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Design and Verification of the Arm Confidential Compute Architecture

This artifact includes the mechanized Coq proofs for the security of RMM/EL3M, the verified software stack for the Arm Confidential Compute Architecture (CCA). It also provides instructions on running the performance evaluations of CCA KVM.

Table of Contents

1. Coq Proofs

We first provide instructions to install Coq proof assistant and check our mechanized proofs by compilation. Then, we summarize the proof sketch.

1.1 Coq installation

We use opam to install Coq and other dependencies. To install opam:

- Ubuntu:
  sudo apt install opam

- Mac OS X:
  brew install opam

Then, initialize opam with the specific version 4.02.0:

opam init --compiler 4.02.0

If you already have opam installed which has a different version, switch to 4.02.0:

opam switch create 4.02.0

Then, use opam to install coq 8.4.6 and menhir 20151112

opam install coq.8.4.6 menhir.20151112

Make sure coqc is in PATH, or add it manually:

export PATH="path/to/.opam/4.02.0/bin":$PATH

.opam/ is usually in user's home directory.

1.2 Compile the proofs

Under the root folder of this repo, simply run

make -j6

to check all the coq proofs. Use a smaller process number if the compilation runs out of memory. The compilation may take a few hours.

1.3 Proof Organization

1.3.1 Layering Refinement Proof

The proof is organized as layers, one folder a layer (e.g. proof/BaremoreService). In each layer, we introduce new functions, define specifications for them, and prove the functions' implementation refine their specifications. We provide the ASTs compiled from the C source code in each layer's Code/ folder which are generated by the tool clightgen of CompCert project. The ASTs play the role of source code in our proof. The specifications of each layer are defined in Specs/ folder. We do two-step simulation when proving code refines specifications. We first prove that the ASTs refine some intermediate specifications (in LowSpecs/), then prove the intermediate specifications refine the final specifications (in Specs/). The simulation proofs are in CodeProof/ (Code Verification) and RefProof/ (Refinement) respectively.

The definition of the machine states shared by all layers is in RData and the bottom layer primitives are defined in AbsAccessor. A full list of layers is shown below:

# Layer Source Code Specification Intermediate Specification Code Verification Refinement
1 BaremoreService Code Specs LowSpecs CodeProof RefProof
2 BaremoreHandler Code Specs LowSpecs CodeProof RefProof
3 BaremoreSMC Code Specs LowSpecs CodeProof RefProof
4 RmiAux Code Specs LowSpecs CodeProof RefProof
5 RmiAux2 Code Specs LowSpecs CodeProof RefProof
6 RmiOps Code Specs LowSpecs CodeProof RefProof
7 RmiSMC Code Specs LowSpecs CodeProof RefProof
8 PSCIAux Code Specs LowSpecs CodeProof RefProof
9 PSCIAux2 Code Specs LowSpecs CodeProof RefProof
10 PSCI Code Specs LowSpecs CodeProof RefProof
11 PSCIHandler Code Specs LowSpecs CodeProof RefProof
12 RVIC Code Specs LowSpecs CodeProof RefProof
13 RVIC2 Code Specs LowSpecs CodeProof RefProof
14 RVIC3 Code Specs LowSpecs CodeProof RefProof
15 RVIC4 Code Specs LowSpecs CodeProof RefProof
16 PendingCheckAux Code Specs LowSpecs CodeProof RefProof
17 PendingCheck Code Specs LowSpecs CodeProof RefProof
18 CtxtSwitchAux Code Specs LowSpecs CodeProof RefProof
19 CtxtSwitch Code Specs LowSpecs CodeProof RefProof
20 RealmTimerHandler Code Specs LowSpecs CodeProof RefProof
21 RealmSyncHandlerAux Code Specs LowSpecs CodeProof RefProof
22 RealmSyncHandler Code Specs LowSpecs CodeProof RefProof
23 RealmExitHandlerAux Code Specs LowSpecs CodeProof RefProof
24 RealmExitHandler Code Specs LowSpecs CodeProof RefProof
25 RunAux Code Specs LowSpecs CodeProof RefProof
26 RunComplete Code Specs LowSpecs CodeProof RefProof
27 RunLoop Code Specs LowSpecs CodeProof RefProof
28 RunSMC Code Specs LowSpecs CodeProof RefProof
29 TableAux Code Specs LowSpecs CodeProof RefProof
30 TableAux2 Code Specs LowSpecs CodeProof RefProof
31 TableAux3 Code Specs LowSpecs CodeProof RefProof
32 TableWalk Code Specs LowSpecs CodeProof RefProof
33 TableDataOpsIntro Code Specs LowSpecs CodeProof RefProof
34 TableDataOpsRef1 Code Specs LowSpecs CodeProof RefProof
35 TableDataOpsRef2 Code Specs LowSpecs CodeProof RefProof
36 TableDataOpsRef3 Code Specs LowSpecs CodeProof RefProof
37 TableDataSMC Code Specs LowSpecs CodeProof RefProof
38 SMCHandler Code Specs LowSpecs CodeProof RefProof
39 RMMHandler Code Specs LowSpecs CodeProof RefProof
  • Mover Oracle related definitions can be found in MoverTypes. The proof that refines page table operations into atomic specifications can be found in the consecutive layers TableDataOpsRef1, TableDataOpsRef2, TableDataOpsRef3.

