From 750d890cacdd13f9850754ccdbf12d0fb6f4ea07 Mon Sep 17 00:00:00 2001 From: Paolo Bonzini Date: Nov 14 2017 17:16:25 +0000 Subject: add missing files --- diff --git a/openssl-patch-to-tarball.sh b/openssl-patch-to-tarball.sh new file mode 100644 index 0000000..f13382a --- /dev/null +++ b/openssl-patch-to-tarball.sh @@ -0,0 +1,62 @@ +#! /bin/sh + +: << \EOF + For importing the hobbled OpenSSL tarball from Fedora, the following + steps are necessary. Note that both the "sources" file format and the + pkgs.fedoraproject.org directory structure have changed, accommodating + SHA512 checksums. + + # in a separate directory + fedpkg clone -a openssl + cd openssl + fedpkg switch-branch master + gitk -- sources + + # the commit that added the 1.1.0e hobbled tarball is c676ac32d544, + # subject "update to upstream version 1.1.0e" + git checkout c676ac32d544 + + # fetch the hobbled tarball and verify the checksum + ( + set -e + while read HASH_TYPE FN EQ HASH; do + # remove leading and trailing parens + FN="${FN#(*}" + FN="${FN%*)}" + wget \ + http://pkgs.fedoraproject.org/repo/pkgs/openssl/$FN/sha512/$HASH/$FN + done openssl-${openssl_version}-hobbled.tar.xz + cd tianocore-openssl-${openssl_version} + git init . + git config core.whitespace cr-at-eol + git config am.keepcr true + git am + git archive --format=tar --prefix=tianocore-edk2-${edk2_githash}/ \ + HEAD CryptoPkg/Library/OpensslLib/ | \ + xz -9ev >&3) < $1 +rm -rf tianocore-openssl-${openssl_version} diff --git a/ovmf-whitepaper-c770f8c.txt b/ovmf-whitepaper-c770f8c.txt new file mode 100644 index 0000000..ba727b4 --- /dev/null +++ b/ovmf-whitepaper-c770f8c.txt @@ -0,0 +1,2422 @@ +Open Virtual Machine Firmware (OVMF) Status Report +July 2014 (with updates in August 2014 - January 2015) + +Author: Laszlo Ersek +Copyright (C) 2014-2015, Red Hat, Inc. +CC BY-SA 4.0 + +Abstract +-------- + +The Unified Extensible Firmware Interface (UEFI) is a specification that +defines a software interface between an operating system and platform firmware. +UEFI is designed to replace the Basic Input/Output System (BIOS) firmware +interface. + +Hardware platform vendors have been increasingly adopting the UEFI +Specification to govern their boot firmware developments. OVMF (Open Virtual +Machine Firmware), a sub-project of Intel's EFI Development Kit II (edk2), +enables UEFI support for Ia32 and X64 Virtual Machines. + +This paper reports on the status of the OVMF project, treats features and +limitations, gives end-user hints, and examines some areas in-depth. + +Keywords: ACPI, boot options, CSM, edk2, firmware, flash, fw_cfg, KVM, memory +map, non-volatile variables, OVMF, PCD, QEMU, reset vector, S3, Secure Boot, +Smbios, SMM, TianoCore, UEFI, VBE shim, Virtio + +Table of Contents +----------------- + +- Motivation +- Scope +- Example qemu invocation +- Installation of OVMF guests with virt-manager and virt-install +- Supported guest operating systems +- Compatibility Support Module (CSM) +- Phases of the boot process +- Project structure +- Platform Configuration Database (PCD) +- Firmware image structure +- S3 (suspend to RAM and resume) +- A comprehensive memory map of OVMF +- Known Secure Boot limitations +- Variable store and LockBox in SMRAM +- Select features + - X64-specific reset vector for OVMF + - Client library for QEMU's firmware configuration interface + - Guest ACPI tables + - Guest SMBIOS tables + - Platform-specific boot policy + - Virtio drivers + - Platform Driver + - Video driver +- Afterword + +Motivation +---------- + +OVMF extends the usual benefits of virtualization to UEFI. Reasons to use OVMF +include: + +- Legacy-free guests. A UEFI-based environment eliminates dependencies on + legacy address spaces and devices. This is especially beneficial when used + with physically assigned devices where the legacy operating mode is + troublesome to support, ex. assigned graphics cards operating in legacy-free, + non-VGA mode in the guest. + +- Future proof guests. The x86 market is steadily moving towards a legacy-free + platform and guest operating systems may eventually require a UEFI + environment. OVMF provides that next generation firmware support for such + applications. + +- GUID partition tables (GPTs). MBR partition tables represent partition + offsets and sizes with 32-bit integers, in units of 512 byte sectors. This + limits the addressable portion of the disk to 2 TB. GPT represents logical + block addresses with 64 bits. + +- Liberating boot loader binaries from residing in contested and poorly defined + space between the partition table and the partitions. + +- Support for booting off disks (eg. pass-through physical SCSI devices) with a + 4kB physical and logical sector size, i.e. which don't have 512-byte block + emulation. + +- Development and testing of Secure Boot-related features in guest operating + systems. Although OVMF's Secure Boot implementation is currently not secure + against malicious UEFI drivers, UEFI applications, and guest kernels, + trusted guest code that only uses standard UEFI interfaces will find a valid + Secure Boot environment under OVMF, with working key enrollment and signature + validation. This enables development and testing of portable, Secure + Boot-related guest code. + +- Presence of non-volatile UEFI variables. This furthers development and + testing of OS installers, UEFI boot loaders, and unique, dependent guest OS + features. For example, an efivars-backed pstore (persistent storage) + file system works under Linux. + +- Altogether, a near production-level UEFI environment for virtual machines + when Secure Boot is not required. + +Scope +----- + +UEFI and especially Secure Boot have been topics fraught with controversy and +political activism. This paper sidesteps these aspects and strives to focus on +use cases, hands-on information for end users, and technical details. + +Unless stated otherwise, the expression "X supports Y" means "X is technically +compatible with interfaces provided or required by Y". It does not imply +support as an activity performed by natural persons or companies. + +We discuss the status of OVMF at a state no earlier than edk2 SVN revision +16158. The paper concentrates on upstream projects and communities, but +occasionally it pans out about OVMF as it is planned to be shipped (as +Technical Preview) in Red Hat Enterprise Linux 7.1. Such digressions are marked +with the [RHEL] margin notation. + +Although other VMMs and accelerators are known to support (or plan to support) +OVMF to various degrees -- for example, VirtualBox, Xen, BHyVe --, we'll +emphasize OVMF on qemu/KVM, because QEMU and KVM have always been Red Hat's +focus wrt. OVMF. + +The recommended upstream QEMU version is 2.1+. The recommended host Linux +kernel (KVM) version is 3.10+. The recommended QEMU machine type is +"qemu-system-x86_64 -M pc-i440fx-2.1" or later. + +The term "TianoCore" is used interchangeably with "edk2" in this paper. + +Example qemu invocation +----------------------- + +The following commands give a quick foretaste of installing a UEFI operating +system on OVMF, relying only on upstream edk2 and qemu. + +- Clone and build OVMF: + + git clone https://github.com/tianocore/edk2.git + cd edk2 + nice OvmfPkg/build.sh -a X64 -n $(getconf _NPROCESSORS_ONLN) + + (Note that this ad-hoc build will not include the Secure Boot feature.) + +- The build output file, "OVMF.fd", includes not only the executable firmware + code, but the non-volatile variable store as well. For this reason, make a + VM-specific copy of the build output (the variable store should be private to + the virtual machine): + + cp Build/OvmfX64/DEBUG_GCC4?/FV/OVMF.fd fedora.flash + + (The variable store and the firmware executable are also available in the + build output as separate files: "OVMF_VARS.fd" and "OVMF_CODE.fd". This + enables central management and updates of the firmware executable, while each + virtual machine can retain its own variable store.) + +- Download a Fedora LiveCD: + + wget https://dl.fedoraproject.org/pub/fedora/linux/releases/20/Live/x86_64/Fedora-Live-Xfce-x86_64-20-1.iso + +- Create a virtual disk (qcow2 format, 20 GB in size): + + qemu-img create -f qcow2 fedora.img 20G + +- Create the following qemu wrapper script under the name "fedora.sh": + + # Basic virtual machine properties: a recent i440fx machine type, KVM + # acceleration, 2048 MB RAM, two VCPUs. + OPTS="-M pc-i440fx-2.1 -enable-kvm -m 2048 -smp 2" + + # The OVMF binary, including the non-volatile variable store, appears as a + # "normal" qemu drive on the host side, and it is exposed to the guest as a + # persistent flash device. + OPTS="$OPTS -drive if=pflash,format=raw,file=fedora.flash" + + # The hard disk is exposed to the guest as a virtio-block device. OVMF has a + # driver stack that supports such a disk. We specify this disk as first boot + # option. OVMF recognizes the boot order specification. + OPTS="$OPTS -drive id=disk0,if=none,format=qcow2,file=fedora.img" + OPTS="$OPTS -device virtio-blk-pci,drive=disk0,bootindex=0" + + # The Fedora installer disk appears as an IDE CD-ROM in the guest. This is + # the 2nd boot option. + OPTS="$OPTS -drive id=cd0,if=none,format=raw,readonly" + OPTS="$OPTS,file=Fedora-Live-Xfce-x86_64-20-1.iso" + OPTS="$OPTS -device ide-cd,bus=ide.1,drive=cd0,bootindex=1" + + # The following setting enables S3 (suspend to RAM). OVMF supports S3 + # suspend/resume. + OPTS="$OPTS -global PIIX4_PM.disable_s3=0" + + # OVMF emits a number of info / debug messages to the QEMU debug console, at + # ioport 0x402. We configure qemu so that the debug console is indeed + # available at that ioport. We redirect the host side of the debug console to + # a file. + OPTS="$OPTS -global isa-debugcon.iobase=0x402 -debugcon file:fedora.ovmf.log" + + # QEMU accepts various commands and queries from the user on the monitor + # interface. Connect the monitor with the qemu process's standard input and + # output. + OPTS="$OPTS -monitor stdio" + + # A USB tablet device in the guest allows for accurate pointer tracking + # between the host and the guest. + OPTS="$OPTS -device piix3-usb-uhci -device usb-tablet" + + # Provide the guest with a virtual network card (virtio-net). + # + # Normally, qemu provides the guest with a UEFI-conformant network driver + # from the iPXE project, in the form of a PCI expansion ROM. For this test, + # we disable the expansion ROM and allow OVMF's built-in virtio-net driver to + # take effect. + # + # On the host side, we use the SLIRP ("user") network backend, which has + # relatively low performance, but it doesn't require extra privileges from + # the user executing qemu. + OPTS="$OPTS -netdev id=net0,type=user" + OPTS="$OPTS -device virtio-net-pci,netdev=net0,romfile=" + + # A Spice QXL GPU is recommended as the primary VGA-compatible display + # device. It is a full-featured virtual video card, with great operating + # system driver support. OVMF supports it too. + OPTS="$OPTS -device qxl-vga" + + qemu-system-x86_64 $OPTS + +- Start the Fedora guest: + + sh fedora.sh + +- The above command can be used for both installation and later boots of the + Fedora guest. + +- In order to verify basic OVMF network connectivity: + + - Assuming that the non-privileged user running qemu belongs to group G + (where G is a numeric identifier), ensure as root on the host that the + group range in file "/proc/sys/net/ipv4/ping_group_range" includes G. + + - As the non-privileged user, boot the guest as usual. + + - On the TianoCore splash screen, press ESC. + + - Navigate to Boot Manager | EFI Internal Shell + + - In the UEFI Shell, issue the following commands: + + ifconfig -s eth0 dhcp + ping A.B.C.D + + where A.B.C.D is a public IPv4 address in dotted decimal notation that your + host can reach. + + - Type "quit" at the (qemu) monitor prompt. + +Installation of OVMF guests with virt-manager and virt-install +-------------------------------------------------------------- + +(1) Assuming OVMF has been installed on the host with the following files: + - /usr/share/OVMF/OVMF_CODE.fd + - /usr/share/OVMF/OVMF_VARS.fd + + locate the "nvram" stanza in "/etc/libvirt/qemu.conf", and edit it as + follows: + + nvram = [ "/usr/share/OVMF/OVMF_CODE.fd:/usr/share/OVMF/OVMF_VARS.fd" ] + +(2) Restart libvirtd with your Linux distribution's service management tool; + for example, + + systemctl restart libvirtd + +(3) In virt-manager, proceed with the guest installation as usual: + - select File | New Virtual Machine, + - advance