X-Git-Url: https://git.proxmox.com/?p=mirror_edk2.git;a=blobdiff_plain;f=OvmfPkg%2FREADME;h=7415419d2dd7befae31da17082a68312d82c0afd;hp=213d8648d6bd9f4e6ade68cb832c7563662c0121;hb=f33d5d68abc02727dc828c1079e72ab65e1d63af;hpb=7a1f59476d40348429575b26b5612b219ddb83e2 diff --git a/OvmfPkg/README b/OvmfPkg/README index 213d8648d6..7415419d2d 100644 --- a/OvmfPkg/README +++ b/OvmfPkg/README @@ -5,12 +5,10 @@ The Open Virtual Machine Firmware (OVMF) project aims to support firmware for Virtual Machines using the edk2 code base. More information can be found at: -http://sourceforge.net/apps/mediawiki/tianocore/index.php?title=OVMF +http://www.tianocore.org/ovmf/ === STATUS === -Current status: Alpha - Current capabilities: * IA32 and X64 architectures * QEMU (0.10.0 or later) @@ -19,10 +17,10 @@ Current capabilities: - Optional NIC support. Requires QEMU (0.12.2 or later) * UEFI Linux boots * UEFI Windows 8 boots +* UEFI Windows 7 & Windows 2008 Server boot (see important notes below!) === FUTURE PLANS === -* Stabilize UEFI Linux boot * Test/Stabilize UEFI Self-Certification Tests (SCT) results === BUILDING OVMF === @@ -32,6 +30,7 @@ Pre-requisites: * A properly configured ASL compiler: - Intel ASL compiler: Available from http://www.acpica.org - Microsoft ASL compiler: Available from http://www.acpi.info +* NASM: http://www.nasm.us/ Update Conf/target.txt ACTIVE_PLATFORM for OVMF: PEI arch DXE arch UEFI interfaces @@ -56,16 +55,29 @@ these binary outputs: More information on building OVMF can be found at: -http://sourceforge.net/apps/mediawiki/tianocore/index.php?title=How_to_build_OVMF +https://github.com/tianocore/tianocore.github.io/wiki/How%20to%20build%20OVMF === RUNNING OVMF on QEMU === -* QEMU 0.9.1 or later is required. -* Either copy, rename or symlink OVMF.FD => bios.bin +* QEMU 0.12.2 or later is required. * Be sure to use qemu-system-x86_64, if you are using and X64 firmware. (qemu-system-x86_64 works for the IA32 firmware as well, of course.) -* Use the QEMU -L parameter to specify the directory where the bios.bin - file is located. +* Use OVMF for QEMU firmware (3 options available) + - Option 1: QEMU 1.6 or newer; Use QEMU -pflash parameter + * QEMU/OVMF will use emulated flash, and fully support UEFI variables + * Run qemu with: -pflash path/to/OVMF.fd + * Note that this option is required for running SecureBoot-enabled builds + (-D SECURE_BOOT_ENABLE). + - Option 2: Use QEMU -bios parameter + * Note that UEFI variables will be partially emulated, and non-volatile + variables may lose their contents after a reboot + * Run qemu with: -bios path/to/OVMF.fd + - Option 3: Use QEMU -L parameter + * Note that UEFI variables will be partially emulated, and non-volatile + variables may lose their contents after a reboot + * Either copy, rename or symlink OVMF.fd => bios.bin + * Use the QEMU -L parameter to specify the directory where the bios.bin + file is located. * The EFI shell is built into OVMF builds at this time, so it should run automatically if a UEFI boot application is not found on the removable media. @@ -106,6 +118,58 @@ $ OvmfPkg/build.sh -a X64 qemu -cdrom /path/to/disk-image.iso To build a 32-bit OVMF without debug messages using GCC 4.5: $ OvmfPkg/build.sh -a IA32 -b RELEASE -t GCC45 +=== SMM support === + +Requirements: +* SMM support requires QEMU 2.5. +* The minimum required QEMU machine type is "pc-q35-2.5". +* SMM with KVM requires Linux 4.4 (host). + +OVMF is capable of utilizing SMM if the underlying QEMU or KVM hypervisor +emulates SMM. SMM is put to use in the S3 suspend and resume infrastructure, +and in the UEFI variable