  • The proof lifting relaxed memory model to sequentially consistent model can be found in RelaxedMemory. The permutation condition proof in Section 4.2 is in PermCondition.

  • Assembly code related definitions and proofs are in Assembly, including:

    • Assembly language semantics definition Asm
    • Coq representation of the proved assembly code AsmCode
    • The specification of assembly code AsmSpec
    • Proving assembly code refines its specification AsmProof, AsmProof2.

1.3.2 Security Proof

Above the top layer RMMHandler, we compose the final security proof in Security.

  • The Ideal machine's definition can be found in SecureMachine.
  • The simulation relation between Ideal machine and Real machine can be found in RefRel.
  • The proof showing that Realms' and Hypervisors' execution preserves simulation relation can be found in SecureProofUser.
  • The proof showing that RMM handler preserves simulation relation can be found in SecureProofRMM1 and SecureProofRMM2.

2. Performance Evaluation

2.0 Prelogue

Evaluation Platform Since the hardware support for CCA is not avaiable yet, we provide an Arm Neoverse N1 System Development Platform (N1SDP) that runs a modified RMM and Trusted Firmware-A (TF-A) as EL3M to get a preliminary measure of CCA performance. We provide remote access for you to run benchmarks on the N1SDP.

Evaluation Tools There are two main changes to our testbed from the original evaluation in the submitted paper. First, due to legal issues, the original evaluation in the submitted paper was done using kvmtool as the required modifications to QEMU to use CCA were not possible then. However, kvmtool is less mature than QEMU, and since then we have been able to make the required changes to QEMU for the evaluation, so we have updated the evaluation based on QEMU. Second, we changed the client machine for the network benchmarks to make this artifact evaluation available to the reviewers as the original setup was not remotely accessible. The new benchmark workloads and results based on the current setup that we plan to report are shown here (Table 1 and Figure 1).

Name Description
Apache Apache server v2.4.41 handling 100 concurrent requests via TLS/SSL from remote ApacheBench v2.3 client, serving the index.html of the GCC 7.5.0 manual.
Hackbench Hackbench using Unix domain sockets and 20 process groups running in 500 loops.
Kernbench Compilation of the Linux kernel v4.18 using allnoconfig for Arm with GCC 9.3.0.
Memcached Memcached v1.5.22 handling requests from a remote memtier benchmark v1.2.11 with the default parameters.
MongoDB MongoDB server v3.6.8 handling requests from a remote YCSB v0.17.0 client running workload A with 16 concurrent threads and operationcount=500000.
MySQL MySQL v8.0.27 running sysbench v1.0.11 with 32 concurrent threads and TLS encryption.
Redis Redis v4.0.9 server handling requests from a remote redis-benchmark in redis-tools v5.0.7 running GET/SET with 50 parallel connections and 12 pipelined requests.
Table 1: Application benchmarks.
qemu-bench.png
Fig 1: Application benchmark performance using QEMU.

2.1 Prerequisites

NOTE: Since we only have one N1SDP for performance benchmarks, multiple reviewers may connect to the jump host but only one can do the evaluation at a time. If you are not able to open the ttyUSB(see instructions below), please wait for the other reviewer to finish the evaluation. Sorry about the inconvenience.