to Step 5 of 5, + - in Step 5, check "Customize configuration before install", + - click Finish; + - in the customization dialog, select Overview | Firmware, and choose UEFI, + - click Apply and Begin Installation. + +(4) With virt-install: + + LDR="loader=/usr/share/OVMF/OVMF_CODE.fd,loader_ro=yes,loader_type=pflash" + virt-install \ + --name fedora20 \ + --memory 2048 \ + --vcpus 2 \ + --os-variant fedora20 \ + --boot hd,cdrom,$LDR \ + --disk size=20 \ + --disk path=Fedora-Live-Xfce-x86_64-20-1.iso,device=cdrom,bus=scsi + +(5) A popular, distribution-independent, bleeding-edge OVMF package is + available under , courtesy of Gerd Hoffmann. + + The "edk2.git-ovmf-x64" package provides the following files, among others: + - /usr/share/edk2.git/ovmf-x64/OVMF_CODE-pure-efi.fd + - /usr/share/edk2.git/ovmf-x64/OVMF_VARS-pure-efi.fd + + When using this package, adapt steps (1) and (4) accordingly. + +(6) Additionally, the "edk2.git-ovmf-x64" package seeks to simplify the + enablement of Secure Boot in a virtual machine (strictly for development + and testing purposes). + + - Boot the virtual machine off the CD-ROM image called + "/usr/share/edk2.git/ovmf-x64/UefiShell.iso"; before or after installing + the main guest operating system. + + - When the UEFI shell appears, issue the following commands: + + EnrollDefaultKeys.efi + reset -s + + - The EnrollDefaultKeys.efi utility enrolls the following keys: + + - A static example X.509 certificate (CN=TestCommonName) as Platform Key + and first Key Exchange Key. + + The private key matching this certificate has been destroyed (but you + shouldn't trust this statement). + + - "Microsoft Corporation KEK CA 2011" as second Key Exchange Key + (SHA1: 31:59:0b:fd:89:c9:d7:4e:d0:87:df:ac:66:33:4b:39:31:25:4b:30). + + - "Microsoft Windows Production PCA 2011" as first DB entry + (SHA1: 58:0a:6f:4c:c4:e4:b6:69:b9:eb:dc:1b:2b:3e:08:7b:80:d0:67:8d). + + - "Microsoft Corporation UEFI CA 2011" as second DB entry + (SHA1: 46:de:f6:3b:5c:e6:1c:f8:ba:0d:e2:e6:63:9c:10:19:d0:ed:14:f3). + + These keys suffice to boot released versions of popular Linux + distributions (through the shim.efi utility), and Windows 8 and Windows + Server 2012 R2, in Secure Boot mode. + +Supported guest operating systems +--------------------------------- + +Upstream OVMF does not favor some guest operating systems over others for +political or ideological reasons. However, some operating systems are harder to +obtain and/or technically more difficult to support. The general expectation is +that recent UEFI OSes should just work. Please consult the "OvmfPkg/README" +file. + +The following guest OSes were tested with OVMF: +- Red Hat Enterprise Linux 6 +- Red Hat Enterprise Linux 7 +- Fedora 18 +- Fedora 19 +- Fedora 20 +- Windows Server 2008 R2 SP1 +- Windows Server 2012 +- Windows 8 + +Notes about Windows Server 2008 R2 (paraphrasing the "OvmfPkg/README" file): + +- QEMU should be started with one of the "-device qxl-vga" and "-device VGA" + options. + +- Only one video mode, 1024x768x32, is supported at OS runtime. + + Please refer to the section about QemuVideoDxe (OVMF's built-in video driver) + for more details on this limitation. + +- The qxl-vga video card is recommended ("-device qxl-vga"). After booting the + installed guest OS, select the video card in Device Manager, and upgrade the + video driver to the QXL XDDM one. + + The QXL XDDM driver can be downloaded from + , under Guest | Windows binaries. + + This driver enables additional graphics resolutions at OS runtime, and + provides S3 (suspend/resume) capability. + +Notes about Windows Server 2012 and Windows 8: + +- QEMU should be started with the "-device qxl-vga,revision=4" option (or a + later revision, if available). + +- The guest OS's builtin video driver inherits the video mode / frame buffer + from OVMF. There's no way to change the resolution at OS runtime. + + For this reason, a platform driver has been developed for OVMF, which allows + users to change the preferred video mode in the firmware. Please refer to the + section about PlatformDxe for details. + +- It is recommended to upgrade the guest OS's video driver to the QXL WDDM one, + via Device Manager. + + Binaries for the QXL WDDM driver can be found at + (pick a version greater than or + equal to 0.6), while the source code resides at + . + + This driver enables additional graphics resolutions at OS runtime, and + provides S3 (suspend/resume) capability. + +Compatibility Support Module (CSM) +---------------------------------- + +Collaboration between SeaBIOS and OVMF developers has enabled SeaBIOS to be +built as a Compatibility Support Module, and OVMF to embed and use it. + +Benefits of a SeaBIOS CSM include: + +- The ability to boot legacy (non-UEFI) operating systems, such as legacy Linux + systems, Windows 7, OpenBSD 5.2, FreeBSD 8/9, NetBSD, DragonflyBSD, Solaris + 10/11. + +- Legacy (non-UEFI-compliant) PCI expansion ROMs, such as a VGA BIOS, mapped by + QEMU in emulated devices' ROM BARs, are loaded and executed by OVMF. + + For example, this grants the Windows Server 2008 R2 SP1 guest's native, + legacy video driver access to all modes of all QEMU video cards. + +Building the CSM target of the SeaBIOS source tree is out of scope for this +report. Additionally, upstream OVMF does not enable the CSM by default. + +Interested users and developers should look for OVMF's "-D CSM_ENABLE" +build-time option, and check out the continuous +integration repository, which provides CSM-enabled OVMF builds. + +[RHEL] The "OVMF_CODE.fd" firmware image made available on the Red Hat + Enterprise Linux 7.1 host does not include a Compatibility Support + Module, for the following reasons: + + - Virtual machines running officially supported, legacy guest operating + systems should just use the standalone SeaBIOS firmware. Firmware + selection is flexible in virtualization, see eg. "Installation of OVMF + guests with virt-manager and virt-install" above. + + - The 16-bit thunking interface between OVMF and SeaBIOS is very complex + and presents a large debugging and support burden, based on past + experience. + + - Secure Boot is incompatible with CSM. + + - Inter-project dependencies should be minimized whenever possible. + + - Using the default QXL video card, the Windows 2008 R2 SP1 guest can be + installed with its built-in, legacy video driver. Said driver will + select the only available video mode, 1024x768x32. After installation, + the video driver can be upgraded to the full-featured QXL XDDM driver. + +Phases of the boot process +-------------------------- + +The PI and UEFI specifications, and Intel's UEFI and EDK II Learning and +Development materials provide ample information on PI and UEFI concepts. The +following is an absolutely minimal, rough glossary that is included only to +help readers new to PI and UEFI understand references in later, OVMF-specific +sections. We defer heavily to the official specifications and the training +materials, and frequently quote them below. + +A central concept to mention early is the GUID -- globally unique identifier. A +GUID is a 128-bit number, written as XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX, +where each X stands for a hexadecimal nibble. GUIDs are used to name everything +in PI and in UEFI. Programmers introduce new GUIDs with the "uuidgen" utility, +and standards bodies standardize well-known services by positing their GUIDs. + +The boot process is roughly divided in the following phases: + +- Reset vector code. + +- SEC: Security phase. This phase is the root of firmware integrity. + +- PEI: Pre-EFI Initialization. This phase performs "minimal processor, chipset + and platform configuration for the purpose of discovering memory". Modules in + PEI collectively save their findings about the platform in a list of HOBs + (hand-off blocks). + + When developing PEI code, the Platform Initialization (PI) specification + should be consulted. + +- DXE: Driver eXecution Environment, pronounced as "Dixie". This "is the phase + where the bulk of the booting occurs: devices are enumerated and initialized, + UEFI services are supported, and protocols and drivers are implemented. Also, + the tables that create the UEFI interface are produced". + + On the PEI/DXE boundary, the HOBs produced by PEI are consumed. For example, + this is how the memory space map is configured initially. + +- BDS: Boot Device Selection. It is "responsible for determining how and where + you want to boot the operating system". + + When developing DXE and BDS code, it is mainly the UEFI specification that + should be consulted. When speaking about DXE, BDS is frequently considered to + be a part of it. + +The following concepts are tied to specific boot process phases: + +- PEIM: a PEI Module (pronounced "PIM"). A binary module running in the PEI + phase, consuming some PPIs and producing other PPIs, and producing HOBs. + +- PPI: PEIM-to-PEIM interface. A structure of function pointers and related + data members that establishes a PEI service, or an instance of a PEI service. + PPIs are identified by GUID. + + An example is EFI_PEI_S3_RESUME2_PPI (6D582DBC-DB85-4514-8FCC-5ADF6227B147). + +- DXE driver: a binary module running in the DXE and BDS phases, consuming some + protocols and producing other protocols. + +- Protocol: A structure of function pointers and related data members that + establishes a DXE service, or an instance of a DXE service. Protocols are + identified by GUID. + + An example is EFI_BLOCK_IO_PROTOCOL (964E5B21-6459-11D2-8E39-00A0C969723B). + +- Architectural protocols: a set of standard protocols that are foundational to + the working of a UEFI system. Each architectural protocol has at most one + instance. Architectural protocols are implemented by a subset of DXE drivers. + DXE drivers explicitly list the set of protocols (including architectural + protocols) that they need to work. UEFI drivers can only be loaded once all + architectural protocols have become available during the DXE phase. + + An example is EFI_VARIABLE_WRITE_ARCH_PROTOCOL + (6441F818-6362-4E44-B570-7DBA31DD2453). + +Project structure +----------------- + +The term "OVMF" usually denotes the project (community and development effort) +that provide and maintain the subject matter UEFI firmware for virtual +machines. However the term is also frequently applied to the firmware binary +proper that a virtual machine executes. + +OVMF emerges as a compilation of several modules from the edk2 source +repository. "edk2" stands for EFI Development Kit II; it is a "modern, +feature-rich, cross-platform firmware development environment for the UEFI and +PI specifications". + +The composition of OVMF is dictated by the following build control files: + + OvmfPkg/OvmfPkgIa32.dsc + OvmfPkg/OvmfPkgIa32.fdf + + OvmfPkg/OvmfPkgIa32X64.dsc + OvmfPkg/OvmfPkgIa32X64.fdf + + OvmfPkg/OvmfPkgX64.dsc + OvmfPkg/OvmfPkgX64.fdf + +The format of these files is described in the edk2 DSC and FDF specifications. +Roughly, the DSC file determines: +- library instance resolutions for library class requirements presented by the + modules to be compiled, +- the set of modules to compile. + +The FDF file roughly determines: +- what binary modules (compilation output files, precompiled binaries, graphics + image files, verbatim binary sections) to include in the firmware image, +- how to lay out the firmware image. + +The Ia32 flavor of these files builds a firmware where both PEI and DXE phases +are 32-bit. The Ia32X64 flavor builds a firmware where the PEI phase consists +of 32-bit modules, and the DXE phase is 64-bit. The X64 flavor builds a purely +64-bit firmware. + +The word size of the DXE phase must match the word size of the runtime OS -- a +32-bit DXE can't cooperate with a 64-bit OS, and a 64-bit DXE can't work a +32-bit OS. + +OVMF pulls together modules from across the edk2 tree. For example: + +- common drivers and libraries that are platform independent are usually + located under MdeModulePkg and MdePkg, + +- common but hardware-specific drivers and libraries that match QEMU's + pc-i440fx-* machine type are pulled in from IntelFrameworkModulePkg, + PcAtChipsetPkg and UefiCpuPkg, + +- the platform independent UEFI Shell is built from ShellPkg, + +- OvmfPkg includes drivers and libraries that are useful for virtual machines + and may or may not be specific to QEMU's pc-i440fx-* machine type. + +Platform Configuration Database (PCD) +------------------------------------- + +Like