diff --git a/Documentation/ABI/testing/sysfs-devices-system-cpu b/Documentation/ABI/testing/sysfs-devices-system-cpu index 9605dbd4b5b5..141a7bb58b80 100644 --- a/Documentation/ABI/testing/sysfs-devices-system-cpu +++ b/Documentation/ABI/testing/sysfs-devices-system-cpu @@ -484,6 +484,7 @@ What: /sys/devices/system/cpu/vulnerabilities /sys/devices/system/cpu/vulnerabilities/spectre_v2 /sys/devices/system/cpu/vulnerabilities/spec_store_bypass /sys/devices/system/cpu/vulnerabilities/l1tf + /sys/devices/system/cpu/vulnerabilities/mds Date: January 2018 Contact: Linux kernel mailing list <linux-kernel@xxxxxxxxxxxxxxx> Description: Information about CPU vulnerabilities @@ -496,8 +497,7 @@ Description: Information about CPU vulnerabilities "Vulnerable" CPU is affected and no mitigation in effect "Mitigation: $M" CPU is affected and mitigation $M is in effect - Details about the l1tf file can be found in - Documentation/admin-guide/l1tf.rst + See also: Documentation/admin-guide/hw-vuln/index.rst What: /sys/devices/system/cpu/smt /sys/devices/system/cpu/smt/active diff --git a/Documentation/admin-guide/hw-vuln/index.rst b/Documentation/admin-guide/hw-vuln/index.rst new file mode 100644 index 000000000000..ffc064c1ec68 --- /dev/null +++ b/Documentation/admin-guide/hw-vuln/index.rst @@ -0,0 +1,13 @@ +======================== +Hardware vulnerabilities +======================== + +This section describes CPU vulnerabilities and provides an overview of the +possible mitigations along with guidance for selecting mitigations if they +are configurable at compile, boot or run time. + +.. toctree:: + :maxdepth: 1 + + l1tf + mds diff --git a/Documentation/admin-guide/hw-vuln/l1tf.rst b/Documentation/admin-guide/hw-vuln/l1tf.rst new file mode 100644 index 000000000000..31653a9f0e1b --- /dev/null +++ b/Documentation/admin-guide/hw-vuln/l1tf.rst @@ -0,0 +1,615 @@ +L1TF - L1 Terminal Fault +======================== + +L1 Terminal Fault is a hardware vulnerability which allows unprivileged +speculative access to data which is available in the Level 1 Data Cache +when the page table entry controlling the virtual address, which is used +for the access, has the Present bit cleared or other reserved bits set. + +Affected processors +------------------- + +This vulnerability affects a wide range of Intel processors. The +vulnerability is not present on: + + - Processors from AMD, Centaur and other non Intel vendors + + - Older processor models, where the CPU family is < 6 + + - A range of Intel ATOM processors (Cedarview, Cloverview, Lincroft, + Penwell, Pineview, Silvermont, Airmont, Merrifield) + + - The Intel XEON PHI family + + - Intel processors which have the ARCH_CAP_RDCL_NO bit set in the + IA32_ARCH_CAPABILITIES MSR. If the bit is set the CPU is not affected + by the Meltdown vulnerability either. These CPUs should become + available by end of 2018. + +Whether a processor is affected or not can be read out from the L1TF +vulnerability file in sysfs. See :ref:`l1tf_sys_info`. + +Related CVEs +------------ + +The following CVE entries are related to the L1TF vulnerability: + + ============= ================= ============================== + CVE-2018-3615 L1 Terminal Fault SGX related aspects + CVE-2018-3620 L1 Terminal Fault OS, SMM related aspects + CVE-2018-3646 L1 Terminal Fault Virtualization related aspects + ============= ================= ============================== + +Problem +------- + +If an instruction accesses a virtual address for which the relevant page +table entry (PTE) has the Present bit cleared or other reserved bits set, +then speculative execution ignores the invalid PTE and loads the referenced +data if it is present in the Level 1 Data Cache, as if the page referenced +by the address bits in the PTE was still present and accessible. + +While this is a purely speculative mechanism and the instruction will raise +a page fault when it is retired eventually, the pure act of loading the +data and making it available to other speculative instructions opens up the +opportunity for side channel attacks to unprivileged malicious code, +similar to the Meltdown attack. + +While Meltdown breaks the user space to kernel space protection, L1TF +allows to attack any physical memory address in the system and the attack +works across all protection domains. It allows an attack of SGX and also +works from inside virtual machines because the speculation bypasses the +extended page table (EPT) protection mechanism. + + +Attack scenarios +---------------- + +1. Malicious user space +^^^^^^^^^^^^^^^^^^^^^^^ + + Operating Systems store arbitrary information in the address bits of a + PTE which is marked non present. This allows a malicious user space + application to attack the physical memory to which these PTEs resolve. + In some cases user-space can maliciously influence the information + encoded in the address bits of the PTE, thus making attacks more + deterministic and more practical. + + The Linux kernel contains a mitigation for this attack vector, PTE + inversion, which is permanently enabled and has no performance + impact. The kernel ensures that the address bits of PTEs, which are not + marked present, never point to cacheable physical memory space. + + A system with an up to date kernel is protected against