2.1.1 Connecting to the Jump Host

The N1SDP is connected to a jump host with two Intel Xeon E5-2690 8 cores CPUs via a 1Gbps switch. You can use the jump host to access the N1SDP and run network benchmarks from the jump host as the client.

qemu-bench.png
Fig 2: Topology of the N1SDP and jump host.

2.1.2 Setup the Jump Host

Once you have access to the jump host, you may clone this repo to it to run the benchmarks.

git clone https://github.com/columbia/osdi-paper196-ae.git; cd osdi-paper196-ae/client

You will need to download YCSB and memtier_benchmark:

./install.sh

2.2 N1SDP Serial Port

The N1SDP exposes two serial ports to the jump host as described below:

  • /dev/ttyUSB0: Motherboard Configuration Controller (MCC) console, can be used for power cycle for the N1SDP
  • /dev/ttyUSB1: the regular serial port for applicatons

To connect to the serial port, you can use GNU Screen, for example:

screen /dev/ttyUSB1 115200

2.2.1 GNU Screen 101

Below is a simple instruction for GNU Screen. You may refer to the manual page for more information. If you are familiar with the GNU Screen, you can go ahead to Boot the N1SDP.

You can use Ctrl-a c to create a new window in the current session and open the other serial port:

screen /dev/ttyUSB0 115200

Then you can use Ctrl-a c again to create a new window to continue working on the shell of the jump host.

To switch between different windows in a session, you can use Ctrl-a SPACE to switch directly or use Ctrl-a " to show a list of windows and choose the one you want to switch to.

To kill a window, you may Ctrl-d if the window opens a shell or Ctrl-a k if the window opens a serial port. You can also use Ctrl-a \ to kill all windows and terminate the current screen session.

If you disconnected from your ssh session, you can use:

screen -d
screen -r

to resume your previous screen session.

2.2.2 More GNU Screen

Similar to vim, you can also split the current window in GNU Screen by Ctrl-a | for a vertical split or Ctrl-a S for a horizontal split.

You can use Ctrl-a TAB to switch between different splited windows.

You can use Ctrl-a X to close the splitted window(the closed window still runs on the background).

2.3 Booting the N1SDP

You can boot, reboot or shutdown the N1SDP through the MCC console (/dev/ttyUSB0).

Here's a list of useful commands:

+ command ------------------+ function ---------------------------------+
| SHUTDOWN                  | Shutdown PSU (leave micro running)        |
| REBOOT                    | Power cycle system and reboot             |
+---------------------------+-------------------------------------------+

You can use REBOOT to power on the system if it is not yet and then you can checkout the application serial port /dev/ttyUSB1 to see if the system boots.

If the system boots successfully, a GRUB menu should show up shortly after the POST. We will have a detailed explanation for each entry shortly.

2.4 Running the VM and Benchmarks

Due to license constraints, we are not able to provide the source code of CCA software stacks for you to compile and install on the N1SDP. They are preinstalled on the N1SDP, including modified RMM, TF-A, CCA KVM and CCA QEMU, for running the benchmarks.

RMM and TF-A are automatically loaded from the board when the machine powered up and the kernel will be loaded by GRUB.

2.4.1 Choosing the Kernel

In the GRUB menu, you should see four (4) entries as explained below:

Ubuntu                            # DO NOT USE, Ubuntu stock kernel, incompatible with ACCA
Advanced options for Ubuntu       # DO NOT USE, Ubuntu stock kernel, incompatible with ACCA
Ubuntu N1SDP realm - QEMU         # Linux v5.12 kernel modified for ACCA, used for VM benchmarks
Ubuntu N1SDP - SMP benchmark      # Linux v5.12 kernel, passed with cmdline mem=512m for baseline SMP native benchmarks

Here's a quick summary for running the benchmarks, in case you get lost in the upcoming instructions:

You will need five(5) GNU screen windows(W0 - W4) on the jump host to run the benchmarks.

  • W0 and W1 are used for the serial ports.
  • W2 is in the osdi-paper196-ae/client directory.
  • W3 opens an ssh session to the N1SDP and launchs the the VM using ./run-qemu-kvm.sh [bench] or ./run-qemu-cca.sh [bench].
  • W4 opens an ssh session to the N1SDP, configures the network by ./net.sh and pins the vCPU by ./pin_vcpus.sh.

