| .. SPDX-License-Identifier: GPL-2.0 |
| |
| Spectre Side Channels |
| ===================== |
| |
| Spectre is a class of side channel attacks that exploit branch prediction |
| and speculative execution on modern CPUs to read memory, possibly |
| bypassing access controls. Speculative execution side channel exploits |
| do not modify memory but attempt to infer privileged data in the memory. |
| |
| This document covers Spectre variant 1 and Spectre variant 2. |
| |
| Affected processors |
| ------------------- |
| |
| Speculative execution side channel methods affect a wide range of modern |
| high performance processors, since most modern high speed processors |
| use branch prediction and speculative execution. |
| |
| The following CPUs are vulnerable: |
| |
| - Intel Core, Atom, Pentium, and Xeon processors |
| |
| - AMD Phenom, EPYC, and Zen processors |
| |
| - IBM POWER and zSeries processors |
| |
| - Higher end ARM processors |
| |
| - Apple CPUs |
| |
| - Higher end MIPS CPUs |
| |
| - Likely most other high performance CPUs. Contact your CPU vendor for details. |
| |
| Whether a processor is affected or not can be read out from the Spectre |
| vulnerability files in sysfs. See :ref:`spectre_sys_info`. |
| |
| Related CVEs |
| ------------ |
| |
| The following CVE entries describe Spectre variants: |
| |
| ============= ======================= ========================== |
| CVE-2017-5753 Bounds check bypass Spectre variant 1 |
| CVE-2017-5715 Branch target injection Spectre variant 2 |
| CVE-2019-1125 Spectre v1 swapgs Spectre variant 1 (swapgs) |
| ============= ======================= ========================== |
| |
| Problem |
| ------- |
| |
| CPUs use speculative operations to improve performance. That may leave |
| traces of memory accesses or computations in the processor's caches, |
| buffers, and branch predictors. Malicious software may be able to |
| influence the speculative execution paths, and then use the side effects |
| of the speculative execution in the CPUs' caches and buffers to infer |
| privileged data touched during the speculative execution. |
| |
| Spectre variant 1 attacks take advantage of speculative execution of |
| conditional branches, while Spectre variant 2 attacks use speculative |
| execution of indirect branches to leak privileged memory. |
| See :ref:`[1] <spec_ref1>` :ref:`[5] <spec_ref5>` :ref:`[6] <spec_ref6>` |
| :ref:`[7] <spec_ref7>` :ref:`[10] <spec_ref10>` :ref:`[11] <spec_ref11>`. |
| |
| Spectre variant 1 (Bounds Check Bypass) |
| --------------------------------------- |
| |
| The bounds check bypass attack :ref:`[2] <spec_ref2>` takes advantage |
| of speculative execution that bypasses conditional branch instructions |
| used for memory access bounds check (e.g. checking if the index of an |
| array results in memory access within a valid range). This results in |
| memory accesses to invalid memory (with out-of-bound index) that are |
| done speculatively before validation checks resolve. Such speculative |
| memory accesses can leave side effects, creating side channels which |
| leak information to the attacker. |
| |
| There are some extensions of Spectre variant 1 attacks for reading data |
| over the network, see :ref:`[12] <spec_ref12>`. However such attacks |
| are difficult, low bandwidth, fragile, and are considered low risk. |
| |
| Note that, despite "Bounds Check Bypass" name, Spectre variant 1 is not |
| only about user-controlled array bounds checks. It can affect any |
| conditional checks. The kernel entry code interrupt, exception, and NMI |
| handlers all have conditional swapgs checks. Those may be problematic |
| in the context of Spectre v1, as kernel code can speculatively run with |
| a user GS. |
| |
| Spectre variant 2 (Branch Target Injection) |
| ------------------------------------------- |
| |
| The branch target injection attack takes advantage of speculative |
| execution of indirect branches :ref:`[3] <spec_ref3>`. The indirect |
| branch predictors inside the processor used to guess the target of |
| indirect branches can be influenced by an attacker, causing gadget code |
| to be speculatively executed, thus exposing sensitive data touched by |
| the victim. The side effects left in the CPU's caches during speculative |