driver stack. The purpose is (virtual) hardware +separation between the runtime guest OS and the firmware (OVMF), with the +intent to make Secure Boot actually secure, by preventing the runtime guest OS +from tampering with the variable store and S3 areas. + +For SMM support, OVMF must be built with the "-D SMM_REQUIRE" option. The +resultant firmware binary will check if QEMU actually provides SMM emulation; +if it doesn't, then OVMF will log an error and trigger an assertion failure +during boot (even in RELEASE builds). Both the naming of the flag (SMM_REQUIRE, +instead of SMM_ENABLE), and this behavior are consistent with the goal +described above: this is supposed to be a security feature, and fallbacks are +not allowed. Similarly, a pflash-backed variable store is a requirement. + +QEMU should be started with the options listed below (in addition to any other +guest-specific flags). The command line should be gradually composed from the +hints below. '\' is used to extend the command line to multiple lines, and '^' +can be used on Windows. + +* QEMU binary and options specific to 32-bit guests: + + $ qemu-system-i386 -cpu coreduo,-nx \ + + or + + $ qemu-system-x86_64 -cpu ,-lm,-nx \ + +* QEMU binary for running 64-bit guests (no particular options): + + $ qemu-system-x86_64 \ + +* Flags common to all SMM scenarios (only the Q35 machine type is supported): + + -machine q35,smm=on,accel=(tcg|kvm) \ + -m ... \ + -smp ... \ + -global driver=cfi.pflash01,property=secure,value=on \ + -drive if=pflash,format=raw,unit=0,file=OVMF_CODE.fd,readonly=on \ + -drive if=pflash,format=raw,unit=1,file=copy_of_OVMF_VARS.fd \ + +* In order to disable S3, add: + + -global ICH9-LPC.disable_s3=1 \ + === Network Support === OVMF provides a UEFI network stack by default. Its lowest level driver is the @@ -160,24 +224,183 @@ longer.) basic virtio-net driver, located in OvmfPkg/VirtioNetDxe. * Also independently of the iPXE NIC drivers, Intel's proprietary E1000 NIC - driver (PROEFI) can be embedded in the OVMF image at build time: - - - Download UEFI drivers for the e1000 NIC - - http://downloadcenter.intel.com/Detail_Desc.aspx?agr=Y&DwnldID=17515&lang=eng - - Install the drivers into a directory called Intel3.5 in your WORKSPACE. + driver (from the BootUtil distribution) can be embedded in the OVMF image at + build time: + + - Download BootUtil: + - Navigate to + https://downloadcenter.intel.com/download/19186/Ethernet-Intel-Ethernet-Connections-Boot-Utility-Preboot-Images-and-EFI-Drivers + - Click the download link for "PREBOOT.EXE". + - Accept the Intel Software License Agreement that appears. + - Unzip "PREBOOT.EXE" into a separate directory (this works with the + "unzip" utility on platforms different from Windows as well). + - Copy the "APPS/EFI/EFIx64/E3522X2.EFI" driver binary to + "Intel3.5/EFIX64/E3522X2.EFI" in your WORKSPACE. + - Intel have stopped distributing an IA32 driver binary (which used to + match the filename pattern "E35??E2.EFI"), thus this method will only + work for the IA32X64 and X64 builds of OVMF. - Include the driver in OVMF during the build: - - Add "-D E1000_ENABLE -D FD_SIZE_2MB" to your build command, - - For example: "build -D E1000_ENABLE -D FD_SIZE_2MB". + - Add "-D E1000_ENABLE" to your build command (only when building + "OvmfPkg/OvmfPkgIa32X64.dsc" or "OvmfPkg/OvmfPkgX64.dsc"). + - For example: "build -D E1000_ENABLE". * When a matching iPXE driver is configured for a NIC as described above, it takes priority over other drivers that could possibly drive the card too: - | e1000 ne2k_pci pcnet rtl8139 virtio-net-pci - -------------+------------------------------------------------ - iPXE | x x x x x - VirtioNetDxe | x - Intel PROEFI | x + | e1000 ne2k_pci pcnet rtl8139 virtio-net-pci + ---------------------+------------------------------------------------ + iPXE | x x x x x + VirtioNetDxe | x + Intel BootUtil (X64) | x + +=== HTTPS Boot === + +HTTPS Boot is an alternative solution to PXE. It replaces the tftp server +with a HTTPS server so the firmware can download the images through a trusted +and encrypted connection. + +* To enable HTTPS Boot, you have to build OVMF with -D HTTP_BOOT_ENABLE and + -D TLS_ENABLE. The former brings in the HTTP stack from NetworkPkg while + the latter enables TLS support in both NetworkPkg and CryptoPkg. + +* By default, there is no trusted certificate. The user has to import the + certificates either manually with "Tls Auth Configuration" utility in the + firmware UI or through the fw_cfg entry, etc/edk2/https/cacerts. + + -fw_cfg name=etc/edk2/https/cacerts,file= + + The blob for etc/edk2/https/cacerts has to be in the format of Signature + Database(*1). You can use p11-kit(*2) or efisiglit(*3) to create the + certificate list. + + If you want to create the certificate list based on the CA certificates + in your local host, p11-kit will be a good choice. Here is the command to + create the list: + + p11-kit extract --format=edk2-cacerts --filter=ca-anchors \ + --overwrite --purpose=server-auth + + If you only want to import one certificate, efisiglist is the tool for you: + + efisiglist -a -o + + Please note that the certificate has to be in the DER format. + + You can also append a certificate to the existing list with the following + command: + + efisiglist -i -a -o + + NOTE: You may need the patch to make efisiglist generate the correct header. + (https://github.com/rhboot/pesign/pull/40) + +* Besides the trusted certificates, it's also possible to configure the trusted + cipher suites for HTTPS through another fw_cfg entry: etc/edk2/https/ciphers. + + -fw_cfg name=etc/edk2/https/ciphers,file= + + OVMF expects a binary UINT16 array which comprises the cipher suites HEX + IDs(*4). If the cipher suite list is given, OVMF will choose the cipher + suite from the intersection of the given list and the built-in cipher + suites. Otherwise, OVMF just chooses whatever proper cipher suites from the + built-in ones. + + While the tool(*5) to create the cipher suite array is still under + development, the array can be generated with the following script: + + export LC_ALL=C + openssl ciphers -V \ + | sed -r -n \ + -e 's/^ *0x([0-9A-F]{2}),0x([0-9A-F]{2}) - .*$/\\\\x\1 \\\\x\2/p' \ + | xargs -r -- printf -- '%b' > ciphers.bin + + This script creates ciphers.bin that contains all the cipher suite IDs + supported by openssl according to the local host configuration. + + You may want to enable only a limited set of cipher suites. Then, you + should check the validity of your list first: + + openssl ciphers -V + + If all the cipher suites in your list map to the proper HEX IDs, go ahead + to modify the script and execute it: + + export LC_ALL=C + openssl ciphers -V \ + | sed -r -n \ + -e 's/^ *0x([0-9A-F]{2}),0x([0-9A-F]{2}) - .