attacks from + malicious user space applications. + +2. Malicious guest in a virtual machine +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + The fact that L1TF breaks all domain protections allows malicious guest + OSes, which can control the PTEs directly, and malicious guest user + space applications, which run on an unprotected guest kernel lacking the + PTE inversion mitigation for L1TF, to attack physical host memory. + + A special aspect of L1TF in the context of virtualization is symmetric + multi threading (SMT). The Intel implementation of SMT is called + HyperThreading. The fact that Hyperthreads on the affected processors + share the L1 Data Cache (L1D) is important for this. As the flaw allows + only to attack data which is present in L1D, a malicious guest running + on one Hyperthread can attack the data which is brought into the L1D by + the context which runs on the sibling Hyperthread of the same physical + core. This context can be host OS, host user space or a different guest. + + If the processor does not support Extended Page Tables, the attack is + only possible, when the hypervisor does not sanitize the content of the + effective (shadow) page tables. + + While solutions exist to mitigate these attack vectors fully, these + mitigations are not enabled by default in the Linux kernel because they + can affect performance significantly. The kernel provides several + mechanisms which can be utilized to address the problem depending on the + deployment scenario. The mitigations, their protection scope and impact + are described in the next sections. + + The default mitigations and the rationale for choosing them are explained + at the end of this document. See :ref:`default_mitigations`. + +.. _l1tf_sys_info: + +L1TF system information +----------------------- + +The Linux kernel provides a sysfs interface to enumerate the current L1TF +status of the system: whether the system is vulnerable, and which +mitigations are active. The relevant sysfs file is: + +/sys/devices/system/cpu/vulnerabilities/l1tf + +The possible values in this file are: + + =========================== =============================== + 'Not affected' The processor is not vulnerable + 'Mitigation: PTE Inversion' The host protection is active + =========================== =============================== + +If KVM/VMX is enabled and the processor is vulnerable then the following +information is appended to the 'Mitigation: PTE Inversion' part: + + - SMT status: + + ===================== ================ + 'VMX: SMT vulnerable' SMT is enabled + 'VMX: SMT disabled' SMT is disabled + ===================== ================ + + - L1D Flush mode: + + ================================ ==================================== + 'L1D vulnerable' L1D flushing is disabled + + 'L1D conditional cache flushes' L1D flush is conditionally enabled + + 'L1D cache flushes' L1D flush is unconditionally enabled + ================================ ==================================== + +The resulting grade of protection is discussed in the following sections. + + +Host mitigation mechanism +------------------------- + +The kernel is unconditionally protected against L1TF attacks from malicious +user space running on the host. + + +Guest mitigation mechanisms +--------------------------- + +.. _l1d_flush: + +1. L1D flush on VMENTER +^^^^^^^^^^^^^^^^^^^^^^^ + + To make sure that a guest cannot attack data which is present in the L1D + the hypervisor flushes the L1D before entering the guest. + + Flushing the L1D evicts not only the data which should not be accessed + by a potentially malicious guest, it also flushes the guest + data. Flushing the L1D has a performance impact as the processor has to + bring the flushed guest data back into the L1D. Depending on the + frequency of VMEXIT/VMENTER and the type of computations in the guest + performance degradation in the range of 1% to 50% has been observed. For + scenarios where guest VMEXIT/VMENTER are rare the performance impact is + minimal. Virtio and mechanisms like posted interrupts are designed to + confine the VMEXITs to a bare minimum, but specific configurations and + application scenarios might still suffer from a high VMEXIT rate. + + The kernel provides two L1D flush modes: + - conditional ('cond') + - unconditional ('always') + + The conditional mode avoids L1D flushing after VMEXITs which execute + only audited code paths before the corresponding VMENTER. These code + paths have been verified that they cannot expose secrets or other + interesting data to an attacker, but they can leak information about the + address space layout of the hypervisor. + + Unconditional mode flushes L1D on all VMENTER invocations and provides + maximum protection. It has a higher overhead than the conditional + mode. The overhead cannot be quantified correctly as it depends on the + workload scenario and the resulting number of VMEXITs. + + The general recommendation is to enable L1D flush on VMENTER. The kernel + defaults to conditional mode on affected processors. + + **Note**, that L1D flush does not prevent the SMT problem because the + sibling thread will also bring back its data into the L1D which makes it + attackable again. + + L1D flush can be controlled by the administrator via the kernel command + line and sysfs control files. See :ref:`mitigation_control_command_line` + and :ref:`mitigation_control_kvm`. + +.. _guest_confinement: + +2. Guest VCPU confinement to dedicated physical cores +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + To address the SMT problem, it is possible to make a guest or a group of + guests affine to one or more physical cores. The proper mechanism for + that is to utilize exclusive cpusets to ensure that no other guest or + host tasks can run on these cores. + + If only a single guest or related guests run on sibling SMT threads on + the same physical core then they can only attack their own memory and + restricted parts of the host memory. + + Host memory is attackable, when one of the sibling SMT threads runs in + host OS (hypervisor) context and the other in guest context. The amount + of valuable information from the host OS context depends on the context + which the host OS executes, i.e. interrupts, soft interrupts and kernel + threads. The amount of valuable data from these contexts cannot be + declared as non-interesting for an attacker without deep inspection of + the code. + + **Note**, that assigning guests to a fixed set of physical cores affects + the ability of the scheduler to do load balancing and might have + negative effects on CPU utilization depending on the hosting + scenario. Disabling SMT might be a viable alternative for particular + scenarios. + + For further information about confining guests to a single or to a group + of cores consult the cpusets documentation: + + https://www.kernel.org/doc/Documentation/cgroup-v1/cpusets.txt + +.. _interrupt_isolation: + +3. Interrupt affinity +^^^^^^^^^^^^^^^^^^^^^ + + Interrupts can be made affine to logical CPUs. This is not universally + true because there are types of interrupts which are truly per CPU + interrupts, e.g. the local timer interrupt. Aside of that multi queue + devices affine their interrupts to single CPUs or groups of CPUs per + queue without allowing the administrator to control the affinities. + + Moving the interrupts, which can be affinity controlled, away from CPUs + which run untrusted guests, reduces the attack vector space. + + Whether the interrupts with are affine to CPUs, which run untrusted + guests, provide interesting data for an attacker depends on the system + configuration and the scenarios which run on the system. While for some + of the interrupts it can be assumed that they won't expose interesting + information beyond exposing hints about the host OS memory layout, there + is no way to make general assumptions. + + Interrupt affinity can be controlled by the administrator via the + /proc/irq/$NR/smp_affinity[_list] files. Limited documentation is + available at: + + https://www.kernel.org/doc/Documentation/IRQ-affinity.txt + +.. _smt_control: + +4. SMT control +^^^^^^^^^^^^^^ + + To prevent the SMT issues of L1TF it might be necessary to disable SMT + completely. Disabling SMT can have a significant performance impact, but + the impact depends on the hosting scenario and the type of workloads. + The impact of disabling SMT needs also to be weighted against the impact + of other mitigation solutions like confining guests to dedicated cores. + + The kernel provides a sysfs interface to retrieve the status of SMT and + to control it. It also provides a kernel command line interface to + control SMT. + + The kernel command line interface consists of the following options: + + =========== ========================================================== + nosmt Affects the bring up of the secondary CPUs during boot. The + kernel tries to bring all present CPUs online during the + boot process. "nosmt" makes sure that from each physical + core only one - the so called primary (hyper) thread is + activated. Due to a design flaw of Intel processors related + to Machine Check Exceptions the non primary siblings have + to be brought up at least partially and are then shut down + again. "nosmt" can be undone via the sysfs interface. + + nosmt=force Has the same effect as "nosmt" but it does not allow to + undo the SMT disable via the sysfs interface. + =========== ========================================================== + + The sysfs interface provides two files: + + - /sys/devices/system/cpu/smt/control + - /sys/devices/system/cpu/smt/active + + /sys/devices/system/cpu/smt/control: + + This file allows to read out the SMT control state and provides the + ability to disable or (re)enable SMT. The possible states are: + + ============== =================================================== + on SMT is supported by the CPU and enabled. All + logical CPUs can be onlined and offlined without + restrictions. + + off SMT is supported by the CPU and disabled. Only + the so called primary SMT threads can be onlined + and offlined without restrictions. An attempt to + online a non-primary sibling is rejected + + forceoff Same as 'off' but the state cannot be controlled. + Attempts to write to the control file are rejected. + + notsupported The processor does not support SMT. It's therefore + not affected by the SMT implications of L1TF. + Attempts to write to the control file are rejected. + ============== =================================================== + + The possible states