| execution can be measured to infer data values. |
| |
| .. _poison_btb: |
| |
| In Spectre variant 2 attacks, the attacker can steer speculative indirect |
| branches in the victim to gadget code by poisoning the branch target |
| buffer of a CPU used for predicting indirect branch addresses. Such |
| poisoning could be done by indirect branching into existing code, |
| with the address offset of the indirect branch under the attacker's |
| control. Since the branch prediction on impacted hardware does not |
| fully disambiguate branch address and uses the offset for prediction, |
| this could cause privileged code's indirect branch to jump to a gadget |
| code with the same offset. |
| |
| The most useful gadgets take an attacker-controlled input parameter (such |
| as a register value) so that the memory read can be controlled. Gadgets |
| without input parameters might be possible, but the attacker would have |
| very little control over what memory can be read, reducing the risk of |
| the attack revealing useful data. |
| |
| One other variant 2 attack vector is for the attacker to poison the |
| return stack buffer (RSB) :ref:`[13] <spec_ref13>` to cause speculative |
| subroutine return instruction execution to go to a gadget. An attacker's |
| imbalanced subroutine call instructions might "poison" entries in the |
| return stack buffer which are later consumed by a victim's subroutine |
| return instructions. This attack can be mitigated by flushing the return |
| stack buffer on context switch, or virtual machine (VM) exit. |
| |
| On systems with simultaneous multi-threading (SMT), attacks are possible |
| from the sibling thread, as level 1 cache and branch target buffer |
| (BTB) may be shared between hardware threads in a CPU core. A malicious |
| program running on the sibling thread may influence its peer's BTB to |
| steer its indirect branch speculations to gadget code, and measure the |
| speculative execution's side effects left in level 1 cache to infer the |
| victim's data. |
| |
| Yet another variant 2 attack vector is for the attacker to poison the |
| Branch History Buffer (BHB) to speculatively steer an indirect branch |
| to a specific Branch Target Buffer (BTB) entry, even if the entry isn't |
| associated with the source address of the indirect branch. Specifically, |
| the BHB might be shared across privilege levels even in the presence of |
| Enhanced IBRS. |
| |
| Currently the only known real-world BHB attack vector is via |
| unprivileged eBPF. Therefore, it's highly recommended to not enable |
| unprivileged eBPF, especially when eIBRS is used (without retpolines). |
| For a full mitigation against BHB attacks, it's recommended to use |
| retpolines (or eIBRS combined with retpolines). |
| |
| Attack scenarios |
| ---------------- |
| |
| The following list of attack scenarios have been anticipated, but may |
| not cover all possible attack vectors. |
| |
| 1. A user process attacking the kernel |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Spectre variant 1 |
| ~~~~~~~~~~~~~~~~~ |
| |
| The attacker passes a parameter to the kernel via a register or |
| via a known address in memory during a syscall. Such parameter may |
| be used later by the kernel as an index to an array or to derive |
| a pointer for a Spectre variant 1 attack. The index or pointer |
| is invalid, but bound checks are bypassed in the code branch taken |
| for speculative execution. This could cause privileged memory to be |
| accessed and leaked. |
| |
| For kernel code that has been identified where data pointers could |
| potentially be influenced for Spectre attacks, new "nospec" accessor |
| macros are used to prevent speculative loading of data. |
| |
| Spectre variant 1 (swapgs) |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| An attacker can train the branch predictor to speculatively skip the |
| swapgs path for an interrupt or exception. If they initialize |
| the GS register to a user-space value, if the swapgs is speculatively |
| skipped, subsequent GS-related percpu accesses in the speculation |
| window will be done with the attacker-controlled GS value. This |
| could cause privileged memory to be accessed and leaked. |
| |
| For example: |
| |
| :: |
| |
