From patchwork Mon Feb 3 06:11:06 2020 Content-Type: text/plain; charset="utf-8" MIME-Version: 1.0 Content-Transfer-Encoding: 8bit X-Patchwork-Submitter: David Gibson X-Patchwork-Id: 11362093 Return-Path: Received: from mail.kernel.org (pdx-korg-mail-1.web.codeaurora.org [172.30.200.123]) by pdx-korg-patchwork-2.web.codeaurora.org (Postfix) with ESMTP id 3B07E1398 for ; Mon, 3 Feb 2020 06:19:00 +0000 (UTC) Received: from lists.gnu.org (lists.gnu.org [209.51.188.17]) (using TLSv1.2 with cipher ECDHE-RSA-AES256-GCM-SHA384 (256/256 bits)) (No client certificate requested) by mail.kernel.org (Postfix) with ESMTPS id E65122080D for ; Mon, 3 Feb 2020 06:18:59 +0000 (UTC) Authentication-Results: mail.kernel.org; dkim=fail reason="signature verification failed" (1024-bit key) header.d=gibson.dropbear.id.au header.i=@gibson.dropbear.id.au header.b="gfeGQSg7" DMARC-Filter: OpenDMARC Filter v1.3.2 mail.kernel.org E65122080D Authentication-Results: mail.kernel.org; dmarc=none (p=none dis=none) header.from=gibson.dropbear.id.au Authentication-Results: mail.kernel.org; spf=pass smtp.mailfrom=qemu-devel-bounces+patchwork-qemu-devel=patchwork.kernel.org@nongnu.org Received: from localhost ([::1]:34874 helo=lists1p.gnu.org) by lists.gnu.org with esmtp (Exim 4.90_1) (envelope-from ) id 1iyV4V-00080V-3s for patchwork-qemu-devel@patchwork.kernel.org; Mon, 03 Feb 2020 01:18:59 -0500 Received: from eggs.gnu.org ([2001:470:142:3::10]:57552) by lists.gnu.org with esmtp (Exim 4.90_1) (envelope-from ) id 1iyUxZ-0002us-2H for qemu-devel@nongnu.org; Mon, 03 Feb 2020 01:11:54 -0500 Received: from Debian-exim by eggs.gnu.org with spam-scanned (Exim 4.71) (envelope-from ) id 1iyUxS-0002jS-GJ for qemu-devel@nongnu.org; Mon, 03 Feb 2020 01:11:48 -0500 Received: from ozlabs.org ([203.11.71.1]:32889) by eggs.gnu.org with esmtps (TLS1.0:DHE_RSA_AES_256_CBC_SHA1:32) (Exim 4.71) (envelope-from ) id 1iyUxR-0002cT-H5; Mon, 03 Feb 2020 01:11:42 -0500 Received: by ozlabs.org (Postfix, from userid 1007) id 489yBq0ZzNz9sSZ; Mon, 3 Feb 2020 17:11:30 +1100 (AEDT) DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/simple; d=gibson.dropbear.id.au; s=201602; t=1580710291; bh=9vfuq3Pt8p0OO2vMbqtQTPn8S+3Ztyw7AsWGda7qqYI=; h=From:To:Cc:Subject:Date:In-Reply-To:References:From; b=gfeGQSg7ZN1vWR2865TmsxoEVcVgea9vW6bOYT0yRL5Yk/Ig4lk+39W3NNlnjuWsF uqerdMW1T0rBO2X4U/0Clw5X+SecNJxDyMYQrP9eNIA1jLPKwueFcEfubclGyY5mWR U8PMuvm80CXsmX+cTWA4tDiuM4HbWttlLLGGa5P8= From: David Gibson To: peter.maydell@linaro.org Subject: [PULL 18/35] docs/specs/tpm: reST-ify TPM documentation Date: Mon, 3 Feb 2020 17:11:06 +1100 Message-Id: <20200203061123.59150-19-david@gibson.dropbear.id.au> X-Mailer: git-send-email 2.24.1 In-Reply-To: <20200203061123.59150-1-david@gibson.dropbear.id.au> References: <20200203061123.59150-1-david@gibson.dropbear.id.au> MIME-Version: 1.0 X-detected-operating-system: by eggs.gnu.org: GNU/Linux 2.2.x-3.x [generic] [fuzzy] X-Received-From: 203.11.71.1 X-BeenThere: qemu-devel@nongnu.org X-Mailman-Version: 2.1.23 Precedence: list List-Id: List-Unsubscribe: , List-Archive: List-Post: List-Help: List-Subscribe: , Cc: lvivier@redhat.com, qemu-devel@nongnu.org, groug@kaod.org, qemu-ppc@nongnu.org, =?utf-8?q?Marc-Andr=C3=A9_Lureau?= , David Gibson , Stefan Berger Errors-To: qemu-devel-bounces+patchwork-qemu-devel=patchwork.kernel.org@nongnu.org Sender: "Qemu-devel" From: Marc-André Lureau Signed-off-by: Marc-André Lureau Reviewed-by: Stefan Berger Message-Id: <20200121152935.649898-7-stefanb@linux.ibm.com> Signed-off-by: David Gibson --- docs/specs/index.rst | 1 + docs/specs/tpm.rst | 503 +++++++++++++++++++++++++++++++++++++++++++ docs/specs/tpm.txt | 445 -------------------------------------- 3 files changed, 504 insertions(+), 445 deletions(-) create mode 100644 docs/specs/tpm.rst delete mode 100644 docs/specs/tpm.txt diff --git a/docs/specs/index.rst b/docs/specs/index.rst index 984ba44029..de46a8b5e7 100644 --- a/docs/specs/index.rst +++ b/docs/specs/index.rst @@ -13,3 +13,4 @@ Contents: ppc-xive ppc-spapr-xive acpi_hw_reduced_hotplug + tpm diff --git a/docs/specs/tpm.rst b/docs/specs/tpm.rst new file mode 100644 index 0000000000..2bdf637f55 --- /dev/null +++ b/docs/specs/tpm.rst @@ -0,0 +1,503 @@ +=============== +QEMU TPM Device +=============== + +Guest-side hardware interface +============================= + +TIS interface +------------- + +The QEMU TPM emulation implements a TPM TIS hardware interface +following the Trusted Computing Group's specification "TCG PC Client +Specific TPM Interface Specification (TIS)", Specification Version +1.3, 21 March 2013. (see the `TIS specification`_, or a later version +of it). + +The TIS interface makes a memory mapped IO region in the area +0xfed40000-0xfed44fff available to the guest operating system. + +QEMU files related to TPM TIS interface: + - ``hw/tpm/tpm_tis.c`` + - ``hw/tpm/tpm_tis.h`` + +CRB interface +------------- + +QEMU also implements a TPM CRB interface following the Trusted +Computing Group's specification "TCG PC Client Platform TPM Profile +(PTP) Specification", Family "2.0", Level 00 Revision 01.03 v22, May +22, 2017. (see the `CRB specification`_, or a later version of it) + +The CRB interface makes a memory mapped IO region in the area +0xfed40000-0xfed40fff (1 locality) available to the guest +operating system. + +QEMU files related to TPM CRB interface: + - ``hw/tpm/tpm_crb.c`` + +SPAPR interface +--------------- + +pSeries (ppc64) machines offer a tpm-spapr device model. + +QEMU files related to the SPAPR interface: + - ``hw/tpm/tpm_spapr.c`` + +fw_cfg interface +================ + +The bios/firmware may read the ``"etc/tpm/config"`` fw_cfg entry for +configuring the guest appropriately. + +The entry of 6 bytes has the following content, in little-endian: + +.. code-block:: c + + #define TPM_VERSION_UNSPEC 0 + #define TPM_VERSION_1_2 1 + #define TPM_VERSION_2_0 2 + + #define TPM_PPI_VERSION_NONE 0 + #define TPM_PPI_VERSION_1_30 1 + + struct FwCfgTPMConfig { + uint32_t tpmppi_address; /* PPI memory location */ + uint8_t tpm_version; /* TPM version */ + uint8_t tpmppi_version; /* PPI version */ + }; + +ACPI interface +============== + +The TPM device is defined with ACPI ID "PNP0C31". QEMU builds a SSDT +and passes it into the guest through the fw_cfg device. The device +description contains the base address of the TIS interface 0xfed40000 +and the size of the MMIO area (0x5000). In case a TPM2 is used by +QEMU, a TPM2 ACPI table is also provided. The device is described to +be used in polling mode rather than interrupt mode primarily because +no unused IRQ could be found. + +To support measurement logs to be written by the firmware, +e.g. SeaBIOS, a TCPA table is implemented. This table provides a 64kb +buffer where the firmware can write its log into. For TPM 2 only a +more recent version of the TPM2 table provides support for +measurements logs and a TCPA table does not need to be created. + +The TCPA and TPM2 ACPI tables follow the Trusted Computing Group +specification "TCG ACPI Specification" Family "1.2" and "2.0", Level +00 Revision 00.37. (see the `ACPI specification`_, or a later version +of it) + +ACPI PPI Interface +------------------ + +QEMU supports the Physical Presence Interface (PPI) for TPM 1.2 and +TPM 2. This interface requires ACPI and firmware support. (see the +`PPI specification`_) + +PPI enables a system administrator (root) to request a modification to +the TPM upon reboot. The PPI specification defines the operation +requests and the actions the firmware has to take. The system +administrator passes the operation request number to the firmware +through an ACPI interface which writes this number to a memory +location that the firmware knows. Upon reboot, the firmware finds the +number and sends commands to the TPM. The firmware writes the TPM +result code and the operation request number to a memory location that +ACPI can read from and pass the result on to the administrator. + +The PPI specification defines a set of mandatory and optional +operations for the firmware to implement. The ACPI interface also +allows an administrator to list the supported operations. In QEMU the +ACPI code is generated by QEMU, yet the firmware needs to implement +support on a per-operations basis, and different firmwares may support +a different subset. Therefore, QEMU introduces the virtual memory +device for PPI where the firmware can indicate which operations it +supports and ACPI can enable the ones that are supported and disable +all others. This interface lies in main memory and has the following +layout: + + +-------------+--------+--------+-------------------------------------------+ + | Field | Length | Offset | Description | + +=============+========+========+===========================================+ + | ``func`` | 0x100 | 0x000 | Firmware sets values for each supported | + | | | | operation. See defined values below. | + +-------------+--------+--------+-------------------------------------------+ + | ``ppin`` | 0x1 | 0x100 | SMI interrupt to use. Set by firmware. | + | | | | Not supported. | + +-------------+--------+--------+-------------------------------------------+ + | ``ppip`` | 0x4 | 0x101 | ACPI function index to pass to SMM code. | + | | | | Set by ACPI. Not supported. | + +-------------+--------+--------+-------------------------------------------+ + | ``pprp`` | 0x4 | 0x105 | Result of last executed operation. Set by | + | | | | firmware. See function index 5 for values.| + +-------------+--------+--------+-------------------------------------------+ + | ``pprq`` | 0x4 | 0x109 | Operation request number to execute. See | + | | | | 'Physical Presence Interface Operation | + | | | | Summary' tables in specs. Set by ACPI. | + +-------------+--------+--------+-------------------------------------------+ + | ``pprm`` | 0x4 | 0x10d | Operation request optional parameter. | + | | | | Values depend on operation. Set by ACPI. | + +-------------+--------+--------+-------------------------------------------+ + | ``lppr`` | 0x4 | 0x111 | Last executed operation request number. | + | | | | Copied from pprq field by firmware. | + +-------------+--------+--------+-------------------------------------------+ + | ``fret`` | 0x4 | 0x115 | Result code