Kyle Swenson | 8d8f654 | 2021-03-15 11:02:55 -0600 | [diff] [blame] | 1 | Intel(R) TXT Overview: |
| 2 | ===================== |
| 3 | |
| 4 | Intel's technology for safer computing, Intel(R) Trusted Execution |
| 5 | Technology (Intel(R) TXT), defines platform-level enhancements that |
| 6 | provide the building blocks for creating trusted platforms. |
| 7 | |
| 8 | Intel TXT was formerly known by the code name LaGrande Technology (LT). |
| 9 | |
| 10 | Intel TXT in Brief: |
| 11 | o Provides dynamic root of trust for measurement (DRTM) |
| 12 | o Data protection in case of improper shutdown |
| 13 | o Measurement and verification of launched environment |
| 14 | |
| 15 | Intel TXT is part of the vPro(TM) brand and is also available some |
| 16 | non-vPro systems. It is currently available on desktop systems |
| 17 | based on the Q35, X38, Q45, and Q43 Express chipsets (e.g. Dell |
| 18 | Optiplex 755, HP dc7800, etc.) and mobile systems based on the GM45, |
| 19 | PM45, and GS45 Express chipsets. |
| 20 | |
| 21 | For more information, see http://www.intel.com/technology/security/. |
| 22 | This site also has a link to the Intel TXT MLE Developers Manual, |
| 23 | which has been updated for the new released platforms. |
| 24 | |
| 25 | Intel TXT has been presented at various events over the past few |
| 26 | years, some of which are: |
| 27 | LinuxTAG 2008: |
| 28 | http://www.linuxtag.org/2008/en/conf/events/vp-donnerstag.html |
| 29 | TRUST2008: |
| 30 | http://www.trust-conference.eu/downloads/Keynote-Speakers/ |
| 31 | 3_David-Grawrock_The-Front-Door-of-Trusted-Computing.pdf |
| 32 | IDF, Shanghai: |
| 33 | http://www.prcidf.com.cn/index_en.html |
| 34 | IDFs 2006, 2007 (I'm not sure if/where they are online) |
| 35 | |
| 36 | Trusted Boot Project Overview: |
| 37 | ============================= |
| 38 | |
| 39 | Trusted Boot (tboot) is an open source, pre-kernel/VMM module that |
| 40 | uses Intel TXT to perform a measured and verified launch of an OS |
| 41 | kernel/VMM. |
| 42 | |
| 43 | It is hosted on SourceForge at http://sourceforge.net/projects/tboot. |
| 44 | The mercurial source repo is available at http://www.bughost.org/ |
| 45 | repos.hg/tboot.hg. |
| 46 | |
| 47 | Tboot currently supports launching Xen (open source VMM/hypervisor |
| 48 | w/ TXT support since v3.2), and now Linux kernels. |
| 49 | |
| 50 | |
| 51 | Value Proposition for Linux or "Why should you care?" |
| 52 | ===================================================== |
| 53 | |
| 54 | While there are many products and technologies that attempt to |
| 55 | measure or protect the integrity of a running kernel, they all |
| 56 | assume the kernel is "good" to begin with. The Integrity |
| 57 | Measurement Architecture (IMA) and Linux Integrity Module interface |
| 58 | are examples of such solutions. |
| 59 | |
| 60 | To get trust in the initial kernel without using Intel TXT, a |
| 61 | static root of trust must be used. This bases trust in BIOS |
| 62 | starting at system reset and requires measurement of all code |
| 63 | executed between system reset through the completion of the kernel |
| 64 | boot as well as data objects used by that code. In the case of a |
| 65 | Linux kernel, this means all of BIOS, any option ROMs, the |
| 66 | bootloader and the boot config. In practice, this is a lot of |
| 67 | code/data, much of which is subject to change from boot to boot |
| 68 | (e.g. changing NICs may change option ROMs). Without reference |
| 69 | hashes, these measurement changes are difficult to assess or |
| 70 | confirm as benign. This process also does not provide DMA |
| 71 | protection, memory configuration/alias checks and locks, crash |
| 72 | protection, or policy support. |
| 73 | |
| 74 | By using the hardware-based root of trust that Intel TXT provides, |
| 75 | many of these issues can be mitigated. Specifically: many |
| 76 | pre-launch components can be removed from the trust chain, DMA |