| if (coming from user space) |
| swapgs |
| mov %gs:<percpu_offset>, %reg |
| mov (%reg), %reg1 |
| |
| When coming from user space, the CPU can speculatively skip the |
| swapgs, and then do a speculative percpu load using the user GS |
| value. So the user can speculatively force a read of any kernel |
| value. If a gadget exists which uses the percpu value as an address |
| in another load/store, then the contents of the kernel value may |
| become visible via an L1 side channel attack. |
| |
| A similar attack exists when coming from kernel space. The CPU can |
| speculatively do the swapgs, causing the user GS to get used for the |
| rest of the speculative window. |
| |
| Spectre variant 2 |
| ~~~~~~~~~~~~~~~~~ |
| |
| A spectre variant 2 attacker can :ref:`poison <poison_btb>` the branch |
| target buffer (BTB) before issuing syscall to launch an attack. |
| After entering the kernel, the kernel could use the poisoned branch |
| target buffer on indirect jump and jump to gadget code in speculative |
| execution. |
| |
| If an attacker tries to control the memory addresses leaked during |
| speculative execution, he would also need to pass a parameter to the |
| gadget, either through a register or a known address in memory. After |
| the gadget has executed, he can measure the side effect. |
| |
| The kernel can protect itself against consuming poisoned branch |
| target buffer entries by using return trampolines (also known as |
| "retpoline") :ref:`[3] <spec_ref3>` :ref:`[9] <spec_ref9>` for all |
| indirect branches. Return trampolines trap speculative execution paths |
| to prevent jumping to gadget code during speculative execution. |
| x86 CPUs with Enhanced Indirect Branch Restricted Speculation |
| (Enhanced IBRS) available in hardware should use the feature to |
| mitigate Spectre variant 2 instead of retpoline. Enhanced IBRS is |
| more efficient than retpoline. |
| |
| There may be gadget code in firmware which could be exploited with |
| Spectre variant 2 attack by a rogue user process. To mitigate such |
| attacks on x86, Indirect Branch Restricted Speculation (IBRS) feature |
| is turned on before the kernel invokes any firmware code. |
| |
| 2. A user process attacking another user process |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| A malicious user process can try to attack another user process, |
| either via a context switch on the same hardware thread, or from the |
| sibling hyperthread sharing a physical processor core on simultaneous |
| multi-threading (SMT) system. |
| |
| Spectre variant 1 attacks generally require passing parameters |
| between the processes, which needs a data passing relationship, such |
| as remote procedure calls (RPC). Those parameters are used in gadget |
| code to derive invalid data pointers accessing privileged memory in |
| the attacked process. |
| |
| Spectre variant 2 attacks can be launched from a rogue process by |
| :ref:`poisoning <poison_btb>` the branch target buffer. This can |
| influence the indirect branch targets for a victim process that either |
| runs later on the same hardware thread, or running concurrently on |
| a sibling hardware thread sharing the same physical core. |
| |
| A user process can protect itself against Spectre variant 2 attacks |
| by using the prctl() syscall to disable indirect branch speculation |
| for itself. An administrator can also cordon off an unsafe process |
| from polluting the branch target buffer by disabling the process's |
| indirect branch speculation. This comes with a performance cost |
| from not using indirect branch speculation and clearing the branch |
| target buffer. When SMT is enabled on x86, for a process that has |
| indirect branch speculation disabled, Single Threaded Indirect Branch |
| Predictors (STIBP) :ref:`[4] <spec_ref4>` are turned on to prevent the |
| sibling thread from controlling branch target buffer. In addition, |
| the Indirect Branch Prediction Barrier (IBPB) is issued to clear the |
| branch target buffer when context switching to and from such process. |
| |
| On x86, the return stack buffer is stuffed on context switch. |
| This prevents the branch target buffer from being used for branch |
| prediction when the return stack buffer underflows while switching to |