the "Phases of the boot process" section, this one introduces a concept in +very raw form. We defer to the PCD related edk2 specifications, and we won't +discuss implementation details here. Our purpose is only to offer the reader a +usable (albeit possibly inaccurate) definition, so that we can refer to PCDs +later on. + +Colloquially, when we say "PCD", we actually mean "PCD entry"; that is, an +entry stored in the Platform Configuration Database. + +The Platform Configuration Database is +- a firmware-wide +- name-value store +- of scalars and buffers +- where each entry may be + - build-time constant, or + - run-time dynamic, or + - theoretically, a middle option: patchable in the firmware file itself, + using a dedicated tool. (OVMF does not utilize externally patchable + entries.) + +A PCD entry is declared in the DEC file of the edk2 top-level Package directory +whose modules (drivers and libraries) are the primary consumers of the PCD +entry. (See for example OvmfPkg/OvmfPkg.dec). Basically, a PCD in a DEC file +exposes a simple customization point. + +Interest in a PCD entry is communicated to the build system by naming the PCD +entry in the INF file of the interested module (application, driver or +library). The module may read and -- dependent on the PCD entry's category -- +write the PCD entry. + +Let's investigate the characteristics of the Database and the PCD entries. + +- Firmware-wide: technically, all modules may access all entries they are + interested in, assuming they advertise their interest in their INF files. + With careful design, PCDs enable inter-driver propagation of (simple) system + configuration. PCDs are available in both PEI and DXE. + + (UEFI drivers meant to be portable (ie. from third party vendors) are not + supposed to use PCDs, since PCDs qualify internal to the specific edk2 + firmware in question.) + +- Name-value store of scalars and buffers: each PCD has a symbolic name, and a + fixed scalar type (UINT16, UINT32 etc), or VOID* for buffers. Each PCD entry + belongs to a namespace, where a namespace is (obviously) a GUID, defined in + the DEC file. + +- A DEC file can permit several categories for a PCD: + - build-time constant ("FixedAtBuild"), + - patchable in the firmware image ("PatchableInModule", unused in OVMF), + - runtime modifiable ("Dynamic"). + +The platform description file (DSC) of a top-level Package directory may choose +the exact category for a given PCD entry that its modules wish to use, and +assign a default (or constant) initial value to it. + +In addition, the edk2 build system too can initialize PCD entries to values +that it calculates while laying out the flash device image. Such PCD +assignments are described in the FDF control file. + +Firmware image structure +------------------------ + +(We assume the common X64 choice for both PEI and DXE, and the default DEBUG +build target.) + +The OvmfPkg/OvmfPkgX64.fdf file defines the following layout for the flash +device image "OVMF.fd": + + Description Compression type Size + ------------------------------ ---------------------- ------- + Non-volatile data storage open-coded binary data 128 KB + Variable store 56 KB + Event log 4 KB + Working block 4 KB + Spare area 64 KB + + FVMAIN_COMPACT uncompressed 1712 KB + FV Firmware File System file LZMA compressed + PEIFV uncompressed 896 KB + individual PEI modules uncompressed + DXEFV uncompressed 8192 KB + individual DXE modules uncompressed + + SECFV uncompressed 208 KB + SEC driver + reset vector code + +The top-level image consists of three regions (three firmware volumes): +- non-volatile data store (128 KB), +- main firmware volume (FVMAIN_COMPACT, 1712 KB), +- firmware volume containing the reset vector code and the SEC phase code (208 + KB). + +In total, the OVMF.fd file has size 128 KB + 1712 KB + 208 KB == 2 MB. + +(1) The firmware volume with non-volatile data store (128 KB) has the following + internal structure, in blocks of 4 KB: + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ L: event log + LIVE | varstore |L|W| W: working block + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + SPARE | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + The first half of this firmware volume is "live", while the second half is + "spare". The spare half is important when the variable driver reclaims + unused storage and reorganizes the variable store. + + The live half dedicates 14 blocks (56 KB) to the variable store itself. On + top of those, one block is set aside for an event log, and one block is + used as the working block of the fault tolerant write protocol. Fault + tolerant writes are used to recover from an occasional (virtual) power loss + during variable updates. + + The blocks in this firmware volume are accessed, in stacking order from + least abstract to most abstract, by: + + - EFI_FIRMWARE_VOLUME_BLOCK_PROTOCOL (provided by + OvmfPkg/QemuFlashFvbServicesRuntimeDxe), + + - EFI_FAULT_TOLERANT_WRITE_PROTOCOL (provided by + MdeModulePkg/Universal/FaultTolerantWriteDxe), + + - architectural protocols instrumental to the runtime UEFI variable + services: + - EFI_VARIABLE_ARCH_PROTOCOL, + - EFI_VARIABLE_WRITE_ARCH_PROTOCOL. + + In a non-secure boot build, the DXE driver providing these architectural + protocols is MdeModulePkg/Universal/Variable/RuntimeDxe. In a secure boot + build, where authenticated variables are available, the DXE driver + offering these protocols is SecurityPkg/VariableAuthenticated/RuntimeDxe. + +(2) The main firmware volume (FVMAIN_COMPACT, 1712 KB) embeds further firmware + volumes. The outermost layer is a Firmware File System (FFS), carrying a + single file. This file holds an LZMA-compressed section, which embeds two + firmware volumes: PEIFV (896 KB) with PEIMs, and DXEFV (8192 KB) with DXE + and UEFI drivers. + + This scheme enables us to build 896 KB worth of PEI drivers and 8192 KB + worth of DXE and UEFI drivers, compress them all with LZMA in one go, and + store the compressed result in 1712 KB, saving room in the flash device. + +(3) The SECFV firmware volume (208 KB) is not compressed. It carries the + "volume top file" with the reset vector code, to end at 4 GB in + guest-physical address space, and the SEC phase driver (OvmfPkg/Sec). + + The last 16 bytes of the volume top file (mapped directly under 4 GB) + contain a NOP slide and a jump instruction. This is where QEMU starts + executing the firmware, at address 0xFFFF_FFF0. The reset vector and the + SEC driver run from flash directly. + + The SEC driver locates FVMAIN_COMPACT in the flash, and decompresses the + main firmware image to RAM. The rest of OVMF (PEI, DXE, BDS phases) run + from RAM. + +As already mentioned, the OVMF.fd file is mapped by qemu's +"hw/block/pflash_cfi01.c" device just under 4 GB in guest-physical address +space, according to the command line option + + -drive if=pflash,format=raw,file=fedora.flash + +(refer to the Example qemu invocation). This is a "ROMD device", which can +switch out of "ROMD mode" and back into it. + +Namely, in the default ROMD mode, the guest-physical address range backed by +the flash device reads and executes as ROM (it does not trap from KVM to QEMU). +The first write access in this mode traps to QEMU, and flips the device out of +ROMD mode. + +In non-ROMD mode, the flash chip is programmed by storing CFI (Common Flash +Interface) command values at the flash-covered addresses; both reads and writes +trap to QEMU, and the flash contents are modified and synchronized to the +host-side file. A special CFI command flips the flash device back to ROMD mode. + +Qemu implements the above based on the KVM_CAP_READONLY_MEM / KVM_MEM_READONLY +KVM features, and OVMF puts it to use in its EFI_FIRMWARE_VOLUME_BLOCK_PROTOCOL +implementation, under "OvmfPkg/QemuFlashFvbServicesRuntimeDxe". + +IMPORTANT: Never pass OVMF.fd to qemu with the -bios option. That option maps +the firmware image as ROM into the guest's address space, and forces OVMF to +emulate non-volatile variables with a fallback driver that is bound to have +insufficient and confusing semantics. + +The 128 KB firmware volume with the variable store, discussed under (1), is +also built as a separate host-side file, named "OVMF_VARS.fd". The "rest" is +built into a third file, "OVMF_CODE.fd", which is only 1920 KB in size. The +variable store is mapped into its usual location, at 4 GB - 2 MB = 0xFFE0_0000, +through the following qemu options: + + -drive if=pflash,format=raw,readonly,file=OVMF_CODE.fd \ + -drive if=pflash,format=raw,file=fedora.varstore.fd + +This way qemu configures two flash chips consecutively, with start addresses +growing downwards, which is transparent to OVMF. + +[RHEL] Red Hat Enterprise Linux 7.1 ships a Secure Boot-enabled, X64, DEBUG + firmware only. Furthermore, only the split files ("OVMF_VARS.fd" and + "OVMF_CODE.fd") are available. + +S3 (suspend to RAM and resume) +------------------------------ + +As noted in Example qemu invocation, the + + -global PIIX4_PM.disable_s3=0 + +command line option tells qemu and OVMF if the user would like to enable S3 +support. (This is corresponds to the /domain/pm/suspend-to-mem/@enabled libvirt +domain XML attribute.) + +Implementing / orchestrating S3 was a considerable community effort in OVMF. A +detailed description exceeds the scope of this report; we only make a few +statements. + +(1) S3-related PPIs and protocols are well documented in the PI specification. + +(2) Edk2 contains most modules that are needed to implement S3 on a given + platform. One abstraction that is central to the porting / extending of the + S3-related modules to a new platform is the LockBox library interface, + which a specific platform can fill in by implementing its own LockBox + library instance. + + The LockBox library provides a privileged name-value store (to be addressed + by GUIDs). The privilege separation stretches between the firmware and the + operating system. That is, the S3-related machinery of the firmware saves + some items in the LockBox securely, under well-known GUIDs, before booting + the operating system. During resume (which is a form of warm reset), the + firmware is activated again, and retrieves items from the LockBox. Before + jumping to the OS's resume vector, the LockBox is secured again. + + We'll return to this later when we separately discuss SMRAM and SMM. + +(3) During resume, the DXE and later phases are never reached; only the reset + vector, and the SEC and PEI phases of the firmware run. The platform is + supposed to detect a resume in progress during PEI, and to store that fact + in the BootMode field of the Phase Handoff Information Table (PHIT) HOB. + OVMF keys this off the CMOS, see OvmfPkg/PlatformPei. + + At the end of PEI, the DXE IPL PEIM (Initial Program Load PEI Module, see + MdeModulePkg/Core/DxeIplPeim) examines the Boot Mode, and if it says "S3 + resume in progress", then the IPL branches to the PEIM that exports + EFI_PEI_S3_RESUME2_PPI (provided by UefiCpuPkg/Universal/Acpi/S3Resume2Pei) + rather than loading the DXE core. + + S3Resume2Pei executes the technical steps of the resumption, relying on the + contents of the LockBox. + +(4) During first boot (or after a normal platform reset), when DXE does run, + hardware drivers in the DXE phase are encouraged to "stash" their hardware + configuration steps (eg. accesses to PCI config space, I/O ports, memory + mapped addresses, and so on) in a centrally maintained, so called "S3 boot + script". Hardware accesses are represented with opcodes of a special binary + script language. + + This boot script is to be replayed during resume, by S3Resume2Pei. The + general goal is to bring back hardware devices -- which have been powered + off during suspend -- to their original after-first-boot state, and in + particular, to do so quickly. + + At the moment, OVMF saves only one opcode in the S3 resume boot script: an + INFORMATION opcode, with contents 0xDEADBEEF (in network byte order). The + consensus between Linux developers seems to be that boot firmware is only + responsible for restoring basic chipset state, which OVMF does during PEI + anyway, independently of S3 vs. normal reset. (One example is the power + management registers of the i440fx chipset.) Device and peripheral state is + the responsibility of the runtime operating system. + + Although an experimental OVMF S3 boot script was at one point captured for + the virtual Cirrus VGA card, such a boot script cannot follow eg. video + mode