| 77 | protection is provided to all launched components, a large number |
| 78 | of platform configuration checks are performed and values locked, |
| 79 | protection is provided for any data in the event of an improper |
| 80 | shutdown, and there is support for policy-based execution/verification. |
| 81 | This provides a more stable measurement and a higher assurance of |
| 82 | system configuration and initial state than would be otherwise |
| 83 | possible. Since the tboot project is open source, source code for |
| 84 | almost all parts of the trust chain is available (excepting SMM and |
| 85 | Intel-provided firmware). |
| 86 | |
| 87 | How Does it Work? |
| 88 | ================= |
| 89 | |
| 90 | o Tboot is an executable that is launched by the bootloader as |
| 91 | the "kernel" (the binary the bootloader executes). |
| 92 | o It performs all of the work necessary to determine if the |
| 93 | platform supports Intel TXT and, if so, executes the GETSEC[SENTER] |
| 94 | processor instruction that initiates the dynamic root of trust. |
| 95 | - If tboot determines that the system does not support Intel TXT |
| 96 | or is not configured correctly (e.g. the SINIT AC Module was |
| 97 | incorrect), it will directly launch the kernel with no changes |
| 98 | to any state. |
| 99 | - Tboot will output various information about its progress to the |
| 100 | terminal, serial port, and/or an in-memory log; the output |
| 101 | locations can be configured with a command line switch. |
| 102 | o The GETSEC[SENTER] instruction will return control to tboot and |
| 103 | tboot then verifies certain aspects of the environment (e.g. TPM NV |
| 104 | lock, e820 table does not have invalid entries, etc.). |
| 105 | o It will wake the APs from the special sleep state the GETSEC[SENTER] |
| 106 | instruction had put them in and place them into a wait-for-SIPI |
| 107 | state. |
| 108 | - Because the processors will not respond to an INIT or SIPI when |
| 109 | in the TXT environment, it is necessary to create a small VT-x |
| 110 | guest for the APs. When they run in this guest, they will |
| 111 | simply wait for the INIT-SIPI-SIPI sequence, which will cause |
| 112 | VMEXITs, and then disable VT and jump to the SIPI vector. This |
| 113 | approach seemed like a better choice than having to insert |
| 114 | special code into the kernel's MP wakeup sequence. |
| 115 | o Tboot then applies an (optional) user-defined launch policy to |
| 116 | verify the kernel and initrd. |
| 117 | - This policy is rooted in TPM NV and is described in the tboot |
| 118 | project. The tboot project also contains code for tools to |
| 119 | create and provision the policy. |
| 120 | - Policies are completely under user control and if not present |
| 121 | then any kernel will be launched. |
| 122 | - Policy action is flexible and can include halting on failures |
| 123 | or simply logging them and continuing. |
| 124 | o Tboot adjusts the e820 table provided by the bootloader to reserve |
| 125 | its own location in memory as well as to reserve certain other |
| 126 | TXT-related regions. |
| 127 | o As part of its launch, tboot DMA protects all of RAM (using the |
| 128 | VT-d PMRs). Thus, the kernel must be booted with 'intel_iommu=on' |
| 129 | in order to remove this blanket protection and use VT-d's |
| 130 | page-level protection. |
| 131 | o Tboot will populate a shared page with some data about itself and |
| 132 | pass this to the Linux kernel as it transfers control. |
| 133 | - The location of the shared page is passed via the boot_params |
| 134 | struct as a physical address. |
| 135 | o The kernel will look for the tboot shared page address and, if it |
| 136 | exists, map it. |
| 137 | o As one of the checks/protections provided by TXT, it makes a copy |
| 138 | of the VT-d DMARs in a DMA-protected region of memory and verifies |
| 139 | them for correctness. The VT-d code will detect if the kernel was |
| 140 | launched with tboot and use this copy instead of the one in the |