| a deeper call stack. Any poisoned entries in the return stack buffer |
| left by the previous process will also be cleared. |
| |
| User programs should use address space randomization to make attacks |
| more difficult (Set /proc/sys/kernel/randomize_va_space = 1 or 2). |
| |
| 3. A virtualized guest attacking the host |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The attack mechanism is similar to how user processes attack the |
| kernel. The kernel is entered via hyper-calls or other virtualization |
| exit paths. |
| |
| For Spectre variant 1 attacks, rogue guests can pass parameters |
| (e.g. in registers) via hyper-calls to derive invalid pointers to |
| speculate into privileged memory after entering the kernel. For places |
| where such kernel code has been identified, nospec accessor macros |
| are used to stop speculative memory access. |
| |
| For Spectre variant 2 attacks, rogue guests can :ref:`poison |
| <poison_btb>` the branch target buffer or return stack buffer, causing |
| the kernel to jump to gadget code in the speculative execution paths. |
| |
| To mitigate variant 2, the host kernel can use return trampolines |
| for indirect branches to bypass the poisoned branch target buffer, |
| and flushing the return stack buffer on VM exit. This prevents rogue |
| guests from affecting indirect branching in the host kernel. |
| |
| To protect host processes from rogue guests, host processes can have |
| indirect branch speculation disabled via prctl(). The branch target |
| buffer is cleared before context switching to such processes. |
| |
| 4. A virtualized guest attacking other guest |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| A rogue guest may attack another guest to get data accessible by the |
| other guest. |
| |
| Spectre variant 1 attacks are possible if parameters can be passed |
| between guests. This may be done via mechanisms such as shared memory |
| or message passing. Such parameters could be used to derive data |
| pointers to privileged data in guest. The privileged data could be |
| accessed by gadget code in the victim's speculation paths. |
| |
| Spectre variant 2 attacks can be launched from a rogue guest by |
| :ref:`poisoning <poison_btb>` the branch target buffer or the return |
| stack buffer. Such poisoned entries could be used to influence |
| speculation execution paths in the victim guest. |
| |
| Linux kernel mitigates attacks to other guests running in the same |
| CPU hardware thread by flushing the return stack buffer on VM exit, |
| and clearing the branch target buffer before switching to a new guest. |
| |
| If SMT is used, Spectre variant 2 attacks from an untrusted guest |
| in the sibling hyperthread can be mitigated by the administrator, |
| by turning off the unsafe guest's indirect branch speculation via |
| prctl(). A guest can also protect itself by turning on microcode |
| based mitigations (such as IBPB or STIBP on x86) within the guest. |
| |
| .. _spectre_sys_info: |
| |
| Spectre system information |
| -------------------------- |
| |
| The Linux kernel provides a sysfs interface to enumerate the current |
| mitigation status of the system for Spectre: whether the system is |
| vulnerable, and which mitigations are active. |
| |
| The sysfs file showing Spectre variant 1 mitigation status is: |
| |
| /sys/devices/system/cpu/vulnerabilities/spectre_v1 |
| |
| The possible values in this file are: |
| |
| .. list-table:: |
| |
| * - 'Not affected' |
| - The processor is not vulnerable. |
| * - 'Vulnerable: __user pointer sanitization and usercopy barriers only; no swapgs barriers' |
| - The swapgs protections are disabled; otherwise it has |
| protection in the kernel on a case by case base with explicit |
| pointer sanitation and usercopy LFENCE barriers. |
| * - 'Mitigation: usercopy/swapgs barriers and __user pointer sanitization' |
| - Protection in the kernel on a case by case base with explicit |
| pointer sanitation, usercopy LFENCE barriers, and swapgs LFENCE |
| barriers. |
| |
| However, the protections are put in place on a case by case basis, |
| and there is no guarantee that all possible attack vectors for Spectre |
| variant 1 are covered. |
| |
| The spectre_v2 kernel file reports if the kernel has been compiled with |