changes effected by the OS. Hence the operating system can never avoid + restoring device state, and most Linux display drivers (eg. stdvga, QXL) + already cover S3 resume fully. + + The XDDM and WDDM driver models used under Windows OSes seem to recognize + this notion of runtime OS responsibility as well. (See the list of OSes + supported by OVMF in a separate section.) + +(5) The S3 suspend/resume data flow in OVMF is included here tersely, for + interested developers. + + (a) BdsLibBootViaBootOption() + EFI_ACPI_S3_SAVE_PROTOCOL [AcpiS3SaveDxe] + - saves ACPI S3 Context to LockBox ---------------------+ + (including FACS address -- FACS ACPI table | + contains OS waking vector) | + | + - prepares boot script: | + EFI_S3_SAVE_STATE_PROTOCOL.Write() [S3SaveStateDxe] | + S3BootScriptLib [PiDxeS3BootScriptLib] | + - opcodes & arguments are saved in NVS. --+ | + | | + - issues a notification by installing | | + EFI_DXE_SMM_READY_TO_LOCK_PROTOCOL | | + | | + (b) EFI_S3_SAVE_STATE_PROTOCOL [S3SaveStateDxe] | | + S3BootScriptLib [PiDxeS3BootScriptLib] | | + - closes script with special opcode <---------+ | + - script is available in non-volatile memory | + via PcdS3BootScriptTablePrivateDataPtr --+ | + | | + BootScriptExecutorDxe | | + S3BootScriptLib [PiDxeS3BootScriptLib] | | + - Knows about boot script location by <----+ | + synchronizing with the other library | + instance via | + PcdS3BootScriptTablePrivateDataPtr. | + - Copies relocated image of itself to | + reserved memory. --------------------------------+ | + - Saved image contains pointer to boot script. ---|--+ | + | | | + Runtime: | | | + | | | + (c) OS is booted, writes OS waking vector to FACS, | | | + suspends machine | | | + | | | + S3 Resume (PEI): | | | + | | | + (d) PlatformPei sets S3 Boot Mode based on CMOS | | | + | | | + (e) DXE core is skipped and EFI_PEI_S3_RESUME2 is | | | + called as last step of PEI | | | + | | | + (f) S3Resume2Pei retrieves from LockBox: | | | + - ACPI S3 Context (path to FACS) <------------------|--|--+ + | | | + +------------------|--|--+ + - Boot Script Executor Image <----------------------+ | | + | | + (g) BootScriptExecutorDxe | | + S3BootScriptLib [PiDxeS3BootScriptLib] | | + - executes boot script <-----------------------------+ | + | + (h) OS waking vector available from ACPI S3 Context / FACS <--+ + is called + +A comprehensive memory map of OVMF +---------------------------------- + +The following section gives a detailed analysis of memory ranges below 4 GB +that OVMF statically uses. + +In the rightmost column, the PCD entry is identified by which the source refers +to the address or size in question. + +The flash-covered range has been discussed previously in "Firmware image +structure", therefore we include it only for completeness. Due to the fact that +this range is always backed by a memory mapped device (and never RAM), it is +unaffected by S3 (suspend to RAM and resume). + ++--------------------------+ 4194304 KB +| | +| SECFV | size: 208 KB +| | ++--------------------------+ 4194096 KB +| | +| FVMAIN_COMPACT | size: 1712 KB +| | ++--------------------------+ 4192384 KB +| | +| variable store | size: 64 KB PcdFlashNvStorageFtwSpareSize +| spare area | +| | ++--------------------------+ 4192320 KB PcdOvmfFlashNvStorageFtwSpareBase +| | +| FTW working block | size: 4 KB PcdFlashNvStorageFtwWorkingSize +| | ++--------------------------+ 4192316 KB PcdOvmfFlashNvStorageFtwWorkingBase +| | +| Event log of | size: 4 KB PcdOvmfFlashNvStorageEventLogSize +| non-volatile storage | +| | ++--------------------------+ 4192312 KB PcdOvmfFlashNvStorageEventLogBase +| | +| variable store | size: 56 KB PcdFlashNvStorageVariableSize +| | ++--------------------------+ 4192256 KB PcdOvmfFlashNvStorageVariableBase + +The flash-mapped image of OVMF.fd covers the entire structure above (2048 KB). + +When using the split files, the address 4192384 KB +(PcdOvmfFlashNvStorageFtwSpareBase + PcdFlashNvStorageFtwSpareSize) is the +boundary between the mapped images of OVMF_VARS.fd (56 KB + 4 KB + 4 KB + 64 KB += 128 KB) and OVMF_CODE.fd (1712 KB + 208 KB = 1920 KB). + +With regard to RAM that is statically used by OVMF, S3 (suspend to RAM and +resume) complicates matters. Many ranges have been introduced only to support +S3, hence for all ranges below, the following questions will be audited: + +(a) when and how a given range is initialized after first boot of the VM, +(b) how it is protected from memory allocations during DXE, +(c) how it is protected from the OS, +(d) how it is accessed on the S3 resume path, +(e) how it is accessed on the warm reset path. + +Importantly, the term "protected" is meant as protection against inadvertent +reallocations and overwrites by co-operating DXE and OS modules. It does not +imply security against malicious code. + ++--------------------------+ 17408 KB +| | +|DXEFV from FVMAIN_COMPACT | size: 8192 KB PcdOvmfDxeMemFvSize +| decompressed firmware | +| volume with DXE modules | +| | ++--------------------------+ 9216 KB PcdOvmfDxeMemFvBase +| | +|PEIFV from FVMAIN_COMPACT | size: 896 KB PcdOvmfPeiMemFvSize +| decompressed firmware | +| volume with PEI modules | +| | ++--------------------------+ 8320 KB PcdOvmfPeiMemFvBase +| | +| permanent PEI memory for | size: 32 KB PcdS3AcpiReservedMemorySize +| the S3 resume path | +| | ++--------------------------+ 8288 KB PcdS3AcpiReservedMemoryBase +| | +| temporary SEC/PEI heap | size: 32 KB PcdOvmfSecPeiTempRamSize +| and stack | +| | ++--------------------------+ 8256 KB PcdOvmfSecPeiTempRamBase +| | +| unused | size: 32 KB +| | ++--------------------------+ 8224 KB +| | +| SEC's table of | size: 4 KB PcdGuidedExtractHandlerTableSize +| GUIDed section handlers | +| | ++--------------------------+ 8220 KB PcdGuidedExtractHandlerTableAddress +| | +| LockBox storage | size: 4 KB PcdOvmfLockBoxStorageSize +| | ++--------------------------+ 8216 KB PcdOvmfLockBoxStorageBase +| | +| early page tables on X64 | size: 24 KB PcdOvmfSecPageTablesSize +| | ++--------------------------+ 8192 KB PcdOvmfSecPageTablesBase + +(1) Early page tables on X64: + + (a) when and how it is initialized after first boot of the VM + + The range is filled in during the SEC phase + [OvmfPkg/ResetVector/Ia32/PageTables64.asm]. The CR3 register is verified + against the base address in SecCoreStartupWithStack() + [OvmfPkg/Sec/SecMain.c]. + + (b) how it is protected from memory allocations during DXE + + If S3 was enabled on the QEMU command line (see "-global + PIIX4_PM.disable_s3=0" earlier), then InitializeRamRegions() + [OvmfPkg/PlatformPei/MemDetect.c] protects the range with an AcpiNVS memory + allocation HOB, in PEI. + + If S3 was disabled, then this range is not protected. DXE's own page tables + are first built while still in PEI (see HandOffToDxeCore() + [MdeModulePkg/Core/DxeIplPeim/X64/DxeLoadFunc.c]). Those tables are located + in permanent PEI memory. After CR3 is switched over to them (which occurs + before jumping to the DXE core entry point), we don't have to preserve the + initial tables. + + (c) how it is protected from the OS + + If S3 is enabled, then (1b) reserves it from the OS too. + + If S3 is disabled, then the range needs no protection. + + (d) how it is accessed on the S3 resume path + + It is rewritten same as in (1a), which is fine because (1c) reserved it. + + (e) how it is accessed on the warm reset path + + It is rewritten same as in (1a). + +(2) LockBox storage: + + (a) when and how it is initialized after first boot of the VM + + InitializeRamRegions() [OvmfPkg/PlatformPei/MemDetect.c] zeroes out the + area during PEI. This is correct but not strictly necessary, since on first + boot the area is zero-filled anyway. + + The LockBox signature of the area is filled in by the PEI module or DXE + driver that has been linked against OVMF's LockBoxLib and is run first. The + signature is written in LockBoxLibInitialize() + [OvmfPkg/Library/LockBoxLib/LockBoxLib.c]. + + Any module calling SaveLockBox() [OvmfPkg/Library/LockBoxLib/LockBoxLib.c] + will co-populate this area. + + (b) how it is protected from memory allocations during DXE + + If S3 is enabled, then InitializeRamRegions() + [OvmfPkg/PlatformPei/MemDetect.c] protects the range as AcpiNVS. + + Otherwise, the range is covered with a BootServicesData memory allocation + HOB. + + (c) how it is protected from the OS + + If S3 is enabled, then (2b) protects it sufficiently. + + Otherwise the range requires no runtime protection, and the + BootServicesData allocation type from (2b) ensures that the range will be + released to the OS. + + (d) how it is accessed on the S3 resume path + + The S3 Resume PEIM restores data from the LockBox, which has been correctly + protected in (2c). + + (e) how it is accessed on the warm reset path + + InitializeRamRegions() [OvmfPkg/PlatformPei/MemDetect.c] zeroes out the + range during PEI, effectively emptying the LockBox. Modules will + re-populate the LockBox as described in (2a). + +(3) SEC's table of GUIDed section handlers + + (a) when and how it is initialized after first boot of the VM + + The following two library instances are linked into SecMain: + - IntelFrameworkModulePkg/Library/LzmaCustomDecompressLib, + - MdePkg/Library/BaseExtractGuidedSectionLib. + + The first library registers its LZMA decompressor plugin (which is a called + a "section handler") by calling the second library: + + LzmaDecompressLibConstructor() [GuidedSectionExtraction.c] + ExtractGuidedSectionRegisterHandlers() [BaseExtractGuidedSectionLib.c] + + The second library maintains its table of registered "section handlers", to + be indexed by GUID, in this fixed memory area, independently of S3 + enablement. + + (The decompression of FVMAIN_COMPACT's FFS file section that contains the + PEIFV and DXEFV firmware volumes occurs with the LZMA decompressor + registered above. See (6) and (7) below.) + + (b) how it is protected from memory allocations during DXE + + There is no need to protect this area from DXE: because nothing else in + OVMF links against BaseExtractGuidedSectionLib, the area loses its + significance as soon as OVMF progresses from SEC to PEI, therefore DXE is + allowed to overwrite the region. + + (c) how it is protected from the OS + + When S3 is enabled, we cover the range with an AcpiNVS memory allocation + HOB in InitializeRamRegions(). + + When S3 is disabled, the range is not protected. + + (d) how it is accessed on the S3 resume path + + The table of registered section handlers is again managed by + BaseExtractGuidedSectionLib linked into SecMain exclusively. Section + handler registrations update the table in-place (based on GUID matches). + + (e) how it is accessed on the warm reset path + + If S3 is enabled, then the OS won't damage the table (due to (3c)), thus + see (3d). + + If S3 is disabled, then the OS has most probably overwritten the range with + its own data, hence (3a) -- complete reinitialization -- will come into + effect, based on the table signature check in BaseExtractGuidedSectionLib. + +(4) temporary SEC/PEI heap and stack + + (a) when and how it is initialized after first boot of the VM + + The range is configured in [OvmfPkg/Sec/X64/SecEntry.S] and + SecCoreStartupWithStack() [OvmfPkg/Sec/SecMain.c]. The stack half is read & + written by the CPU transparently. The heap half is used for memory + allocations during PEI. + + Data is migrated out (to permanent PEI stack & memory) in (or soon after) + PublishPeiMemory() [OvmfPkg/PlatformPei/MemDetect.c]. + + (b) how it is protected from memory allocations during DXE + + It is not necessary to protect this range during DXE because its use ends + still in PEI. + + (c) how it is protected from the OS + + If S3 is enabled, then InitializeRamRegions() + [OvmfPkg/PlatformPei/MemDetect.c] reserves it as AcpiNVS. + + If S3 is disabled, then the range doesn't require protection. + + (d) how it is accessed on the S3 resume path + + Same as in (4a), except the target area of the migration triggered by + PublishPeiMemory() [OvmfPkg/PlatformPei/MemDetect.c] is different -- see + (5). + + (e) how it is accessed on the warm reset path + + Same as in (4a). The stack and heap halves both may contain garbage, but it + doesn't matter. + +(5) permanent PEI memory for the S3 resume path + + (a) when and how it is initialized after first boot of the VM + + No particular initialization or use. + + (b) how it is protected from memory allocations during DXE + + We don't need to protect this area during