For each benchmark, you need to:

  • W4: ./net.sh(Only needed for the first time after rebooting)
  • W3: ./run-qemu-kvm.sh [bench] or ./run-qemu-cca.sh [bench]
  • W4: ./pin_vcpu.sh
  • W2: ./[bench].sh 192.168.1.1
  • W3: halt -p
  • W2: ./avg.py [bench].txt

2.4.2 Running the VM

Make sure you choose the entry Ubuntu N1SDP realm - QEMU in the GRUB menu. After the login interface prompts, you can ssh to the N1SDP from the jump host:

ssh 192.168.11.10

After you loged in, you can run:

sudo ./net.sh

to configure the bridged network for the VM.

We provide scripts for different VM configurations:

run-qemu-kvm.sh            # Run vanilla KVM using QEMU
run-qemu-cca.sh            # Run CCA KVM using QEMU

You can use the following command to run the VM using vanilla KVM and 2 vCPUs:

./run-qemu-kvm.sh apache

You can replace apache with hack, kern, memcached, mysql, mongo or redis for different workloads.

If you use QEMU, after you run the command, QEMU will wait for the vCPUs being pinned to proceed. To pin the vCPUs, login to the N1SDP on a different shell and run:

./pin_vcpu.sh

Once the vCPUs are pinned, the VM will boot. The VM is configured with IP address 192.168.11.11 and you can run each benchmarks using the scripts on the jump host. We will cover this in the next section.

OPTIONAL for Running Benchmarks

You can login to the VM either through the VM serial port or using ssh. The username and password for the VM are both root:

ssh -o StrictHostKeyChecking=no -o StrictHostKeyChecking=no 192.168.11.11

Note that -o StrictHostKeyChecking=no -o StrictHostKeyChecking=no is required for ssh'ing to the VM because all VM is configured to use the same IP address but they have different ECDSA keys.

2.4.3 Running the Benchmarks on the VM

To run benchmarks on the VM, make sure the network is correctly configured for the VM (by running ./net) before launching the VM. If the network of the VM is configured correctly, its IP address should be 192.168.11.11. You can use ip addr on the VM to check it out.

You can launch the benchmarks on the jump host by ./[bench.sh] IP, for example:

./apache.sh 192.168.11.11

[bench] can be apache, hack, kern, memcached, mongo, mysql or redis.

The results will be saved to the corresponding [bench].txt and you can get the average results by:

./avg [bench].txt

2.4.4 Running the Benchmarks on the baremetal

To run benchmarks on the bare metal, make sure you select the correct kernel (see Choose the Kernel). The bare metal host is configured with IP address 192.168.11.10.

You have to login to the N1SDP and start the correpsonding server program. For a more accurate performance measurement, you may want to only start one server program at once. All of them can be enabled/disabled by systemctl:

sudo systemctl [start|stop] service-name

The benchmarks and the correpsonding command to enable them are listed below:

Benchmarks service-name
Apache sudo systemctl start apache2.service
Memcached sudo systemctl start memcached.service
MongoDB sudo systemctl start mongodb.service
MySQL sudo systemctl start mysql.service
Redis sudo systemctl start redis-server.service

You can use systemctl status service-name to see if the server is up. It is recommended to only start one(1) service at a time for the performance evaluation to avoid the interference from other services.

You don't need any service for Hackbench or Kernbench.

You can launch the benchmarks on the jump host by ./[bench.sh] IP, for example:

./apache.sh 192.168.11.10

[bench] can be apache, hack, kern, memcached, mongo, mysql or redis.

2.5 Epilogue

After finishing the benchmark for a VM, please gently shutdown the VM by running halt -p on the VM to prevent VM disk image corruption. Similarly, to reboot the host, please first run sudo halt -p on the host and after ttyUSB1 shows reboot: Power down, enter reboot on ttyUSB0 to power cycle the machine.

Since RMM shares the same virtual address space with the Linux kernel on this Arm v8 machine, you may encounter unstability when running CCA KVM due to insufficient TLB management. This problem can be solved on the Arm v9 platform but for this artifact evaluation, if you see erroneous behaviors of the machine, such as VM crashing or siginificant outlaying benchmark data, please reboot the N1SDP. We suggest you run CCA KVM on a fresh reboot for every benchmark.

After you finish all performance evaluations, please kindly close all opened USBttys from the jump host so the following reviewers can proceed their evaluations.

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Mirror of Artifact for OSDI 22 Paper: Design and Verification of the Arm Confidential Compute Architecture

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