| retpoline mitigation or if the CPU has hardware mitigation, and if the |
| CPU has support for additional process-specific mitigation. |
| |
| This file also reports CPU features enabled by microcode to mitigate |
| attack between user processes: |
| |
| 1. Indirect Branch Prediction Barrier (IBPB) to add additional |
| isolation between processes of different users. |
| 2. Single Thread Indirect Branch Predictors (STIBP) to add additional |
| isolation between CPU threads running on the same core. |
| |
| These CPU features may impact performance when used and can be enabled |
| per process on a case-by-case base. |
| |
| The sysfs file showing Spectre variant 2 mitigation status is: |
| |
| /sys/devices/system/cpu/vulnerabilities/spectre_v2 |
| |
| The possible values in this file are: |
| |
| - Kernel status: |
| |
| ======================================== ================================= |
| 'Not affected' The processor is not vulnerable |
| 'Mitigation: None' Vulnerable, no mitigation |
| 'Mitigation: Retpolines' Use Retpoline thunks |
| 'Mitigation: LFENCE' Use LFENCE instructions |
| 'Mitigation: Enhanced IBRS' Hardware-focused mitigation |
| 'Mitigation: Enhanced IBRS + Retpolines' Hardware-focused + Retpolines |
| 'Mitigation: Enhanced IBRS + LFENCE' Hardware-focused + LFENCE |
| ======================================== ================================= |
| |
| - Firmware status: Show if Indirect Branch Restricted Speculation (IBRS) is |
| used to protect against Spectre variant 2 attacks when calling firmware (x86 only). |
| |
| ========== ============================================================= |
| 'IBRS_FW' Protection against user program attacks when calling firmware |
| ========== ============================================================= |
| |
| - Indirect branch prediction barrier (IBPB) status for protection between |
| processes of different users. This feature can be controlled through |
| prctl() per process, or through kernel command line options. This is |
| an x86 only feature. For more details see below. |
| |
| =================== ======================================================== |
| 'IBPB: disabled' IBPB unused |
| 'IBPB: always-on' Use IBPB on all tasks |
| 'IBPB: conditional' Use IBPB on SECCOMP or indirect branch restricted tasks |
| =================== ======================================================== |
| |
| - Single threaded indirect branch prediction (STIBP) status for protection |
| between different hyper threads. This feature can be controlled through |
| prctl per process, or through kernel command line options. This is x86 |
| only feature. For more details see below. |
| |
| ==================== ======================================================== |
| 'STIBP: disabled' STIBP unused |
| 'STIBP: forced' Use STIBP on all tasks |
| 'STIBP: conditional' Use STIBP on SECCOMP or indirect branch restricted tasks |
| ==================== ======================================================== |
| |
| - Return stack buffer (RSB) protection status: |
| |
| ============= =========================================== |
| 'RSB filling' Protection of RSB on context switch enabled |
| ============= =========================================== |
| |
| - EIBRS Post-barrier Return Stack Buffer (PBRSB) protection status: |
| |
| =========================== ======================================================= |
| 'PBRSB-eIBRS: SW sequence' CPU is affected and protection of RSB on VMEXIT enabled |
| 'PBRSB-eIBRS: Vulnerable' CPU is vulnerable |
| 'PBRSB-eIBRS: Not affected' CPU is not affected by PBRSB |
| =========================== ======================================================= |
| |
| Full mitigation might require a microcode update from the CPU |
| vendor. When the necessary microcode is not available, the kernel will |
| report vulnerability. |
| |
| Turning on mitigation for Spectre variant 1 and Spectre variant 2 |
| ----------------------------------------------------------------- |
| |
| 1. Kernel mitigation |
| ^^^^^^^^^^^^^^^^^^^^ |
| |
| Spectre variant 1 |
| ~~~~~~~~~~~~~~~~~ |
| |
| For the Spectre variant 1, vulnerable kernel code (as determined |
| by code audit or scanning tools) is annotated on a case by case |