DXE. + + (c) how it is protected from the OS + + When S3 is enabled, InitializeRamRegions() + [OvmfPkg/PlatformPei/MemDetect.c] makes sure the OS stays away by covering + the range with an AcpiNVS memory allocation HOB. + + When S3 is disabled, the range needs no protection. + + (d) how it is accessed on the S3 resume path + + PublishPeiMemory() installs the range as permanent RAM for PEI. The range + will serve as stack and will satisfy allocation requests during the rest of + PEI. OS data won't overlap due to (5c). + + (e) how it is accessed on the warm reset path + + Same as (5a). + +(6) PEIFV -- decompressed firmware volume with PEI modules + + (a) when and how it is initialized after first boot of the VM + + DecompressMemFvs() [OvmfPkg/Sec/SecMain.c] populates the area, by + decompressing the flash-mapped FVMAIN_COMPACT volume's contents. (Refer to + "Firmware image structure".) + + (b) how it is protected from memory allocations during DXE + + When S3 is disabled, PeiFvInitialization() [OvmfPkg/PlatformPei/Fv.c] + covers the range with a BootServicesData memory allocation HOB. + + When S3 is enabled, the same is coverage is ensured, just with the stronger + AcpiNVS memory allocation type. + + (c) how it is protected from the OS + + When S3 is disabled, it is not necessary to keep the range from the OS. + + Otherwise the AcpiNVS type allocation from (6b) provides coverage. + + (d) how it is accessed on the S3 resume path + + Rather than decompressing it again from FVMAIN_COMPACT, GetS3ResumePeiFv() + [OvmfPkg/Sec/SecMain.c] reuses the protected area for parsing / execution + from (6c). + + (e) how it is accessed on the warm reset path + + Same as (6a). + +(7) DXEFV -- decompressed firmware volume with DXE modules + + (a) when and how it is initialized after first boot of the VM + + Same as (6a). + + (b) how it is protected from memory allocations during DXE + + PeiFvInitialization() [OvmfPkg/PlatformPei/Fv.c] covers the range with a + BootServicesData memory allocation HOB. + + (c) how it is protected from the OS + + The OS is allowed to release and reuse this range. + + (d) how it is accessed on the S3 resume path + + It's not; DXE never runs during S3 resume. + + (e) how it is accessed on the warm reset path + + Same as in (7a). + +Known Secure Boot limitations +----------------------------- + +Under "Motivation" we've mentioned that OVMF's Secure Boot implementation is +not suitable for production use yet -- it's only good for development and +testing of standards-conformant, non-malicious guest code (UEFI and operating +system alike). + +Now that we've examined the persistent flash device, the workings of S3, and +the memory map, we can discuss two currently known shortcomings of OVMF's +Secure Boot that in fact make it insecure. (Clearly problems other than these +two might exist; the set of issues considered here is not meant to be +exhaustive.) + +One trait of Secure Boot is tamper-evidence. Secure Boot may not prevent +malicious modification of software components (for example, operating system +drivers), but by being the root of integrity on a platform, it can catch (or +indirectly contribute to catching) unauthorized changes, by way of signature +and certificate checks at the earliest phases of boot. + +If an attacker can tamper with key material stored in authenticated and/or +boot-time only persistent variables (for example, PK, KEK, db, dbt, dbx), then +the intended security of this scheme is compromised. The UEFI 2.4A +specification says + +- in section 28.3.4: + + Platform Keys: + + The public key must be stored in non-volatile storage which is tamper and + delete resistant. + + Key Exchange Keys: + + The public key must be stored in non-volatile storage which is tamper + resistant. + +- in section 28.6.1: + + The signature database variables db, dbt, and dbx must be stored in + tamper-resistant non-volatile storage. + +(1) The combination of QEMU, KVM, and OVMF does not provide this kind of + resistance. The variable store in the emulated flash chip is directly + accessible to, and reprogrammable by, UEFI drivers, applications, and + operating systems. + +(2) Under "S3 (suspend to RAM and resume)" we pointed out that the LockBox + storage must be similarly secure and tamper-resistant. + + On the S3 resume path, the PEIM providing EFI_PEI_S3_RESUME2_PPI + (UefiCpuPkg/Universal/Acpi/S3Resume2Pei) restores and interprets data from + the LockBox that has been saved there during boot. This PEIM, being part of + the firmware, has full access to the platform. If an operating system can + tamper with the contents of the LockBox, then at the next resume the + platform's integrity might be subverted. + + OVMF stores the LockBox in normal guest RAM (refer to the memory map + section above). Operating systems and third party UEFI drivers and UEFI + applications that respect the UEFI memory map will not inadvertently + overwrite the LockBox storage, but there's nothing to prevent eg. a + malicious kernel from modifying the LockBox. + +One means to address these issues is SMM and SMRAM (System Management Mode and +System Management RAM). + +During boot and resume, the firmware can enter and leave SMM and access SMRAM. +Before the DXE phase is left, and control is transferred to the BDS phase (when +third party UEFI drivers and applications can be loaded, and an operating +system can be loaded), SMRAM is locked in hardware, and subsequent modules +cannot access it directly. (See EFI_DXE_SMM_READY_TO_LOCK_PROTOCOL.) + +Once SMRAM has been locked, UEFI drivers and the operating system can enter SMM +by raising a System Management Interrupt (SMI), at which point trusted code +(part of the platform firmware) takes control. SMRAM is also unlocked by +platform reset, at which point the boot firmware takes control again. + +Variable store and LockBox in SMRAM +----------------------------------- + +Edk2 provides almost all components to implement the variable store and the +LockBox in SMRAM. In this section we summarize ideas for utilizing those +facilities. + +The SMRAM and SMM infrastructure in edk2 is built up as follows: + +(1) The platform hardware provides SMM / SMI / SMRAM. + + Qemu/KVM doesn't support these features currently and should implement them + in the longer term. + +(2) The platform vendor (in this case, OVMF developers) implement device + drivers for the platform's System Management Mode: + + - EFI_SMM_CONTROL2_PROTOCOL: for raising a synchronous (and/or) periodic + SMI(s); that is, for entering SMM. + + - EFI_SMM_ACCESS2_PROTOCOL: for describing and accessing SMRAM. + + These protocols are documented in the PI Specification, Volume 4. + +(3) The platform DSC file is to include the following platform-independent + modules: + + - MdeModulePkg/Core/PiSmmCore/PiSmmIpl.inf: SMM Initial Program Load + - MdeModulePkg/Core/PiSmmCore/PiSmmCore.inf: SMM Core + +(4) At this point, modules of type DXE_SMM_DRIVER can be loaded. + + Such drivers are privileged. They run in SMM, have access to SMRAM, and are + separated and switched from other drivers through SMIs. Secure + communication between unprivileged (non-SMM) and privileged (SMM) drivers + happens through EFI_SMM_COMMUNICATION_PROTOCOL (implemented by the SMM + Core, see (3)). + + DXE_SMM_DRIVER modules must sanitize their input (coming from unprivileged + drivers) carefully. + +(5) The authenticated runtime variable services driver (for Secure Boot builds) + is located under "SecurityPkg/VariableAuthenticated/RuntimeDxe". OVMF + currently builds the driver (a DXE_RUNTIME_DRIVER module) with the + "VariableRuntimeDxe.inf" control file (refer to "OvmfPkg/OvmfPkgX64.dsc"), + which does not use SMM. + + The directory includes two more INF files: + + - VariableSmm.inf -- module type: DXE_SMM_DRIVER. A privileged driver that + runs in SMM and has access to SMRAM. + + - VariableSmmRuntimeDxe.inf -- module type: DXE_RUNTIME_DRIVER. A + non-privileged driver that implements the variable runtime services + (replacing the current "VariableRuntimeDxe.inf" file) by communicating + with the above privileged SMM half via EFI_SMM_COMMUNICATION_PROTOCOL. + +(6) An SMRAM-based LockBox implementation needs to be discussed in two parts, + because the LockBox is accessed in both PEI and DXE. + + (a) During DXE, drivers save data in the LockBox. A save operation is + layered as follows: + + - The unprivileged driver wishing to store data in the LockBox links + against the "MdeModulePkg/Library/SmmLockBoxLib/SmmLockBoxDxeLib.inf" + library instance. + + The library allows the unprivileged driver to format requests for the + privileged SMM LockBox driver (see below), and to parse responses. + + - The privileged SMM LockBox driver is built from + "MdeModulePkg/Universal/LockBox/SmmLockBox/SmmLockBox.inf". This + driver has module type DXE_SMM_DRIVER and can access SMRAM. + + The driver delegates command parsing and response formatting to + "MdeModulePkg/Library/SmmLockBoxLib/SmmLockBoxSmmLib.inf". + + - The above two halves (unprivileged and privileged) mirror what we've + seen in case of the variable service drivers, under (5). + + (b) In PEI, the S3 Resume PEIM (UefiCpuPkg/Universal/Acpi/S3Resume2Pei) + retrieves data from the LockBox. + + Presumably, S3Resume2Pei should be considered an "unprivileged PEIM", + and the SMRAM access should be layered as seen in DXE. Unfortunately, + edk2 does not implement all of the layers in PEI -- the code either + doesn't exist, or it is not open source: + + role | DXE: protocol/module | PEI: PPI/module + -------------+--------------------------------+------------------------------ + unprivileged | any | S3Resume2Pei.inf + driver | | + -------------+--------------------------------+------------------------------ + command | LIBRARY_CLASS = LockBoxLib | LIBRARY_CLASS = LockBoxLib + formatting | | + and response | SmmLockBoxDxeLib.inf | SmmLockBoxPeiLib.inf + parsing | | + -------------+--------------------------------+------------------------------ + privilege | EFI_SMM_COMMUNICATION_PROTOCOL | EFI_PEI_SMM_COMMUNICATION_PPI + separation | | + | PiSmmCore.inf | missing! + -------------+--------------------------------+------------------------------ + platform SMM | EFI_SMM_CONTROL2_PROTOCOL | PEI_SMM_CONTROL_PPI + and SMRAM | EFI_SMM_ACCESS2_PROTOCOL | PEI_SMM_ACCESS_PPI + access | | + | to be done in OVMF | to be done in OVMF + -------------+--------------------------------+------------------------------ + command | LIBRARY_CLASS = LockBoxLib | LIBRARY_CLASS = LockBoxLib + parsing and | | + response | SmmLockBoxSmmLib.inf | missing! + formatting | | + -------------+--------------------------------+------------------------------ + privileged | SmmLockBox.inf | missing! + LockBox | | + driver | | + + Alternatively, in the future OVMF might be able to provide a LockBoxLib + instance (an SmmLockBoxPeiLib substitute) for S3Resume2Pei that + accesses SMRAM directly, eliminating the need for deeper layers in the + stack (that is, EFI_PEI_SMM_COMMUNICATION_PPI and deeper). + + In fact, a "thin" EFI_PEI_SMM_COMMUNICATION_PPI implementation whose + sole Communicate() member invariably returns EFI_NOT_STARTED would + cause the current SmmLockBoxPeiLib library instance to directly perform + full-depth SMRAM access and LockBox search, obviating the "missing" + cells. (With reference to A Tour Beyond BIOS: Implementing S3 Resume + with EDK2, by Jiewen Yao and Vincent Zimmer, October 2014.) + +Select features +--------------- + +In this section we'll browse the top-level "OvmfPkg" package directory, and +discuss the more interesting drivers and libraries that have not been mentioned +thus far. + +X64-specific reset vector for OVMF +.................................. + +The "OvmfPkg/ResetVector" directory customizes the reset vector (found in +"UefiCpuPkg/ResetVector/Vtf0") for "OvmfPkgX64.fdf", that is, when the SEC/PEI +phases run in 64-bit (ie. long) mode. + +The reset vector's control flow looks roughly like: + + resetVector [Ia16/ResetVectorVtf0.asm] + EarlyBspInitReal16 [Ia16/Init16.asm] + Main16 [Main.asm] + EarlyInit16 [Ia16/Init16.asm] + + ; Transition the processor from + ; 16-bit real mode to 32-bit flat mode + TransitionFromReal16To32BitFlat [Ia16/Real16ToFlat32.asm] + + ; Search for the + ; Boot Firmware Volume (BFV) + Flat32SearchForBfvBase [Ia32/SearchForBfvBase.asm] + + ; Search for the SEC entry point + Flat32SearchForSecEntryPoint [Ia32/SearchForSecEntry.asm] + + %ifdef ARCH_IA32 + ; Jump to the 32-bit SEC entry point + %else + ; Transition the processor + ; from 32-bit flat mode + ; to 64-bit flat mode + Transition32FlatTo64Flat [Ia32/Flat32ToFlat64.asm] + + SetCr3ForPageTables64 [Ia32/PageTables64.asm] + ; set CR3 to page tables + ; built into the ROM image + + ; enable PAE + ; set LME + ; enable paging + + ; Jump to the 64-bit SEC entry point + %endif + +On physical platforms, the initial page tables referenced by +SetCr3ForPageTables64 are built statically into the flash device image, and are +present in ROM at runtime. This is fine on physical platforms because the +pre-built page table entries have the Accessed and Dirty bits set from the +start. + +Accordingly, for OVMF running in long mode on qemu/KVM, the initial page tables +were mapped as a KVM_MEM_READONLY slot, as part of QEMU's pflash device (refer +to "Firmware image structure" above). + +In spite of the Accessed and Dirty bits being pre-set in the read-only, +in-flash PTEs, in a virtual machine attempts are made to update said PTE bits, +differently from physical hardware. The component attempting to update the +read-only PTEs can be one of the following: + +- The processor itself, if it supports nested paging, and the user enables that + processor feature, + +- KVM code implementing shadow paging, otherwise. + +The first case presents no user-visible symptoms, but the second case (KVM, +shadow paging) used to cause a triple fault, prior to Linux commit ba6a354 +("KVM: mmu: allow page tables to be in read-only slots"). + +For compatibility with earlier KVM versions, the OvmfPkg/ResetVector directory +adapts the generic reset vector code as follows: + + Transition32FlatTo64Flat [UefiCpuPkg/.../Ia32/Flat32ToFlat64.asm] + + SetCr3ForPageTables64 [OvmfPkg/ResetVector/Ia32/PageTables64.asm] + + ; dynamically build the initial page tables in RAM, at address + ; PcdOvmfSecPageTablesBase (refer to the memory map above), + ; identity-mapping the first 4 GB of address space + + ; set CR3 to PcdOvmfSecPageTablesBase + + ; enable PAE + ; set LME + ; enable paging + +This way the PTEs that earlier KVM versions try to update (during shadow +paging) are located in a read-write memory slot, and the write attempts +succeed. + +Client library for QEMU's firmware configuration interface +.......................................................... + +QEMU provides a write-only, 16-bit wide control port, and a read-write, 8-bit +wide data port for exchanging configuration elements with the firmware. + +The firmware writes a selector (a key) to the control port (0x510), and then +reads the corresponding configuration data (produced by QEMU) from the data +port (0x511). + +If the selected entry is writable, the firmware may overwrite it. If QEMU has +associated a callback with the entry, then when the entry is completely +rewritten, QEMU runs the callback. (OVMF does not rewrite any entries at the +moment.) + +A number of selector values (keys) are predefined. In particular, key 0x19 +selects (returns) a directory of { name, selector, size } triplets, roughly +speaking. + +The firmware can request configuration elements by well-known name as well, by +looking up the selector value first in the directory, by name, and then writing +the selector to the control port. The number of bytes to read subsequently from +the data port is known from the directory entry's "size" field. + +By convention, directory entries (well-known symbolic names of configuration +elements) are formatted as POSIX pathnames. For example, the array selected by +the "etc/system-states" name indicates (among other things) whether the user +enabled S3 support in QEMU. + +The above interface is called "fw_cfg". + +The binary data associated with a symbolic name is called an "fw_cfg file". + +OVMF's fw_cfg client library is found in "OvmfPkg/Library/QemuFwCfgLib". OVMF +discovers many aspects of the virtual system with it; we refer to a few +examples below. + +Guest ACPI tables +................. + +An operating system discovers a good amount of its hardware by parsing ACPI +tables, and by interpreting ACPI objects and methods. On physical hardware, the +platform vendor's firmware installs ACPI tables in memory that match both the +hardware present in the system and the user's firmware configuration ("BIOS +setup"). + +Under qemu/KVM, the owner of the (virtual) hardware configuration is QEMU. +Hardware can easily be reconfigured on the command line. Furthermore, features +like CPU hotplug, PCI hotplug, memory hotplug are continuously developed for +QEMU, and operating systems need direct ACPI support to exploit these features. + +For this reason, QEMU builds its own ACPI tables dynamically, in a +self-descriptive manner, and exports them to the firmware through a complex, +multi-file fw_cfg interface. It is rooted in the "etc/table-loader" fw_cfg +file. (Further details of this interface are out of scope for this report.) + +OVMF's AcpiPlatformDxe driver fetches the ACPI tables, and installs them for +the guest OS with the EFI_ACPI_TABLE_PROTOCOL (which is in turn provided by the +generic "MdeModulePkg/Universal/Acpi/AcpiTableDxe" driver). + +For earlier QEMU versions and machine types (which we generally don't recommend +for OVMF; see "Scope"), the "OvmfPkg/AcpiTables" directory contains a few +static ACPI table templates. When the "etc/table-loader" fw_cfg file is +unavailable, AcpiPlatformDxe installs these default tables (with a little bit +of dynamic patching). + +When OVMF runs in a Xen domU, AcpiTableDxe also installs ACPI tables that +originate from the hypervisor's environment. + +Guest SMBIOS tables +................... + +Quoting the SMBIOS Reference Specification, + + [...] the System Management BIOS Reference Specification addresses how + motherboard and system vendors present management information about their + products in a standard format [...] + +In practice SMBIOS tables are just another set of tables that the platform +vendor's firmware installs in RAM for the operating system, and, importantly, +for management applications running on the OS. Without rehashing the "Guest +ACPI tables" section in full, let's map the OVMF roles seen there from ACPI to +SMBIOS: + + role | ACPI | SMBIOS + -------------------------+-------------------------+------------------------- + fw_cfg file | etc/table-loader | etc/smbios/smbios-tables + -------------------------+-------------------------+------------------------- + OVMF driver | AcpiPlatformDxe | SmbiosPlatformDxe + under "OvmfPkg" | | + -------------------------+-------------------------+------------------------- + Underlying protocol, | EFI_ACPI_TABLE_PROTOCOL | EFI_SMBIOS_PROTOCOL + implemented by generic | | + driver under | Acpi/AcpiTableDxe | SmbiosDxe + "MdeModulePkg/Universal" | | + -------------------------+-------------------------+------------------------- + default tables available | yes | [RHEL] yes, Type0 and + for earlier QEMU machine | | Type1 tables + types, with hot-patching | | + -------------------------+-------------------------+------------------------- + tables fetched in Xen | yes | yes + domUs | | + +Platform-specific boot policy +............................. + +OVMF's BDS (Boot Device Selection) phase is implemented by +IntelFrameworkModulePkg/Universal/BdsDxe. Roughly speaking, this large driver: + +- provides the EFI BDS architectural protocol (which DXE transfers control to + after dispatching all DXE drivers), + +- connects drivers to devices, + +- enumerates boot devices, + +- auto-generates boot options, + +- provides "BIOS setup" screens, such as: + + - Boot Manager, for booting an option, + + - Boot Maintenance Manager, for adding, deleting, and reordering boot + options, changing console properties etc, + + - Device Manager, where devices can register configuration forms, including + + - Secure Boot configuration forms, + + - OVMF's Platform Driver form (see under PlatformDxe). + +Firmware that includes the "IntelFrameworkModulePkg/Universal/BdsDxe" driver +can customize its behavior by providing an instance of the PlatformBdsLib +library class. The driver links against this platform library, and the +platform library can call Intel's BDS utility functions from +"IntelFrameworkModulePkg/Library/GenericBdsLib". + +OVMF's PlatformBdsLib instance can be found in +"OvmfPkg/Library/PlatformBdsLib". The main function where the BdsDxe driver +enters the library is PlatformBdsPolicyBehavior(). We mention two OVMF +particulars here. + +(1) OVMF is capable of loading kernel images directly from fw_cfg, matching + QEMU's -kernel, -initrd, and -append command line options. This feature is + useful for rapid, repeated Linux kernel testing, and is implemented in the + following call tree: + + PlatformBdsPolicyBehavior() [OvmfPkg/Library/PlatformBdsLib/BdsPlatform.c] + TryRunningQemuKernel() [OvmfPkg/Library/PlatformBdsLib/QemuKernel.c] + LoadLinux*() [OvmfPkg/Library/LoadLinuxLib/Linux.c] + + OvmfPkg/Library/LoadLinuxLib ports the efilinux bootloader project into + OvmfPkg. + +(2) OVMF seeks to comply with the boot order specification passed down by QEMU + over fw_cfg. + + (a) About Boot Modes + + During the PEI phase, OVMF determines and stores the Boot Mode in the + PHIT HOB (already mentioned in "S3 (suspend to RAM and resume)"). The + boot mode is supposed to influence the rest of the system, for example it + distinguishes S3 resume (BOOT_ON_S3_RESUME) from a "normal" boot. + + In general, "normal" boots can be further differentiated from each other; + for example for speed reasons. When the firmware can tell during PEI that + the chassis has not been opened since last power-up, then it might want + to save time by not connecting all devices and not enumerating all boot + options from scratch; it could just rely on the stored results of the + last enumeration. The matching BootMode value, to be set during PEI, + would be BOOT_ASSUMING_NO_CONFIGURATION_CHANGES. + + OVMF only sets one of the following two boot modes, based on CMOS + contents: + - BOOT_ON_S3_RESUME, + - BOOT_WITH_FULL_CONFIGURATION. + + For BOOT_ON_S3_RESUME, please refer to "S3 (suspend to RAM and resume)". + The other boot mode supported by OVMF, BOOT_WITH_FULL_CONFIGURATION, is + an appropriate "catch-all" for a virtual machine, where hardware can + easily change from boot to boot. + + (b) Auto-generation of boot options + + Accordingly, when not resuming from S3 sleep (*), OVMF always connects + all devices, and enumerates all bootable devices as new boot options + (non-volatile variables called Boot####). + + (*) During S3 resume, DXE is not reached, hence BDS isn't either. + + The auto-enumerated boot options are stored in the BootOrder non-volatile + variable after any preexistent options. (Boot options may exist before + auto-enumeration eg. because the user added them manually with the Boot + Maintenance Manager or the efibootmgr utility. They could also originate + from an earlier auto-enumeration.) + + PlatformBdsPolicyBehavior() [OvmfPkg/.../BdsPlatform.c] + TryRunningQemuKernel() [OvmfPkg/.../QemuKernel.c] + BdsLibConnectAll() [IntelFrameworkModulePkg/.../BdsConnect.c] + BdsLibEnumerateAllBootOption() [IntelFrameworkModulePkg/.../BdsBoot.c] + BdsLibBuildOptionFromHandle() [IntelFrameworkModulePkg/.../BdsBoot.c] + BdsLibRegisterNewOption() [IntelFrameworkModulePkg/.../BdsMisc.c] + // + // Append the new option number to the original option order + // + + (c) Relative UEFI device paths in boot options + + The handling of relative ("short-form") UEFI device paths is best + demonstrated through an example, and by quoting the UEFI 2.4A + specification. + + A short-form hard drive UEFI device path could be (displaying each device + path node on a separate line for readability): + + HD(1,GPT,14DD1CC5-D576-4BBF-8858-BAF877C8DF61,0x800,0x64000)/ + \EFI\fedora\shim.efi + + This device path lacks prefix nodes (eg. hardware or messaging type + nodes) that would lead to the hard drive. During load option processing, + the above short-form or relative device path could be matched against the + following absolute device path: + + PciRoot(0x0)/ + Pci(0x4,0x0)/ + HD(1,GPT,14DD1CC5-D576-4BBF-8858-BAF877C8DF61,0x800,0x64000)/ + \EFI\fedora\shim.efi + + The motivation for this type of device path matching / completion is to + allow the user to move around the hard drive (for example, to plug a + controller in a different PCI slot, or to expose the block device on a + different iSCSI path) and still enable the firmware to find the hard + drive. + + The UEFI specification says, + + 9.3.6 Media Device Path + 9.3.6.1 Hard Drive + + [...] Section 3.1.2 defines special rules for processing the Hard + Drive Media Device Path. These special rules enable a disk's location + to change and still have the system boot from the disk. [...] + + 3.1.2 Load Option Processing + + [...] The boot manager must [...] support booting from a short-form + device path that starts with the first element being a hard drive + media device path [...]