from SMM function. | + | | | | Not supported. | + +-------------+--------+--------+-------------------------------------------+ + | ``res1`` | 0x40 | 0x119 | Reserved for future use | + +-------------+--------+--------+-------------------------------------------+ + |``next_step``| 0x1 | 0x159 | Operation to execute after reboot by | + | | | | firmware. Used by firmware. | + +-------------+--------+--------+-------------------------------------------+ + | ``movv`` | 0x1 | 0x15a | Memory overwrite variable | + +-------------+--------+--------+-------------------------------------------+ + +The following values are supported for the ``func`` field. They +correspond to the values used by ACPI function index 8. + + +----------+-------------------------------------------------------------+ + | Value | Description | + +==========+=============================================================+ + | 0 | Operation is not implemented. | + +----------+-------------------------------------------------------------+ + | 1 | Operation is only accessible through firmware. | + +----------+-------------------------------------------------------------+ + | 2 | Operation is blocked for OS by firmware configuration. | + +----------+-------------------------------------------------------------+ + | 3 | Operation is allowed and physically present user required. | + +----------+-------------------------------------------------------------+ + | 4 | Operation is allowed and physically present user is not | + | | required. | + +----------+-------------------------------------------------------------+ + +The location of the table is given by the fw_cfg ``tpmppi_address`` +field. The PPI memory region size is 0x400 (``TPM_PPI_ADDR_SIZE``) to +leave enough room for future updates. + +QEMU files related to TPM ACPI tables: + - ``hw/i386/acpi-build.c`` + - ``include/hw/acpi/tpm.h`` + +TPM backend devices +=================== + +The TPM implementation is split into two parts, frontend and +backend. The frontend part is the hardware interface, such as the TPM +TIS interface described earlier, and the other part is the TPM backend +interface. The backend interfaces implement the interaction with a TPM +device, which may be a physical or an emulated device. The split +between the front- and backend devices allows a frontend to be +connected with any available backend. This enables the TIS interface +to be used with the passthrough backend or the swtpm backend. + +QEMU files related to TPM backends: + - ``backends/tpm.c`` + - ``include/sysemu/tpm_backend.h`` + - ``include/sysemu/tpm_backend_int.h`` + +The QEMU TPM passthrough device +------------------------------- + +In case QEMU is run on Linux as the host operating system it is +possible to make the hardware TPM device available to a single QEMU +guest. In this case the user must make sure that no other program is +using the device, e.g., /dev/tpm0, before trying to start QEMU with +it. + +The passthrough driver uses the host's TPM device for sending TPM +commands and receiving responses from. Besides that it accesses the +TPM device's sysfs entry for support of command cancellation. Since +none of the state of a hardware TPM can be migrated between hosts, +virtual machine migration is disabled when the TPM passthrough driver +is used. + +Since the host's TPM device will already be initialized by the host's +firmware, certain commands, e.g. ``TPM_Startup()``, sent by the +virtual firmware for device initialization, will fail. In this case +the firmware should not use the TPM. + +Sharing the device with the host is generally not a recommended usage +scenario for a TPM device. The primary reason for this is that two +operating systems can then access the device's single set of +resources, such as platform configuration registers +(PCRs). Applications or kernel security subsystems, such as the Linux +Integrity Measurement Architecture (IMA), are not expecting to share +PCRs. + +QEMU files related to the TPM passthrough device: + - ``hw/tpm/tpm_passthrough.c`` + - ``hw/tpm/tpm_util.c`` + - ``hw/tpm/tpm_util.h`` + + +Command line to start QEMU with the TPM passthrough device using the host's +hardware TPM ``/dev/tpm0``: + +.. code-block:: console + + qemu-system-x86_64 -display sdl -accel kvm \ + -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ + -tpmdev passthrough,id=tpm0,path=/dev/tpm0 \ + -device tpm-tis,tpmdev=tpm0 test.img + + +The following commands should result in similar output inside the VM +with a Linux kernel that either has the TPM TIS driver built-in or +available as a module: + +.. code-block:: console + + # dmesg | grep -i tpm + [ 0.711310] tpm_tis 00:06: 1.2 TPM (device=id 0x1, rev-id 1) + + # dmesg | grep TCPA + [ 0.000000] ACPI: TCPA 0x0000000003FFD191C 000032 (v02 BOCHS \ + BXPCTCPA 0000001 BXPC 00000001) + + # ls -l /dev/tpm* + crw-------. 