| basis to use nospec accessor macros for bounds clipping :ref:`[2] |
| <spec_ref2>` to avoid any usable disclosure gadgets. However, it may |
| not cover all attack vectors for Spectre variant 1. |
| |
| Copy-from-user code has an LFENCE barrier to prevent the access_ok() |
| check from being mis-speculated. The barrier is done by the |
| barrier_nospec() macro. |
| |
| For the swapgs variant of Spectre variant 1, LFENCE barriers are |
| added to interrupt, exception and NMI entry where needed. These |
| barriers are done by the FENCE_SWAPGS_KERNEL_ENTRY and |
| FENCE_SWAPGS_USER_ENTRY macros. |
| |
| Spectre variant 2 |
| ~~~~~~~~~~~~~~~~~ |
| |
| For Spectre variant 2 mitigation, the compiler turns indirect calls or |
| jumps in the kernel into equivalent return trampolines (retpolines) |
| :ref:`[3] <spec_ref3>` :ref:`[9] <spec_ref9>` to go to the target |
| addresses. Speculative execution paths under retpolines are trapped |
| in an infinite loop to prevent any speculative execution jumping to |
| a gadget. |
| |
| To turn on retpoline mitigation on a vulnerable CPU, the kernel |
| needs to be compiled with a gcc compiler that supports the |
| -mindirect-branch=thunk-extern -mindirect-branch-register options. |
| If the kernel is compiled with a Clang compiler, the compiler needs |
| to support -mretpoline-external-thunk option. The kernel config |
| CONFIG_RETPOLINE needs to be turned on, and the CPU needs to run with |
| the latest updated microcode. |
| |
| On Intel Skylake-era systems the mitigation covers most, but not all, |
| cases. See :ref:`[3] <spec_ref3>` for more details. |
| |
| On CPUs with hardware mitigation for Spectre variant 2 (e.g. IBRS |
| or enhanced IBRS on x86), retpoline is automatically disabled at run time. |
| |
| Systems which support enhanced IBRS (eIBRS) enable IBRS protection once at |
| boot, by setting the IBRS bit, and they're automatically protected against |
| Spectre v2 variant attacks, including cross-thread branch target injections |
| on SMT systems (STIBP). In other words, eIBRS enables STIBP too. |
| |
| Legacy IBRS systems clear the IBRS bit on exit to userspace and |
| therefore explicitly enable STIBP for that |
| |
| The retpoline mitigation is turned on by default on vulnerable |
| CPUs. It can be forced on or off by the administrator |
| via the kernel command line and sysfs control files. See |
| :ref:`spectre_mitigation_control_command_line`. |
| |
| On x86, indirect branch restricted speculation is turned on by default |
| before invoking any firmware code to prevent Spectre variant 2 exploits |
| using the firmware. |
| |
| Using kernel address space randomization (CONFIG_RANDOMIZE_BASE=y |
| and CONFIG_SLAB_FREELIST_RANDOM=y in the kernel configuration) makes |
| attacks on the kernel generally more difficult. |
| |
| 2. User program mitigation |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| User programs can mitigate Spectre variant 1 using LFENCE or "bounds |
| clipping". For more details see :ref:`[2] <spec_ref2>`. |
| |
| For Spectre variant 2 mitigation, individual user programs |
| can be compiled with return trampolines for indirect branches. |
| This protects them from consuming poisoned entries in the branch |
| target buffer left by malicious software. |
| |
| On legacy IBRS systems, at return to userspace, implicit STIBP is disabled |
| because the kernel clears the IBRS bit. In this case, the userspace programs |
| can disable indirect branch speculation via prctl() (See |
| :ref:`Documentation/userspace-api/spec_ctrl.rst <set_spec_ctrl>`). |
| On x86, this will turn on STIBP to guard against attacks from the |
| sibling thread when the user program is running, and use IBPB to |
| flush the branch target buffer when switching to/from the program. |
| |
| Restricting indirect branch speculation on a user program will |
| also prevent the program from launching a variant 2 attack |
| on x86. Administrators can change that behavior via the kernel |
| command line and sysfs control files. |
| See :ref:`spectre_mitigation_control_command_line`. |
| |
| Programs that disable their indirect branch speculation will have |
| more overhead and run slower. |
| |
| User programs should use address space randomization |