| 141 | ACPI table. |
| 142 | o At this point, tboot and TXT are out of the picture until a |
| 143 | shutdown (S<n>) |
| 144 | o In order to put a system into any of the sleep states after a TXT |
| 145 | launch, TXT must first be exited. This is to prevent attacks that |
| 146 | attempt to crash the system to gain control on reboot and steal |
| 147 | data left in memory. |
| 148 | - The kernel will perform all of its sleep preparation and |
| 149 | populate the shared page with the ACPI data needed to put the |
| 150 | platform in the desired sleep state. |
| 151 | - Then the kernel jumps into tboot via the vector specified in the |
| 152 | shared page. |
| 153 | - Tboot will clean up the environment and disable TXT, then use the |
| 154 | kernel-provided ACPI information to actually place the platform |
| 155 | into the desired sleep state. |
| 156 | - In the case of S3, tboot will also register itself as the resume |
| 157 | vector. This is necessary because it must re-establish the |
| 158 | measured environment upon resume. Once the TXT environment |
| 159 | has been restored, it will restore the TPM PCRs and then |
| 160 | transfer control back to the kernel's S3 resume vector. |
| 161 | In order to preserve system integrity across S3, the kernel |
| 162 | provides tboot with a set of memory ranges (RAM and RESERVED_KERN |
| 163 | in the e820 table, but not any memory that BIOS might alter over |
| 164 | the S3 transition) that tboot will calculate a MAC (message |
| 165 | authentication code) over and then seal with the TPM. On resume |
| 166 | and once the measured environment has been re-established, tboot |
| 167 | will re-calculate the MAC and verify it against the sealed value. |
| 168 | Tboot's policy determines what happens if the verification fails. |
| 169 | Note that the c/s 194 of tboot which has the new MAC code supports |
| 170 | this. |
| 171 | |
| 172 | That's pretty much it for TXT support. |
| 173 | |
| 174 | |
| 175 | Configuring the System: |
| 176 | ====================== |
| 177 | |
| 178 | This code works with 32bit, 32bit PAE, and 64bit (x86_64) kernels. |
| 179 | |
| 180 | In BIOS, the user must enable: TPM, TXT, VT-x, VT-d. Not all BIOSes |
| 181 | allow these to be individually enabled/disabled and the screens in |
| 182 | which to find them are BIOS-specific. |
| 183 | |
| 184 | grub.conf needs to be modified as follows: |
| 185 | title Linux 2.6.29-tip w/ tboot |
| 186 | root (hd0,0) |
| 187 | kernel /tboot.gz logging=serial,vga,memory |
| 188 | module /vmlinuz-2.6.29-tip intel_iommu=on ro |
| 189 | root=LABEL=/ rhgb console=ttyS0,115200 3 |
| 190 | module /initrd-2.6.29-tip.img |
| 191 | module /Q35_SINIT_17.BIN |
| 192 | |
| 193 | The kernel option for enabling Intel TXT support is found under the |
| 194 | Security top-level menu and is called "Enable Intel(R) Trusted |
| 195 | Execution Technology (TXT)". It is considered EXPERIMENTAL and |
| 196 | depends on the generic x86 support (to allow maximum flexibility in |
| 197 | kernel build options), since the tboot code will detect whether the |
| 198 | platform actually supports Intel TXT and thus whether any of the |
| 199 | kernel code is executed. |
| 200 | |
| 201 | The Q35_SINIT_17.BIN file is what Intel TXT refers to as an |
| 202 | Authenticated Code Module. It is specific to the chipset in the |
| 203 | system and can also be found on the Trusted Boot site. It is an |
| 204 | (unencrypted) module signed by Intel that is used as part of the |
| 205 | DRTM process to verify and configure the system. It is signed |
| 206 | because it operates at a higher privilege level in the system than |
| 207 | any other macrocode and its correct operation is critical to the |
| 208 | establishment of the DRTM. The process for determining the correct |
| 209 | SINIT ACM for a system is documented in the SINIT-guide.txt file |
| 210 | that is on the tboot SourceForge site under the SINIT ACM downloads. |