. The boot manager must use the GUID or + signature and partition number in the hard drive device path to match + it to a device in the system. If the drive supports the GPT + partitioning scheme the GUID in the hard drive media device path is + compared with the UniquePartitionGuid field of the GUID Partition + Entry [...]. If the drive supports the PC-AT MBR scheme the signature + in the hard drive media device path is compared with the + UniqueMBRSignature in the Legacy Master Boot Record [...]. If a + signature match is made, then the partition number must also be + matched. The hard drive device path can be appended to the matching + hardware device path and normal boot behavior can then be used. If + more than one device matches the hard drive device path, the boot + manager will pick one arbitrarily. Thus the operating system must + ensure the uniqueness of the signatures on hard drives to guarantee + deterministic boot behavior. + + Edk2 implements and exposes the device path completion logic in the + already referenced "IntelFrameworkModulePkg/Library/GenericBdsLib" + library, in the BdsExpandPartitionPartialDevicePathToFull() function. + + (d) Filtering and reordering the boot options based on fw_cfg + + Once we have an "all-inclusive", partly preexistent, partly freshly + auto-generated boot option list from bullet (b), OVMF loads QEMU's + requested boot order from fw_cfg, and filters and reorders the list from + (b) with it: + + PlatformBdsPolicyBehavior() [OvmfPkg/.../BdsPlatform.c] + TryRunningQemuKernel() [OvmfPkg/.../QemuKernel.c] + BdsLibConnectAll() [IntelFrameworkModulePkg/.../BdsConnect.c] + BdsLibEnumerateAllBootOption() [IntelFrameworkModulePkg/.../BdsBoot.c] + SetBootOrderFromQemu() [OvmfPkg/.../QemuBootOrder.c] + + According to the (preferred) "-device ...,bootindex=N" and the (legacy) + '-boot order=drives' command line options, QEMU requests a boot order + from the firmware through the "bootorder" fw_cfg file. (For a bootindex + example, refer to the "Example qemu invocation" section.) + + This fw_cfg file consists of OpenFirmware (OFW) device paths -- note: not + UEFI device paths! --, one per line. An example list is: + + /pci@i0cf8/scsi@4/disk@0,0 + /pci@i0cf8/ide@1,1/drive@1/disk@0 + /pci@i0cf8/ethernet@3/ethernet-phy@0 + + OVMF filters and reorders the boot option list from bullet (b) with the + following nested loops algorithm: + + new_uefi_order := + for each qemu_ofw_path in QEMU's OpenFirmware device path list: + qemu_uefi_path_prefix := translate(qemu_ofw_path) + + for each boot_option in current_uefi_order: + full_boot_option := complete(boot_option) + + if match(qemu_uefi_path_prefix, full_boot_option): + append(new_uefi_order, boot_option) + break + + for each unmatched boot_option in current_uefi_order: + if survives(boot_option): + append(new_uefi_order, boot_option) + + current_uefi_order := new_uefi_order + + OVMF iterates over QEMU's OFW device paths in order, translates each to a + UEFI device path prefix, tries to match the translated prefix against the + UEFI boot options (which are completed from relative form to absolute + form for the purpose of prefix matching), and if there's a match, the + matching boot option is appended to the new boot order (which starts out + empty). + + (We elaborate on the translate() function under bullet (e). The + complete() function has been explained in bullet (c).) + + In addition, UEFI boot options that remain unmatched after filtering and + reordering are post-processed, and some of them "survive". Due to the + fact that OpenFirmware device paths have less expressive power than their + UEFI counterparts, some UEFI boot options are simply inexpressible (hence + unmatchable) by the nested loops algorithm. + + An important example is the memory-mapped UEFI shell, whose UEFI device + path is inexpressible by QEMU's OFW device paths: + + MemoryMapped(0xB,0x900000,0x10FFFFF)/ + FvFile(7C04A583-9E3E-4F1C-AD65-E05268D0B4D1) + + (Side remark: notice that the address range visible in the MemoryMapped() + node corresponds to DXEFV under "comprehensive memory map of OVMF"! In + addition, the FvFile() node's GUID originates from the FILE_GUID entry of + "ShellPkg/Application/Shell/Shell.inf".) + + The UEFI shell can be booted by pressing ESC in OVMF on the TianoCore + splash screen, and navigating to Boot Manager | EFI Internal Shell. If + the "survival policy" was not implemented, the UEFI shell's boot option + would always be filtered out. + + The current "survival policy" preserves all boot options that start with + neither PciRoot() nor HD(). + + (e) Translating QEMU's OpenFirmware device paths to UEFI device path + prefixes + + In this section we list the (strictly heuristical) mappings currently + performed by OVMF. + + The "prefix only" nature of the translation output is rooted minimally in + the fact that QEMU's OpenFirmware device paths cannot carry pathnames + within filesystems. There's no way to specify eg. + + \EFI\fedora\shim.efi + + in an OFW device path, therefore a UEFI device path translated from an + OFW device path can at best be a prefix (not a full match) of a UEFI + device path that ends with "\EFI\fedora\shim.efi". + + - IDE disk, IDE CD-ROM: + + OpenFirmware device path: + + /pci@i0cf8/ide@1,1/drive@0/disk@0 + ^ ^ ^ ^ ^ + | | | | master or slave + | | | primary or secondary + | PCI slot & function holding IDE controller + PCI root at system bus port, PIO + + UEFI device path prefix: + + PciRoot(0x0)/Pci(0x1,0x1)/Ata(Primary,Master,0x0) + ^ + fixed LUN + + - Floppy disk: + + OpenFirmware device path: + + /pci@i0cf8/isa@1/fdc@03f0/floppy@0 + ^ ^ ^ ^ + | | | A: or B: + | | ISA controller io-port (hex) + | PCI slot holding ISA controller + PCI root at system bus port, PIO + + UEFI device path prefix: + + PciRoot(0x0)/Pci(0x1,0x0)/Floppy(0x0) + ^ + ACPI UID (A: or B:) + + - Virtio-block disk: + + OpenFirmware device path: + + /pci@i0cf8/scsi@6[,3]/disk@0,0 + ^ ^ ^ ^ ^ + | | | fixed + | | PCI function corresponding to disk (optional) + | PCI slot holding disk + PCI root at system bus port, PIO + + UEFI device path prefixes (dependent on the presence of a nonzero PCI + function in the OFW device path): + + PciRoot(0x0)/Pci(0x6,0x0)/HD( + PciRoot(0x0)/Pci(0x6,0x3)/HD( + + - Virtio-scsi disk and virtio-scsi passthrough: + + OpenFirmware device path: + + /pci@i0cf8/scsi@7[,3]/channel@0/disk@2,3 + ^ ^ ^ ^ ^ + | | | | LUN + | | | target + | | channel (unused, fixed 0) + | PCI slot[, function] holding SCSI controller + PCI root at system bus port, PIO + + UEFI device path prefixes (dependent on the presence of a nonzero PCI + function in the OFW device path): + + PciRoot(0x0)/Pci(0x7,0x0)/Scsi(0x2,0x3) + PciRoot(0x0)/Pci(0x7,0x3)/Scsi(0x2,0x3) + + - Emulated and passed-through (physical) network cards: + + OpenFirmware device path: + + /pci@i0cf8/ethernet@3[,2] + ^ ^ + | PCI slot[, function] holding Ethernet card + PCI root at system bus port, PIO + + UEFI device path prefixes (dependent on the presence of a nonzero PCI + function in the OFW device path): + + PciRoot(0x0)/Pci(0x3,0x0) + PciRoot(0x0)/Pci(0x3,0x2) + +Virtio drivers +.............. + +UEFI abstracts various types of hardware resources into protocols, and allows +firmware developers to implement those protocols in device drivers. The Virtio +Specification defines various types of virtual hardware for virtual machines. +Connecting the two specifications, OVMF provides UEFI drivers for QEMU's +virtio-block, virtio-scsi, and virtio-net devices. + +The following diagram presents the protocol and driver stack related to Virtio +devices in edk2 and OVMF. Each node in the graph identifies a protocol and/or +the edk2 driver that produces it. Nodes on the top are more abstract. + + EFI_BLOCK_IO_PROTOCOL EFI_SIMPLE_NETWORK_PROTOCOL + [OvmfPkg/VirtioBlkDxe] [OvmfPkg/VirtioNetDxe] + | | + | EFI_EXT_SCSI_PASS_THRU_PROTOCOL | + | [OvmfPkg/VirtioScsiDxe] | + | | | + +------------------------+--------------------------+ + | + VIRTIO_DEVICE_PROTOCOL + | + +---------------------+---------------------+ + | | + [OvmfPkg/VirtioPciDeviceDxe] [custom platform drivers] + | | + | | + EFI_PCI_IO_PROTOCOL [OvmfPkg/Library/VirtioMmioDeviceLib] + [MdeModulePkg/Bus/Pci/PciBusDxe] direct MMIO register access + +The top three drivers produce standard UEFI abstractions: the Block IO +Protocol, the Extended SCSI Pass Thru Protocol, and the Simple Network +Protocol, for virtio-block, virtio-scsi, and virtio-net devices, respectively. + +Comparing these device-specific virtio drivers to each other, we can determine: + +- They all conform to the UEFI Driver Model. This means that their entry point + functions don't immediately start to search for devices and to drive them, + they only register instances of the EFI_DRIVER_BINDING_PROTOCOL. The UEFI + Driver Model then enumerates devices and chains matching drivers + automatically. + +- They are as minimal as possible, while remaining correct (refer to source + code comments for details). For example, VirtioBlkDxe and VirtioScsiDxe both + support only one request in flight. + + In theory, VirtioBlkDxe could implement EFI_BLOCK_IO2_PROTOCOL, which allows + queueing. Similarly, VirtioScsiDxe does not support the non-blocking mode of + EFI_EXT_SCSI_PASS_THRU_PROTOCOL.PassThru(). (Which is permitted by the UEFI + specification.) Both VirtioBlkDxe and VirtioScsiDxe delegate synchronous + request handling to "OvmfPkg/Library/VirtioLib". This limitation helps keep + the implementation simple, and testing thus far seems to imply satisfactory + performance, for a virtual boot firmware. + + VirtioNetDxe cannot avoid queueing, because EFI_SIMPLE_NETWORK_PROTOCOL + requires it on the interface level. Consequently, VirtioNetDxe is + significantly more complex than VirtioBlkDxe and VirtioScsiDxe. Technical + notes are provided in "OvmfPkg/VirtioNetDxe/TechNotes.txt". + +- None of these drivers access hardware directly. Instead, the Virtio Device + Protocol (OvmfPkg/Include/Protocol/VirtioDevice.h) collects / extracts virtio + operations defined in the Virtio Specification, and these backend-independent + virtio device drivers go through the abstract VIRTIO_DEVICE_PROTOCOL. + + IMPORTANT: the VIRTIO_DEVICE_PROTOCOL is not a standard UEFI protocol. It is + internal to edk2 and not described in the UEFI specification. It should only + be used by drivers and applications that live inside the edk2 source tree. + +Currently two providers exist for VIRTIO_DEVICE_PROTOCOL: + +- The first one is the "more traditional" virtio-pci backend, implemented by + OvmfPkg/VirtioPciDeviceDxe. This driver also complies with the UEFI Driver + Model. It consumes an instance of the EFI_PCI_IO_PROTOCOL, and, if the PCI + device/function under probing appears to be a virtio device, it produces a + Virtio Device Protocol instance for it. The driver translates abstract virtio + operations to PCI accesses. + +- The second provider, the virtio-mmio backend, is a library, not a driver, + living in OvmfPkg/Library/VirtioMmioDeviceLib. This library translates + abstract virtio operations to MMIO accesses. + + The virtio-mmio backend is only a library -- rather than a standalone, UEFI + Driver Model-compliant driver -- because the type of resource it consumes, an + MMIO register block base address, is not enumerable. + + In other words, while the PCI root bridge driver and the PCI bus driver + produce instances of EFI_PCI_IO_PROTOCOL automatically, thereby enabling the + UEFI Driver Model to probe devices and stack up drivers automatically, no + such enumeration exists for MMIO register blocks. + + For this reason, VirtioMmioDeviceLib needs to be linked into thin, custom + platform drivers that dispose over this kind of information. As soon as a + driver knows about the MMIO register block base addresses, it can pass each + to the library, and then the VIRTIO_DEVICE_PROTOCOL will be instantiated + (assuming a valid virtio-mmio register block of course). From that point on + the UEFI Driver Model again takes care of the chaining. + + Typically, such a custom