| (/proc/sys/kernel/randomize_va_space = 1 or 2) to make attacks more |
| difficult. |
| |
| 3. VM mitigation |
| ^^^^^^^^^^^^^^^^ |
| |
| Within the kernel, Spectre variant 1 attacks from rogue guests are |
| mitigated on a case by case basis in VM exit paths. Vulnerable code |
| uses nospec accessor macros for "bounds clipping", to avoid any |
| usable disclosure gadgets. However, this may not cover all variant |
| 1 attack vectors. |
| |
| For Spectre variant 2 attacks from rogue guests to the kernel, the |
| Linux kernel uses retpoline or Enhanced IBRS to prevent consumption of |
| poisoned entries in branch target buffer left by rogue guests. It also |
| flushes the return stack buffer on every VM exit to prevent a return |
| stack buffer underflow so poisoned branch target buffer could be used, |
| or attacker guests leaving poisoned entries in the return stack buffer. |
| |
| To mitigate guest-to-guest attacks in the same CPU hardware thread, |
| the branch target buffer is sanitized by flushing before switching |
| to a new guest on a CPU. |
| |
| The above mitigations are turned on by default on vulnerable CPUs. |
| |
| To mitigate guest-to-guest attacks from sibling thread when SMT is |
| in use, an untrusted guest running in the sibling thread can have |
| its indirect branch speculation disabled by administrator via prctl(). |
| |
| The kernel also allows guests to use any microcode based mitigation |
| they choose to use (such as IBPB or STIBP on x86) to protect themselves. |
| |
| .. _spectre_mitigation_control_command_line: |
| |
| Mitigation control on the kernel command line |
| --------------------------------------------- |
| |
| Spectre variant 2 mitigation can be disabled or force enabled at the |
| kernel command line. |
| |
| nospectre_v1 |
| |
| [X86,PPC] Disable mitigations for Spectre Variant 1 |
| (bounds check bypass). With this option data leaks are |
| possible in the system. |
| |
| nospectre_v2 |
| |
| [X86] Disable all mitigations for the Spectre variant 2 |
| (indirect branch prediction) vulnerability. System may |
| allow data leaks with this option, which is equivalent |
| to spectre_v2=off. |
| |
| |
| spectre_v2= |
| |
| [X86] Control mitigation of Spectre variant 2 |
| (indirect branch speculation) vulnerability. |
| The default operation protects the kernel from |
| user space attacks. |
| |
| on |
| unconditionally enable, implies |
| spectre_v2_user=on |
| off |
| unconditionally disable, implies |
| spectre_v2_user=off |
| auto |
| kernel detects whether your CPU model is |
| vulnerable |
| |
| Selecting 'on' will, and 'auto' may, choose a |
| mitigation method at run time according to the |
| CPU, the available microcode, the setting of the |
| CONFIG_RETPOLINE configuration option, and the |
| compiler with which the kernel was built. |
| |
| Selecting 'on' will also enable the mitigation |
| against user space to user space task attacks. |
| |
| Selecting 'off' will disable both the kernel and |
| the user space protections. |
| |
| Specific mitigations can also be selected manually: |
| |
| retpoline auto pick between generic,lfence |
| retpoline,generic Retpolines |
| retpoline,lfence LFENCE; indirect branch |
| retpoline,amd alias for retpoline,lfence |
| eibrs Enhanced/Auto IBRS |
| eibrs,retpoline Enhanced/Auto IBRS + Retpolines |
| eibrs,lfence Enhanced/Auto IBRS + LFENCE |
| ibrs use IBRS to protect kernel |
| |
| Not specifying this option is equivalent to |
| spectre_v2=auto. |
| |
| In general the kernel by default selects |
| reasonable mitigations for the current CPU. To |
| disable Spectre variant 2 mitigations, boot with |
| spectre_v2=off. Spectre variant 1 mitigations |
| cannot be disabled. |
| |
| For spectre_v2_user see Documentation/admin-guide/kernel-parameters.txt |
| |
| Mitigation selection guide |
| -------------------------- |
| |
| 1. Trusted userspace |
| ^^^^^^^^^^^^^^^^^^^^ |
| |
| If all userspace applications are from trusted sources and do not |
| execute externally supplied untrusted code, then the mitigations can |
| be disabled. |
| |
| 2. Protect sensitive programs |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| For security-sensitive programs that have secrets (e.g. crypto |
| keys), protection against Spectre variant 2 can be put in place by |