1 root root 10, 224 Jul 11 10:11 /dev/tpm0 + + # find /sys/devices/ | grep pcrs$ | xargs cat + PCR-00: 35 4E 3B CE 23 9F 38 59 ... + ... + PCR-23: 00 00 00 00 00 00 00 00 ... + +The QEMU TPM emulator device +---------------------------- + +The TPM emulator device uses an external TPM emulator called 'swtpm' +for sending TPM commands to and receiving responses from. The swtpm +program must have been started before trying to access it through the +TPM emulator with QEMU. + +The TPM emulator implements a command channel for transferring TPM +commands and responses as well as a control channel over which control +commands can be sent. (see the `SWTPM protocol`_ specification) + +The control channel serves the purpose of resetting, initializing, and +migrating the TPM state, among other things. + +The swtpm program behaves like a hardware TPM and therefore needs to +be initialized by the firmware running inside the QEMU virtual +machine. One necessary step for initializing the device is to send +the TPM_Startup command to it. SeaBIOS, for example, has been +instrumented to initialize a TPM 1.2 or TPM 2 device using this +command. + +QEMU files related to the TPM emulator device: + - ``hw/tpm/tpm_emulator.c`` + - ``hw/tpm/tpm_util.c`` + - ``hw/tpm/tpm_util.h`` + +The following commands start the swtpm with a UnixIO control channel over +a socket interface. They do not need to be run as root. + +.. code-block:: console + + mkdir /tmp/mytpm1 + swtpm socket --tpmstate dir=/tmp/mytpm1 \ + --ctrl type=unixio,path=/tmp/mytpm1/swtpm-sock \ + --log level=20 + +Command line to start QEMU with the TPM emulator device communicating +with the swtpm (x86): + +.. code-block:: console + + qemu-system-x86_64 -display sdl -accel kvm \ + -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ + -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ + -tpmdev emulator,id=tpm0,chardev=chrtpm \ + -device tpm-tis,tpmdev=tpm0 test.img + +In case a pSeries machine is emulated, use the following command line: + +.. code-block:: console + + qemu-system-ppc64 -display sdl -machine pseries,accel=kvm \ + -m 1024 -bios slof.bin -boot menu=on \ + -nodefaults -device VGA -device pci-ohci -device usb-kbd \ + -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ + -tpmdev emulator,id=tpm0,chardev=chrtpm \ + -device tpm-spapr,tpmdev=tpm0 \ + -device spapr-vscsi,id=scsi0,reg=0x00002000 \ + -device virtio-blk-pci,scsi=off,bus=pci.0,addr=0x3,drive=drive-virtio-disk0,id=virtio-disk0 \ + -drive file=test.img,format=raw,if=none,id=drive-virtio-disk0 + +In case SeaBIOS is used as firmware, it should show the TPM menu item +after entering the menu with 'ESC'. + +.. code-block:: console + + Select boot device: + 1. DVD/CD [ata1-0: QEMU DVD-ROM ATAPI-4 DVD/CD] + [...] + 5. Legacy option rom + + t. TPM Configuration + +The following commands should result in similar output inside the VM +with a Linux kernel that either has the TPM TIS driver built-in or +available as a module: + +.. code-block:: console + + # dmesg | grep -i tpm + [ 0.711310] tpm_tis 00:06: 1.2 TPM (device=id 0x1, rev-id 1) + + # dmesg | grep TCPA + [ 0.000000] ACPI: TCPA 0x0000000003FFD191C 000032 (v02 BOCHS \ + BXPCTCPA 0000001 BXPC 00000001) + + # ls -l /dev/tpm* + crw-------. 1 root root 10, 224 Jul 11 10:11 /dev/tpm0 + + # find /sys/devices/ | grep pcrs$ | xargs cat + PCR-00: 35 4E 3B CE 23 9F 38 59 ... + ... + PCR-23: 00 00 00 00 00 00 00 00 ... + +Migration with the TPM emulator +=============================== + +The TPM emulator supports the following types of virtual machine +migration: + +- VM save / restore (migration into a file) +- Network migration +- Snapshotting (migration into storage like QoW2 or QED) + +The following command sequences can be used to test VM save / restore. + +In a 1st terminal start an instance of a swtpm using the following command: + +.. code-block:: console + + mkdir /tmp/mytpm1 + swtpm socket --tpmstate dir=/tmp/mytpm1 \ + --ctrl type=unixio,path=/tmp/mytpm1/swtpm-sock \ + --log level=20 --tpm2 + +In a 2nd terminal start the VM: + +.. code-block:: console + + qemu-system-x86_64 -display sdl -accel kvm \ + -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ + -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ + -tpmdev emulator,id=tpm0,chardev=chrtpm \ + -device tpm-tis,tpmdev=tpm0 \ + -monitor stdio \ + test.img + +Verify that the attached TPM is working as expected using applications +inside the VM. + +To store the state of the VM use the following command in the QEMU +monitor in the 2nd terminal: + +.. code-block:: console + + (qemu) migrate "exec:cat > testvm.bin" + (qemu) quit + +At this point a file called ``testvm.bin`` should exists and the swtpm +and QEMU processes should have ended. + +To test 'VM restore' you have to start the swtpm with the same +parameters as before. If previously a TPM 2 [--tpm2] was saved, --tpm2 +must now be passed again on the command line. + +In the 1st terminal restart the swtpm with the same command line as +before: + +.. code-block:: console + + swtpm socket --tpmstate dir=/tmp/mytpm1 \ + --ctrl type=unixio,path=/tmp/mytpm1/swtpm-sock \ + --log level=20 --tpm2 + +In the 2nd terminal restore the state of the VM using the additional +'-incoming' option. + +.. code-block:: console + + qemu-system-x86_64 -display sdl -accel kvm \ + -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ + -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ + -tpmdev emulator,id=tpm0,chardev=chrtpm \ + -device tpm-tis,tpmdev=tpm0 \ + -incoming "exec:cat < testvm.bin" \ + test.img + +Troubleshooting migration +------------------------- + +There are several reasons why migration may fail. In case of problems, +please ensure that the command lines adhere to the following rules +and, if possible, that identical versions of QEMU and swtpm are used +at all times. + +VM save and restore: + + - QEMU command line parameters should be identical apart from the + '-incoming' option on VM restore + + - swtpm command line parameters should be identical + +VM migration to 'localhost': + + - QEMU command line parameters should be identical apart from the + '-incoming' option on the destination side + + - swtpm command line parameters should point to two different + directories on the source and destination swtpm (--tpmstate dir=...) + (especially if different versions of libtpms were to be used on the + same machine). + +VM migration across the network: + + - QEMU command line parameters should be identical apart from the + '-incoming' option on the destination side + + - swtpm command line parameters should be identical + +VM Snapshotting: + - QEMU command line parameters should be identical + + - swtpm command line parameters should be identical + + +Besides that, migration failure reasons on the swtpm level may include +the following: + + - the versions of the swtpm on the source and destination sides are + incompatible + + - downgrading of TPM state may not be supported + + - the source and destination libtpms were compiled with different + compile-time options and the destination side refuses to accept the + state + + - different migration keys are used on the source and destination side + and the destination side cannot decrypt the migrated state + (swtpm ... --migration-key ... ) + + +.. _TIS specification: + https://trustedcomputinggroup.org/pc-client-work-group-pc-client-specific-tpm-interface-specification-tis/ + +.. _CRB specification: + https://trustedcomputinggroup.org/resource/pc-client-platform-tpm-profile-ptp-specification/ + + +.. _ACPI specification: + https://trustedcomputinggroup.org/tcg-acpi-specification/ + +.. _PPI specification: + https://trustedcomputinggroup.org/resource/tcg-physical-presence-interface-specification/ + +.. _SWTPM protocol: + https://github.com/stefanberger/swtpm/blob/master/man/man3/swtpm_ioctls.pod diff --git a/docs/specs/tpm.txt b/docs/specs/tpm.txt deleted file mode 100644 index 9c3e67d8a7..0000000000 --- a/docs/specs/tpm.txt +++ /dev/null @@ -1,445 +0,0 @@ -QEMU TPM Device -=============== - -= Guest-side Hardware Interface = - -The QEMU TPM emulation implements a TPM TIS hardware interface following the -Trusted Computing Group's specification "TCG PC Client Specific TPM Interface -Specification (TIS)", Specification Version 1.3, 21 March 2013. This -specification, or a later version of it, can be accessed from the following -URL: - -https://trustedcomputinggroup.org/pc-client-work-group-pc-client-specific-tpm-interface-specification-tis/ - -The TIS interface makes a memory mapped IO region in the area 0xfed40000 - -0xfed44fff available to the guest operating system. - - -QEMU files related to TPM TIS interface: - - hw/tpm/tpm_tis.c - - hw/tpm/tpm_tis.h - - -QEMU also implements a TPM CRB interface following the Trusted Computing -Group's specification "TCG PC Client Platform TPM Profile (PTP) -Specification", Family "2.0", Level 00 Revision 01.03 v22, May 22, 2017. -This specification, or a later version of it, can be accessed from the -following URL: - -https://trustedcomputinggroup.org/resource/pc-client-platform-tpm-profile-ptp-specification/ - -The CRB interface makes a memory mapped IO region in the area 0xfed40000 - -0xfed40fff (1 locality) available to the guest operating system. - -QEMU files related to TPM CRB interface: - - hw/tpm/tpm_crb.c - - -pSeries (ppc64) machines offer a tpm-spapr device model. - -QEMU files related to the SPAPR interface: - - hw/tpm/tpm_spapr.c - -= fw_cfg interface = - -The bios/firmware may read the "etc/tpm/config" fw_cfg entry for -configuring the guest appropriately. - -The entry of 6 bytes has the following content, in little-endian: - - #define TPM_VERSION_UNSPEC 0 - #define TPM_VERSION_1_2 1 - #define TPM_VERSION_2_0 2 - - #define TPM_PPI_VERSION_NONE 0 - #define TPM_PPI_VERSION_1_30 1 - - struct FwCfgTPMConfig { - uint32_t tpmppi_address; /* PPI memory location */ - uint8_t tpm_version; /* TPM version */ - uint8_t tpmppi_version; /* PPI version */ - }; - -= ACPI Interface = - -The TPM device is defined with ACPI ID "PNP0C31". QEMU builds a SSDT and passes -it into the guest through the fw_cfg device. The device description contains -the base address of the TIS interface 0xfed40000 and the size of the MMIO area -(0x5000). In case a TPM2 is used by QEMU, a TPM2 ACPI table is also provided. -The device is described to be used in polling mode rather than interrupt mode -primarily because no unused IRQ could be found. - -To support measurement logs to be written by the firmware, e.g. SeaBIOS, a