driver does not conform to the UEFI Driver Model + (because that would presuppose auto-enumeration for MMIO register blocks). + Hence it has the following responsibilities: + + - it shall behave as a "wrapper" UEFI driver around the library, + + - it shall know virtio-mmio base addresses, + + - in its entry point function, it shall create a new UEFI handle with an + instance of the EFI_DEVICE_PATH_PROTOCOL for each virtio-mmio device it + knows the base address for, + + - it shall call VirtioMmioInstallDevice() on those handles, with the + corresponding base addresses. + + OVMF itself does not employ VirtioMmioDeviceLib. However, the library is used + (or has been tested as Proof-of-Concept) in the following 64-bit and 32-bit + ARM emulator setups: + + - in "RTSM_VE_FOUNDATIONV8_EFI.fd" and "FVP_AARCH64_EFI.fd", on ARM Holdings' + ARM(R) v8-A Foundation Model and ARM(R) AEMv8-A Base Platform FVP + emulators, respectively: + + EFI_BLOCK_IO_PROTOCOL + [OvmfPkg/VirtioBlkDxe] + | + VIRTIO_DEVICE_PROTOCOL + [ArmPlatformPkg/ArmVExpressPkg/ArmVExpressDxe/ArmFvpDxe.inf] + | + [OvmfPkg/Library/VirtioMmioDeviceLib] + direct MMIO register access + + - in "RTSM_VE_CORTEX-A15_EFI.fd" and "RTSM_VE_CORTEX-A15_MPCORE_EFI.fd", on + "qemu-system-arm -M vexpress-a15": + + EFI_BLOCK_IO_PROTOCOL EFI_SIMPLE_NETWORK_PROTOCOL + [OvmfPkg/VirtioBlkDxe] [OvmfPkg/VirtioNetDxe] + | | + +------------------+---------------+ + | + VIRTIO_DEVICE_PROTOCOL + [ArmPlatformPkg/ArmVExpressPkg/ArmVExpressDxe/ArmFvpDxe.inf] + | + [OvmfPkg/Library/VirtioMmioDeviceLib] + direct MMIO register access + + In the above ARM / VirtioMmioDeviceLib configurations, VirtioBlkDxe was + tested with booting Linux distributions, while VirtioNetDxe was tested with + pinging public IPv4 addresses from the UEFI shell. + +Platform Driver +............... + +Sometimes, elements of persistent firmware configuration are best exposed to +the user in a friendly way. OVMF's platform driver (OvmfPkg/PlatformDxe) +presents such settings on the "OVMF Platform Configuration" dialog: + +- Press ESC on the TianoCore splash screen, +- Navigate to Device Manager | OVMF Platform Configuration. + +At the moment, OVMF's platform driver handles only one setting: the preferred +graphics resolution. This is useful for two purposes: + +- Some UEFI shell commands, like DRIVERS and DEVICES, benefit from a wide + display. Using the MODE shell command, the user can switch to a larger text + resolution (limited by the graphics resolution), and see the command output + in a more easily consumable way. + + [RHEL] The list of text modes available to the MODE command is also limited + by ConSplitterDxe (found under MdeModulePkg/Universal/Console). + ConSplitterDxe builds an intersection of text modes that are + simultaneously supported by all consoles that ConSplitterDxe + multiplexes console output to. + + In practice, the strongest text mode restriction comes from + TerminalDxe, which provides console I/O on serial ports. TerminalDxe + has a very limited built-in list of text modes, heavily pruning the + intersection built by ConSplitterDxe, and made available to the MODE + command. + + On the Red Hat Enterprise Linux 7.1 host, TerminalDxe's list of modes + has been extended with text resolutions that match the Spice QXL GPU's + common graphics resolutions. This way a "full screen" text mode should + always be available in the MODE command. + +- The other advantage of controlling the graphics resolution lies with UEFI + operating systems that don't (yet) have a native driver for QEMU's virtual + video cards -- eg. the Spice QXL GPU. Such OSes may choose to inherit the + properties of OVMF's EFI_GRAPHICS_OUTPUT_PROTOCOL (provided by + OvmfPkg/QemuVideoDxe, see later). + + Although the display can be used at runtime in such cases, by direct + framebuffer access, its properties, for example, the resolution, cannot be + modified. The platform driver allows the user to select the preferred GOP + resolution, reboot, and let the guest OS inherit that preferred resolution. + +The platform driver has three access points: the "normal" driver entry point, a +set of HII callbacks, and a GOP installation callback. + +(1) Driver entry point: the PlatformInit() function. + + (a) First, this function loads any available settings, and makes them take + effect. For the preferred graphics resolution in particular, this means + setting the following PCDs: + + gEfiMdeModulePkgTokenSpaceGuid.PcdVideoHorizontalResolution + gEfiMdeModulePkgTokenSpaceGuid.PcdVideoVerticalResolution + + These PCDs influence the GraphicsConsoleDxe driver (located under + MdeModulePkg/Universal/Console), which switches to the preferred + graphics mode, and produces EFI_SIMPLE_TEXT_OUTPUT_PROTOCOLs on GOPs: + + EFI_SIMPLE_TEXT_OUTPUT_PROTOCOL + [MdeModulePkg/Universal/Console/GraphicsConsoleDxe] + | + EFI_GRAPHICS_OUTPUT_PROTOCOL + [OvmfPkg/QemuVideoDxe] + | + EFI_PCI_IO_PROTOCOL + [MdeModulePkg/Bus/Pci/PciBusDxe] + + (b) Second, the driver entry point registers the user interface, including + HII callbacks. + + (c) Third, the driver entry point registers a GOP installation callback. + +(2) HII callbacks and the user interface. + + The Human Interface Infrastructure (HII) "is a set of protocols that allow + a UEFI driver to provide the ability to register user interface and + configuration content with the platform firmware". + + OVMF's platform driver: + + - provides a static, basic, visual form (PlatformForms.vfr), written in the + Visual Forms Representation language, + + - includes a UCS-16 encoded message catalog (Platform.uni), + + - includes source code that dynamically populates parts of the form, with + the help of MdeModulePkg/Library/UefiHiiLib -- this library simplifies + the handling of IFR (Internal Forms Representation) opcodes, + + - processes form actions that the user takes (Callback() function), + + - loads and saves platform configuration in a private, non-volatile + variable (ExtractConfig() and RouteConfig() functions). + + The ExtractConfig() HII callback implements the following stack of + conversions, for loading configuration and presenting it to the user: + + MultiConfigAltResp -- form engine / HII communication + ^ + | + [BlockToConfig] + | + MAIN_FORM_STATE -- binary representation of form/widget + ^ state + | + [PlatformConfigToFormState] + | + PLATFORM_CONFIG -- accessible to DXE and UEFI drivers + ^ + | + [PlatformConfigLoad] + | + UEFI non-volatile variable -- accessible to external utilities + + The layers are very similar for the reverse direction, ie. when taking + input from the user, and saving the configuration (RouteConfig() HII + callback): + + ConfigResp -- form engine / HII communication + | + [ConfigToBlock] + | + v + MAIN_FORM_STATE -- binary representation of form/widget + | state + [FormStateToPlatformConfig] + | + v + PLATFORM_CONFIG -- accessible to DXE and UEFI drivers + | + [PlatformConfigSave] + | + v + UEFI non-volatile variable -- accessible to external utilities + +(3) When the platform driver starts, a GOP may not be available yet. Thus the + driver entry point registers a callback (the GopInstalled() function) for + GOP installations. + + When the first GOP is produced (usually by QemuVideoDxe, or potentially by + a third party video driver), PlatformDxe retrieves the list of graphics + modes the GOP supports, and dynamically populates the drop-down list of + available resolutions on the form. The GOP installation callback is then + removed. + +Video driver +............ + +OvmfPkg/QemuVideoDxe is OVMF's built-in video driver. We can divide its +services in two parts: graphics output protocol (primary), and Int10h (VBE) +shim (secondary). + +(1) QemuVideoDxe conforms to the UEFI Driver Model; it produces an instance of + the EFI_GRAPHICS_OUTPUT_PROTOCOL (GOP) on each PCI display that it supports + and is connected to: + + EFI_GRAPHICS_OUTPUT_PROTOCOL + [OvmfPkg/QemuVideoDxe] + | + EFI_PCI_IO_PROTOCOL + [MdeModulePkg/Bus/Pci/PciBusDxe] + + It supports the following QEMU video cards: + + - Cirrus 5430 ("-device cirrus-vga"), + - Standard VGA ("-device VGA"), + - QXL VGA ("-device qxl-vga", "-device qxl"). + + For Cirrus the following resolutions and color depths are available: + 640x480x32, 800x600x32, 1024x768x24. On stdvga and QXL a long list of + resolutions is available. The list is filtered against the frame buffer + size during initialization. + + The size of the QXL VGA compatibility framebuffer can be changed with the + + -device qxl-vga,vgamem_mb=$NUM_MB + + QEMU option. If $NUM_MB exceeds 32, then the following is necessary + instead: + + -device qxl-vga,vgamem_mb=$NUM_MB,ram_size_mb=$((NUM_MB*2)) + + because the compatibility framebuffer can't cover more than half of PCI BAR + #0. The latter defaults to 64MB in size, and is controlled by the + "ram_size_mb" property. + +(2) When QemuVideoDxe binds the first Standard VGA or QXL VGA device, and there + is no real VGA BIOS present in the C to F segments (which could originate + from a legacy PCI option ROM -- refer to "Compatibility Support Module + (CSM)"), then QemuVideoDxe installs a minimal, "fake" VGA BIOS -- an Int10h + (VBE) "shim". + + The shim is implemented in 16-bit assembly in + "OvmfPkg/QemuVideoDxe/VbeShim.asm". The "VbeShim.sh" shell script assembles + it and formats it as a C array ("VbeShim.h") with the help of the "nasm" + utility. The driver's InstallVbeShim() function copies the shim in place + (the C segment), and fills in the VBE Info and VBE Mode Info structures. + The real-mode 10h interrupt vector is pointed to the shim's handler. + + The shim is (correctly) irrelevant and invisible for all UEFI operating + systems we know about -- except Windows Server 2008 R2 and other Windows + operating systems in that family. + + Namely, the Windows 2008 R2 SP1 (and Windows 7) UEFI guest's default video + driver dereferences the real mode Int10h vector, loads the pointed-to + handler code, and executes what it thinks to be VGA BIOS services in an + internal real-mode emulator. Consequently, video mode switching used not to + work in Windows 2008 R2 SP1 when it ran on the "pure UEFI" build of OVMF, + making the guest uninstallable. Hence the (otherwise optional, non-default) + Compatibility Support Module (CSM) ended up a requirement for running such + guests. + + The hard dependency on the sophisticated SeaBIOS CSM and the complex + supporting edk2 infrastructure, for enabling this family of guests, was + considered suboptimal by some members of the upstream community, + + [RHEL] and was certainly considered a serious maintenance disadvantage for + Red Hat Enterprise Linux 7.1 hosts. + + Thus, the shim has been collaboratively developed for the Windows 7 / + Windows Server 2008 R2 family. The shim provides a real stdvga / QXL + implementation for the few services that are in fact necessary for the + Windows 2008 R2 SP1 (and Windows 7) UEFI guest, plus some "fakes" that the + guest invokes but whose effect is not important. The only supported mode is + 1024x768x32, which is enough to install the guest and then upgrade its + video driver to the full-featured QXL XDDM one. + + The C segment is not present in the UEFI memory map prepared by OVMF. + Memory space that would cover it is never added (either in PEI, in the form + of memory resource descriptor HOBs, or in DXE, via gDS->AddMemorySpace()). + This way the handler body is invisible to all other UEFI guests, and the + rest of edk2. + + The Int10h real-mode IVT entry is covered with a Boot Services Code page, + making that too inaccessible to the rest of edk2. Due to the allocation + type, UEFI guest OSes different from the Windows Server 2008 family can + reclaim the page at zero. (The Windows 2008 family accesses that page + regardless of the allocation type.) + +Afterword +--------- + +After the bulk of this document was written in July 2014, OVMF development has +not stopped. To name two significant code contributions from the community: in +January 2015, OVMF runs on the "q35" machine type of QEMU, and it features a +driver for Xen paravirtual block devices (and another for the underlying Xen +bus). + +Furthermore, a dedicated virtualization platform has been contributed to +ArmPlatformPkg that plays a role parallel to OvmfPkg's. It targets the "virt" +machine type of qemu-system-arm and qemu-system-aarch64. Parts of OvmfPkg are +being refactored and modularized so they can be reused in +"ArmPlatformPkg/ArmVirtualizationPkg/ArmVirtualizationQemu.dsc".