| disabling indirect branch speculation when the program is running |
| (See :ref:`Documentation/userspace-api/spec_ctrl.rst <set_spec_ctrl>`). |
| |
| 3. Sandbox untrusted programs |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Untrusted programs that could be a source of attacks can be cordoned |
| off by disabling their indirect branch speculation when they are run |
| (See :ref:`Documentation/userspace-api/spec_ctrl.rst <set_spec_ctrl>`). |
| This prevents untrusted programs from polluting the branch target |
| buffer. This behavior can be changed via the kernel command line |
| and sysfs control files. See |
| :ref:`spectre_mitigation_control_command_line`. |
| |
| 3. High security mode |
| ^^^^^^^^^^^^^^^^^^^^^ |
| |
| All Spectre variant 2 mitigations can be forced on |
| at boot time for all programs (See the "on" option in |
| :ref:`spectre_mitigation_control_command_line`). This will add |
| overhead as indirect branch speculations for all programs will be |
| restricted. |
| |
| On x86, branch target buffer will be flushed with IBPB when switching |
| to a new program. STIBP is left on all the time to protect programs |
| against variant 2 attacks originating from programs running on |
| sibling threads. |
| |
| Alternatively, STIBP can be used only when running programs |
| whose indirect branch speculation is explicitly disabled, |
| while IBPB is still used all the time when switching to a new |
| program to clear the branch target buffer (See "ibpb" option in |
| :ref:`spectre_mitigation_control_command_line`). This "ibpb" option |
| has less performance cost than the "on" option, which leaves STIBP |
| on all the time. |
| |
| References on Spectre |
| --------------------- |
| |
| Intel white papers: |
| |
| .. _spec_ref1: |
| |
| [1] `Intel analysis of speculative execution side channels <https://newsroom.intel.com/wp-content/uploads/sites/11/2018/01/Intel-Analysis-of-Speculative-Execution-Side-Channels.pdf>`_. |
| |
| .. _spec_ref2: |
| |
| [2] `Bounds check bypass <https://software.intel.com/security-software-guidance/software-guidance/bounds-check-bypass>`_. |
| |
| .. _spec_ref3: |
| |
| [3] `Deep dive: Retpoline: A branch target injection mitigation <https://software.intel.com/security-software-guidance/insights/deep-dive-retpoline-branch-target-injection-mitigation>`_. |
| |
| .. _spec_ref4: |
| |
| [4] `Deep Dive: Single Thread Indirect Branch Predictors <https://software.intel.com/security-software-guidance/insights/deep-dive-single-thread-indirect-branch-predictors>`_. |
| |
| AMD white papers: |
| |
| .. _spec_ref5: |
| |
| [5] `AMD64 technology indirect branch control extension <https://developer.amd.com/wp-content/resources/Architecture_Guidelines_Update_Indirect_Branch_Control.pdf>`_. |
| |
| .. _spec_ref6: |
| |
| [6] `Software techniques for managing speculation on AMD processors <https://developer.amd.com/wp-content/resources/Managing-Speculation-on-AMD-Processors.pdf>`_. |
| |
| ARM white papers: |
| |
| .. _spec_ref7: |
| |
| [7] `Cache speculation side-channels <https://developer.arm.com/support/arm-security-updates/speculative-processor-vulnerability/download-the-whitepaper>`_. |
| |
| .. _spec_ref8: |
| |
| [8] `Cache speculation issues update <https://developer.arm.com/support/arm-security-updates/speculative-processor-vulnerability/latest-updates/cache-speculation-issues-update>`_. |
| |
| Google white paper: |
| |
| .. _spec_ref9: |
| |
| [9] `Retpoline: a software construct for preventing branch-target-injection <https://support.google.com/faqs/answer/7625886>`_. |
| |
| MIPS white paper: |
| |
| .. _spec_ref10: |
| |
| [10] `MIPS: response on speculative execution and side channel vulnerabilities <https://www.mips.com/blog/mips-response-on-speculative-execution-and-side-channel-vulnerabilities/>`_. |
| |
| Academic papers: |
| |
| .. _spec_ref11: |
| |
| [11] `Spectre Attacks: Exploiting Speculative Execution <https://spectreattack.com/spectre.pdf>`_. |
| |
| .. _spec_ref12: |
| |
| [12] `NetSpectre: Read Arbitrary Memory over Network <https://arxiv.org/abs/1807.10535>`_. |
| |
| .. _spec_ref13: |
| |
| [13] `Spectre Returns! Speculation Attacks using the Return Stack Buffer <https://www.usenix.org/system/files/conference/woot18/woot18-paper-koruyeh.pdf>`_. |