------------------------------------
Instance IP: 172.30.2.174 | Job: linux-uniform0 | Sim running: True
--------------------------------------------------------------------------------
Summary
--------------------------------------------------------------------------------
1/1 instances are still running.
1/1 simulations are still running.
--------------------------------------------------------------------------------
This will only exit once all of the simulated nodes have shut down. So, let’s let it
run and open another ssh connection to the manager instance. From there, cd
into
your firesim directory again and source sourceme-f1-manager.sh
again to get
our ssh key setup. To access our simulated system, ssh into the IP address being
printed by the status page, from your manager instance. In our case, from
the above output, we see that our simulated system is running on the instance with
IP 172.30.2.174
. So, run:
[RUN THIS ON YOUR MANAGER INSTANCE!]
ssh 172.30.2.174
This will log you into the instance running the simulation. Then, to attach to the console of the simulated system, run:
screen -r fsim0
Voila! You should now see Linux booting on the simulated system and then be prompted with a Linux login prompt, like so:
[truncated Linux boot output]
[ 0.020000] VFS: Mounted root (ext2 filesystem) on device 254:0.
[ 0.020000] devtmpfs: mounted
[ 0.020000] Freeing unused kernel memory: 140K
[ 0.020000] This architecture does not have kernel memory protection.
mount: mounting sysfs on /sys failed: No such device
Starting logging: OK
Starting mdev...
mdev: /sys/dev: No such file or directory
modprobe: can't change directory to '/lib/modules': No such file or directory
Initializing random number generator... done.
Starting network: ip: SIOCGIFFLAGS: No such device
ip: can't find device 'eth0'
FAIL
Starting dropbear sshd: OK
Welcome to Buildroot
buildroot login:
You can ignore the messages about the network – that is expected because we are simulating a design without a NIC.
Now, you can login to the system! The username is root
and the password is
firesim
. At this point, you should be presented with a regular console,
where you can type commands into the simulation and run programs. For example:
Welcome to Buildroot
buildroot login: root
Password:
# uname -a
Linux buildroot 4.15.0-rc6-31580-g9c3074b5c2cd #1 SMP Thu May 17 22:28:35 UTC 2018 riscv64 GNU/Linux
#
At this point, you can run workloads as you’d like. To finish off this tutorial,
let’s poweroff the simulated system and see what the manager does. To do so,
in the console of the simulated system, run poweroff -f
:
Welcome to Buildroot
buildroot login: root
Password:
# uname -a
Linux buildroot 4.15.0-rc6-31580-g9c3074b5c2cd #1 SMP Thu May 17 22:28:35 UTC 2018 riscv64 GNU/Linux
# poweroff -f
You should see output like the following from the simulation console:
# poweroff -f
[ 12.456000] reboot: Power down
Power off
time elapsed: 468.8 s, simulation speed = 88.50 MHz
*** PASSED *** after 41492621244 cycles
Runs 41492621244 cycles
[PASS] FireSim Test
SEED: 1526690334
Script done, file is uartlog
[screen is terminating]
You’ll also notice that the manager polling loop exited! You’ll see output like this from the manager:
FireSim Simulation Status @ 2018-05-19 00:46:50.075885
--------------------------------------------------------------------------------
This workload's output is located in:
/home/centos/firesim-new/deploy/results-workload/2018-05-19--00-38-52-linux-uniform/
This run's log is located in:
/home/centos/firesim-new/deploy/logs/2018-05-19--00-38-52-runworkload-JS5IGTV166X169DZ.log
This status will update every 10s.
--------------------------------------------------------------------------------
Instances
--------------------------------------------------------------------------------
Instance IP: 172.30.2.174 | Terminated: False
--------------------------------------------------------------------------------
Simulated Switches
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
Simulated Nodes/Jobs
--------------------------------------------------------------------------------
Instance IP: 172.30.2.174 | Job: linux-uniform0 | Sim running: False
--------------------------------------------------------------------------------
Summary
--------------------------------------------------------------------------------
1/1 instances are still running.
0/1 simulations are still running.
--------------------------------------------------------------------------------
FireSim Simulation Exited Successfully. See results in:
/home/centos/firesim-new/deploy/results-workload/2018-05-19--00-38-52-linux-uniform/
The full log of this run is:
/home/centos/firesim-new/deploy/logs/2018-05-19--00-38-52-runworkload-JS5IGTV166X169DZ.log
If you take a look at the workload output directory given in the manager output (in this case, /home/centos/firesim-new/deploy/results-workload/2018-05-19--00-38-52-linux-uniform/
), you’ll see the following:
centos@ip-172-30-2-111.us-west-2.compute.internal:~/firesim-new/deploy/results-workload/2018-05-19--00-38-52-linux-uniform$ ls -la */*
-rw-rw-r-- 1 centos centos 797 May 19 00:46 linux-uniform0/memory_stats.csv
-rw-rw-r-- 1 centos centos 125 May 19 00:46 linux-uniform0/os-release
-rw-rw-r-- 1 centos centos 7316 May 19 00:46 linux-uniform0/uartlog
What are these files? They are specified to the manager in a configuration file
(firesim/deploy/workloads/linux-uniform.json
) as files that we want
automatically copied back to our manager after we run a simulation, which is
useful for running benchmarks automatically. The
Defining Custom Workloads section describes this process in detail.
For now, let’s wrap-up our tutorial by terminating the f1.2xlarge
instance
that we launched. To do so, run:
firesim terminaterunfarm
Which should present you with the following:
centos@ip-172-30-2-111.us-west-2.compute.internal:~/firesim-new/deploy$ firesim terminaterunfarm
FireSim Manager. Docs: http://docs.fires.im
Running: terminaterunfarm
IMPORTANT!: This will terminate the following instances:
f1.16xlarges
[]
f1.4xlarges
[]
m4.16xlarges
[]
f1.2xlarges
['i-0d6c29ac507139163']
Type yes, then press enter, to continue. Otherwise, the operation will be cancelled.
You must type yes
then hit enter here to have your instances terminated. Once
you do so, you will see:
[ truncated output from above ]
Type yes, then press enter, to continue. Otherwise, the operation will be cancelled.
yes
Instances terminated. Please confirm in your AWS Management Console.
The full log of this run is:
/home/centos/firesim-new/deploy/logs/2018-05-19--00-51-54-terminaterunfarm-T9ZAED3LJUQQ3K0N.log
At this point, you should always confirm in your AWS management console that the instance is in the shutting-down or terminated states. You are ultimately responsible for ensuring that your instances are terminated appropriately.
Congratulations on running your first FireSim simulation! At this point, you can check-out some of the advanced features of FireSim in the sidebar to the left (for example, we expect that many people will be interested in the ability to automatically run the SPEC17 benchmarks: SPEC 2017), or you can continue on with the cluster simulation tutorial.