TCPA -table is implemented. This table provides a 64kb buffer where the firmware can -write its log into. For TPM 2 only a more recent version of the TPM2 table -provides support for measurements logs and a TCPA table does not need to be -created. - -The TCPA and TPM2 ACPI tables follow the Trusted Computing Group specification -"TCG ACPI Specification" Family "1.2" and "2.0", Level 00 Revision 00.37. This -specification, or a later version of it, can be accessed from the following -URL: - -https://trustedcomputinggroup.org/tcg-acpi-specification/ - -== ACPI PPI Interface == - -QEMU supports the Physical Presence Interface (PPI) for TPM 1.2 and TPM 2. This -interface requires ACPI and firmware support. The specification can be found at -the following URL: - -https://trustedcomputinggroup.org/resource/tcg-physical-presence-interface-specification/ - -PPI enables a system administrator (root) to request a modification to the -TPM upon reboot. The PPI specification defines the operation requests and the -actions the firmware has to take. The system administrator passes the operation -request number to the firmware through an ACPI interface which writes this -number to a memory location that the firmware knows. Upon reboot, the firmware -finds the number and sends commands to the TPM. The firmware writes the TPM -result code and the operation request number to a memory location that ACPI can -read from and pass the result on to the administrator. - -The PPI specification defines a set of mandatory and optional operations for -the firmware to implement. The ACPI interface also allows an administrator to -list the supported operations. In QEMU the ACPI code is generated by QEMU, yet -the firmware needs to implement support on a per-operations basis, and -different firmwares may support a different subset. Therefore, QEMU introduces -the virtual memory device for PPI where the firmware can indicate which -operations it supports and ACPI can enable the ones that are supported and -disable all others. This interface lies in main memory and has the following -layout: - - +----------+--------+--------+-------------------------------------------+ - | Field | Length | Offset | Description | - +----------+--------+--------+-------------------------------------------+ - | func | 0x100 | 0x000 | Firmware sets values for each supported | - | | | | operation. See defined values below. | - +----------+--------+--------+-------------------------------------------+ - | ppin | 0x1 | 0x100 | SMI interrupt to use. Set by firmware. | - | | | | Not supported. | - +----------+--------+--------+-------------------------------------------+ - | ppip | 0x4 | 0x101 | ACPI function index to pass to SMM code. | - | | | | Set by ACPI. Not supported. | - +----------+--------+--------+-------------------------------------------+ - | pprp | 0x4 | 0x105 | Result of last executed operation. Set by | - | | | | firmware. See function index 5 for values.| - +----------+--------+--------+-------------------------------------------+ - | pprq | 0x4 | 0x109 | Operation request number to execute. See | - | | | | 'Physical Presence Interface Operation | - | | | | Summary' tables in specs. Set by ACPI. | - +----------+--------+--------+-------------------------------------------+ - | pprm | 0x4 | 0x10d | Operation request optional parameter. | - | | | | Values depend on operation. Set by ACPI. | - +----------+--------+--------+-------------------------------------------+ - | lppr | 0x4 | 0x111 | Last executed operation request number. | - | | | | Copied from pprq field by firmware. | - +----------+--------+--------+-------------------------------------------+ - | fret | 0x4 | 0x115 | Result code from SMM function. | - | | | | Not supported. | - +----------+--------+--------+-------------------------------------------+ - | res1 | 0x40 | 0x119 | Reserved for future use | - +----------+--------+--------+-------------------------------------------+ - | next_step| 0x1 | 0x159 | Operation to execute after reboot by | - | | | | firmware. Used by firmware. | - +----------+--------+--------+-------------------------------------------+ - | movv | 0x1 | 0x15a | Memory overwrite variable | - +----------+--------+--------+-------------------------------------------+ - - The following values are supported for the 'func' field. They correspond - to the values used by ACPI function index 8. - - +----------+-------------------------------------------------------------+ - | value | Description | - +----------+-------------------------------------------------------------+ - | 0 | Operation is not implemented. | - +----------+-------------------------------------------------------------+ - | 1 | Operation is only accessible through firmware. | - +----------+-------------------------------------------------------------+ - | 2 | Operation is blocked for OS by firmware configuration. | - +----------+-------------------------------------------------------------+ - | 3 | Operation is allowed and physically present user required. | - +----------+-------------------------------------------------------------+ - | 4 | Operation is allowed and physically present user is not | - | | required. | - +----------+-------------------------------------------------------------+ - -The location of the table is given by the fw_cfg tpmppi_address field. -The PPI memory region size is 0x400 (TPM_PPI_ADDR_SIZE) to leave -enough room for future updates. - - -QEMU files related to TPM ACPI tables: - - hw/i386/acpi-build.c - - include/hw/acpi/tpm.h - - -= TPM backend devices = - -The TPM implementation is split into two parts, frontend and backend. The -frontend part is the hardware interface, such as the TPM TIS interface -described earlier, and the other part is the TPM backend interface. The backend -interfaces implement the interaction with a TPM device, which may be a physical -or an emulated device. The split between the front- and backend devices allows -a frontend to be connected with any available backend. This enables the TIS -interface to be used with the passthrough backend or the (future) swtpm backend. - - -QEMU files related to TPM backends: - - backends/tpm.c - - include/sysemu/tpm_backend.h - - include/sysemu/tpm_backend_int.h - - -== The QEMU TPM passthrough device == - -In case QEMU is run on Linux as the host operating system it is possible to -make the hardware TPM device available to a single QEMU guest. In this case the -user must make sure that no other program is using the device, e.g., /dev/tpm0, -before trying to start QEMU with it. - -The passthrough driver uses the host's TPM device for sending TPM commands -and receiving responses from. Besides that it accesses the TPM device's sysfs -entry for support of command cancellation. Since none of the state of a -hardware TPM can be migrated between hosts, virtual machine migration is -disabled when the TPM passthrough driver is used. - -Since the host's TPM device will already be initialized by the host's firmware, -certain commands, e.g. TPM_Startup(), sent by the virtual firmware for device -initialization, will fail. In this case the firmware should not use the TPM. - -Sharing the device with the host is generally not a recommended usage scenario -for a TPM device. The primary reason for this is that two operating systems can -then access the device's single set of resources, such as platform configuration -registers (PCRs). Applications or kernel security subsystems, such as the -Linux Integrity Measurement Architecture (IMA), are not expecting to share PCRs. - - -QEMU files related to the TPM passthrough device: - - hw/tpm/tpm_passthrough.c - - hw/tpm/tpm_util.c - - hw/tpm/tpm_util.h - - -Command line to start QEMU with the TPM passthrough device using the host's -hardware TPM /dev/tpm0: - -qemu-system-x86_64 -display sdl -accel kvm \ - -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ - -tpmdev passthrough,id=tpm0,path=/dev/tpm0 \ - -device tpm-tis,tpmdev=tpm0 test.img - -The following commands should result in similar output inside the VM with a -Linux kernel that either has the TPM TIS driver built-in or available as a -module: - -#> dmesg | grep -i tpm -[ 0.711310] tpm_tis 00:06: 1.2 TPM (device=id 0x1, rev-id 1) - -#> dmesg | grep TCPA -[ 0.000000] ACPI: TCPA 0x0000000003FFD191C 000032 (v02 BOCHS \ - BXPCTCPA 0000001 BXPC 00000001) - -#> ls -l /dev/tpm* -crw-------. 1 root root 10, 224 Jul 11 10:11 /dev/tpm0 - -#> find /sys/devices/ | grep pcrs$ | xargs cat -PCR-00: 35 4E 3B CE 23 9F 38 59 ... -... -PCR-23: 00 00 00 00 00 00 00 00 ... - - -== The QEMU TPM emulator device == - -The TPM emulator device uses an external TPM emulator called 'swtpm' for -sending TPM commands to and receiving responses from. The swtpm program -must have been started before trying to access it through the TPM emulator -with QEMU. - -The TPM emulator implements a command channel for transferring TPM commands -and responses as well as a control channel over which control commands can -be sent. The specification for the control channel can be found here: - -https://github.com/stefanberger/swtpm/blob/master/man/man3/swtpm_ioctls.pod - - -The control channel serves the purpose of resetting, initializing, and -migrating the TPM state, among other things. - -The swtpm program behaves like a hardware TPM and therefore needs to be -initialized by the firmware running inside the QEMU virtual machine. -One necessary step for initializing the device is to send the TPM_Startup -command to it. SeaBIOS, for example, has been instrumented to initialize -a TPM 1.2 or TPM 2 device using this command. - - -QEMU files related to the TPM emulator device: - - hw/tpm/tpm_emulator.c - - hw/tpm/tpm_util.c - - hw/tpm/tpm_util.h - - -The following commands start the swtpm with a UnixIO control channel over -a socket interface. They do not need to be run as root. - -mkdir /tmp/mytpm1 -swtpm socket --tpmstate dir=/tmp/mytpm1 \ - --ctrl type=unixio,path=/tmp/mytpm1/swtpm-sock \ - --log level=20 - -Command line to start QEMU with the TPM emulator device communicating with -the swtpm (x86): - -qemu-system-x86_64 -display sdl -accel kvm \ - -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ - -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ - -tpmdev emulator,id=tpm0,chardev=chrtpm \ - -device tpm-tis,tpmdev=tpm0 test.img - -In case a pSeries machine is emulated, use the following command line: - -qemu-system-ppc64 -display sdl -machine pseries,accel=kvm \ - -m 1024 -bios slof.bin -boot menu=on \ - -nodefaults -device VGA -device pci-ohci -device usb-kbd \ - -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ - -tpmdev emulator,id=tpm0,chardev=chrtpm \ - -device tpm-spapr,tpmdev=tpm0 \ - -device spapr-vscsi,id=scsi0,reg=0x00002000 \ - -device virtio-blk-pci,scsi=off,bus=pci.0,addr=0x3,drive=drive-virtio-disk0,id=virtio-disk0 \ - -drive file=test.img,format=raw,if=none,id=drive-virtio-disk0 - - -In case SeaBIOS is used as firmware, it should show the TPM menu item -after entering the menu with 'ESC'. - -Select boot device: -1. DVD/CD [ata1-0: QEMU DVD-ROM ATAPI-4 DVD/CD] -[...] -5. Legacy option rom - -t. TPM Configuration - - -The following commands should result in similar output inside the VM with a -Linux kernel that either has the TPM TIS driver built-in or available as a -module: - -#> dmesg | grep -i tpm -[ 0.711310] tpm_tis 00:06: 1.2 TPM (device=id 0x1, rev-id 1) - -#> dmesg | grep TCPA -[ 0.000000] ACPI: TCPA 0x0000000003FFD191C 000032 (v02 BOCHS \ - BXPCTCPA 0000001 BXPC 00000001) - -#> ls -l /dev/tpm* -crw-------. 1 root root 10, 224 Jul 11 10:11 /dev/tpm0 - -#> find /sys/devices/ | grep pcrs$ | xargs cat -PCR-00: 35 4E 3B CE 23 9F 38 59 ... -... -PCR-23: 00 00 00 00 00 00 00 00 ... - - -=== Migration with the TPM emulator === - -The TPM emulator supports the following types of virtual machine migration: - -- VM save / restore (migration into a file) -- Network migration -- Snapshotting (migration into storage like QoW2 or QED) - -The following command sequences can be used to test VM save / restore. - - -In a 1st terminal start an instance of a swtpm using the following command: - -mkdir /tmp/mytpm1 -swtpm socket --tpmstate dir=/tmp/mytpm1 \ - --ctrl type=unixio,path=/tmp/mytpm1/swtpm-sock \ - --log level=20 --tpm2 - -In a 2nd terminal start the VM: - -qemu-system-x86_64 -display sdl -accel kvm \ - -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ - -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ - -tpmdev emulator,id=tpm0,chardev=chrtpm \ - -device tpm-tis,tpmdev=tpm0 \ - -monitor stdio \ - test.img - -Verify that the attached TPM is working as expected using applications inside -the VM. - -To store the state of the VM use the following command in the QEMU monitor in -the 2nd terminal: - -(qemu) migrate "exec:cat > testvm.bin" -(qemu) quit - -At this point a file called 'testvm.bin' should exists and the swtpm and QEMU -processes should have ended. - -To test 'VM restore' you have to start the swtpm with the same parameters -as before. If previously a TPM 2 [--tpm2] was saved, --tpm2 must now be -passed again on the command line. - -In the 1st terminal restart the swtpm with the same command line as before: - -swtpm socket --tpmstate dir=/tmp/mytpm1 \ - --ctrl type=unixio,path=/tmp/mytpm1/swtpm-sock \ - --log level=20 --tpm2 - -In the 2nd terminal restore the state of the VM using the additional -'-incoming' option. - -qemu-system-x86_64 -display sdl -accel kvm \ - -m 1024 -boot d -bios bios-256k.bin -boot menu=on \ - -chardev socket,id=chrtpm,path=/tmp/mytpm1/swtpm-sock \ - -tpmdev emulator,id=tpm0,chardev=chrtpm \ - -device tpm-tis,tpmdev=tpm0 \ - -incoming "exec:cat < testvm.bin" \ - test.img - - -Troubleshooting migration: - -There are several reasons why migration may fail. In case of problems, -please ensure that the command lines adhere to the following rules and, -if possible, that identical versions of QEMU and swtpm are used at all -times. - -VM save and restore: - - QEMU command line parameters should be identical apart from the - '-incoming' option on VM restore - - swtpm command line parameters should be identical - -VM migration to 'localhost': - - QEMU command line parameters should be identical apart from the - '-incoming' option on the destination side - - swtpm command line parameters should point to two different - directories on the source and destination swtpm (--tpmstate dir=...) - (especially if different versions of libtpms were to be used on the - same machine). - -VM migration across the network: - - QEMU command line parameters should be identical apart from the - '-incoming' option on the destination side - - swtpm command line parameters should be identical - -VM Snapshotting: - - QEMU command line parameters should be identical - - swtpm command line parameters should be identical - - -Besides that, migration failure reasons on the swtpm level may include -the following: - - - the versions of the swtpm on the source and destination sides are - incompatible - - downgrading of TPM state may not be supported - - the source and destination libtpms were compiled with different - compile-time options and the destination side refuses to accept the - state - - different migration keys are used on the source and destination side - and the destination side cannot decrypt the migrated state - (swtpm ... --migration-key ... )