*$/\\\\x\1 \\\\x\2/p' \ + | xargs -r -- printf -- '%b' > ciphers.bin + +* In the future (after release 2.12), QEMU should populate both above fw_cfg + files automatically from the local host configuration, and enable the user + to override either with dedicated options or properties. + +(*1) See "31.4.1 Signature Database" in UEFI specification 2.7 errata A. +(*2) p11-kit: https://github.com/p11-glue/p11-kit/ +(*3) efisiglist: https://github.com/rhboot/pesign/blob/master/src/efisiglist.c +(*4) https://wiki.mozilla.org/Security/Server_Side_TLS#Cipher_names_correspondence_table +(*5) update-crypto-policies: https://gitlab.com/redhat-crypto/fedora-crypto-policies + +=== OVMF Flash Layout === + +Like all current IA32/X64 system designs, OVMF's firmware device (rom/flash) +appears in QEMU's physical address space just below 4GB (0x100000000). + +OVMF supports building a 1MB, 2MB or 4MB flash image (see the DSC files for the +FD_SIZE_1MB, FD_SIZE_2MB, FD_SIZE_4MB build defines). The base address for the +1MB image in QEMU physical memory is 0xfff00000. The base address for the 2MB +image is 0xffe00000. The base address for the 4MB image is 0xffc00000. + +Using the 1MB or 2MB image, the layout of the firmware device in memory looks +like: + ++--------------------------------------- 4GB (0x100000000) +| VTF0 (16-bit reset code) and OVMF SEC +| (SECFV, 208KB/0x34000) ++--------------------------------------- varies based on flash size +| +| Compressed main firmware image +| (FVMAIN_COMPACT) +| ++--------------------------------------- base + 0x20000 +| Fault-tolerant write (FTW) +| Spare blocks (64KB/0x10000) ++--------------------------------------- base + 0x10000 +| FTW Work block (4KB/0x1000) ++--------------------------------------- base + 0x0f000 +| Event log area (4KB/0x1000) ++--------------------------------------- base + 0x0e000 +| Non-volatile variable storage +| area (56KB/0xe000) ++--------------------------------------- base address + +Using the 4MB image, the layout of the firmware device in memory looks like: + ++--------------------------------------- base + 0x400000 (4GB/0x100000000) +| VTF0 (16-bit reset code) and OVMF SEC +| (SECFV, 208KB/0x34000) ++--------------------------------------- base + 0x3cc000 +| +| Compressed main firmware image +| (FVMAIN_COMPACT, 3360KB/0x348000) +| ++--------------------------------------- base + 0x84000 +| Fault-tolerant write (FTW) +| Spare blocks (264KB/0x42000) ++--------------------------------------- base + 0x42000 +| FTW Work block (4KB/0x1000) ++--------------------------------------- base + 0x41000 +| Event log area (4KB/0x1000) ++--------------------------------------- base + 0x40000 +| Non-volatile variable storage +| area (256KB/0x40000) ++--------------------------------------- base address (0xffc00000) + +The code in SECFV locates FVMAIN_COMPACT, and decompresses the +main firmware (MAINFV) into RAM memory at address 0x800000. The +remaining OVMF firmware then uses this decompressed firmware +volume image. === UNIXGCC Debug === @@ -189,12 +412,22 @@ If you must use UNIXGCC, then you can override the build options for particular libraries and modules in the .dsc to re-enable debugging selectively. For example: [Components] - OvmfPkg/Library/PlatformBdsLib/PlatformBdsLib.inf { + OvmfPkg/Library/PlatformBootManagerLib/PlatformBootManagerLib.inf { GCC:*_*_*_CC_FLAGS = -UMDEPKG_NDEBUG } - IntelFrameworkModulePkg/Universal/BdsDxe/BdsDxe.inf { + MdeModulePkg/Universal/BdsDxe/BdsDxe.inf { GCC:*_*_*_CC_FLAGS = -UMDEPKG_NDEBUG } +=== UEFI Windows 7 & Windows 2008 Server === + +* One of the '-vga std' and '-vga qxl' QEMU options should be used. +* Only one video mode, 1024x768x32, is supported at OS runtime. +* The '-vga qxl' QEMU option is recommended. After booting the installed + guest OS, select the video card in Device Manager, and upgrade its driver + to the QXL XDDM one. Download location: + , Guest | Windows binaries. + This enables further resolutions at OS runtime, and provides S3 + (suspend/resume) capability.