which can be written into this file to control SMT + state are: + + - on + - off + - forceoff + + /sys/devices/system/cpu/smt/active: + + This file reports whether SMT is enabled and active, i.e. if on any + physical core two or more sibling threads are online. + + SMT control is also possible at boot time via the l1tf kernel command + line parameter in combination with L1D flush control. See + :ref:`mitigation_control_command_line`. + +5. Disabling EPT +^^^^^^^^^^^^^^^^ + + Disabling EPT for virtual machines provides full mitigation for L1TF even + with SMT enabled, because the effective page tables for guests are + managed and sanitized by the hypervisor. Though disabling EPT has a + significant performance impact especially when the Meltdown mitigation + KPTI is enabled. + + EPT can be disabled in the hypervisor via the 'kvm-intel.ept' parameter. + +There is ongoing research and development for new mitigation mechanisms to +address the performance impact of disabling SMT or EPT. + +.. _mitigation_control_command_line: + +Mitigation control on the kernel command line +--------------------------------------------- + +The kernel command line allows to control the L1TF mitigations at boot +time with the option "l1tf=". The valid arguments for this option are: + + ============ ============================================================= + full Provides all available mitigations for the L1TF + vulnerability. Disables SMT and enables all mitigations in + the hypervisors, i.e. unconditional L1D flushing + + SMT control and L1D flush control via the sysfs interface + is still possible after boot. Hypervisors will issue a + warning when the first VM is started in a potentially + insecure configuration, i.e. SMT enabled or L1D flush + disabled. + + full,force Same as 'full', but disables SMT and L1D flush runtime + control. Implies the 'nosmt=force' command line option. + (i.e. sysfs control of SMT is disabled.) + + flush Leaves SMT enabled and enables the default hypervisor + mitigation, i.e. conditional L1D flushing + + SMT control and L1D flush control via the sysfs interface + is still possible after boot. Hypervisors will issue a + warning when the first VM is started in a potentially + insecure configuration, i.e. SMT enabled or L1D flush + disabled. + + flush,nosmt Disables SMT and enables the default hypervisor mitigation, + i.e. conditional L1D flushing. + + SMT control and L1D flush control via the sysfs interface + is still possible after boot. Hypervisors will issue a + warning when the first VM is started in a potentially + insecure configuration, i.e. SMT enabled or L1D flush + disabled. + + flush,nowarn Same as 'flush', but hypervisors will not warn when a VM is + started in a potentially insecure configuration. + + off Disables hypervisor mitigations and doesn't emit any + warnings. + It also drops the swap size and available RAM limit restrictions + on both hypervisor and bare metal. + + ============ ============================================================= + +The default is 'flush'. For details about L1D flushing see :ref:`l1d_flush`. + + +.. _mitigation_control_kvm: + +Mitigation control for KVM - module parameter +------------------------------------------------------------- + +The KVM hypervisor mitigation mechanism, flushing the L1D cache when +entering a guest, can be controlled with a module parameter. + +The option/parameter is "kvm-intel.vmentry_l1d_flush=". It takes the +following arguments: + + ============ ============================================================== + always L1D cache flush on every VMENTER. + + cond Flush L1D on VMENTER only when the code between VMEXIT and + VMENTER can leak host memory which is considered + interesting for an attacker. This still can leak host memory + which allows e.g. to determine the hosts address space layout. + + never Disables the mitigation + ============ ============================================================== + +The parameter can be provided on the kernel command line, as a module +parameter when loading the modules and at runtime modified via the sysfs +file: + +/sys/module/kvm_intel/parameters/vmentry_l1d_flush + +The default is 'cond'. If 'l1tf=full,force' is given on the kernel command +line, then 'always' is enforced and the kvm-intel.vmentry_l1d_flush +module parameter is ignored and writes to the sysfs file are rejected. + +.. _mitigation_selection: + +Mitigation selection guide +-------------------------- + +1. No virtualization in use +^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + The system is protected by the kernel unconditionally and no further + action is required. + +2. Virtualization with trusted guests +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + If the guest comes from a trusted source and the guest OS kernel is + guaranteed to have the L1TF mitigations in place the system is fully + protected against L1TF and no further action is required. + + To avoid the overhead of the default L1D flushing on VMENTER the + administrator can disable the flushing via the kernel command line and + sysfs control files. See :ref:`mitigation_control_command_line` and + :ref:`mitigation_control_kvm`. + + +3. Virtualization with untrusted guests +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +3.1. SMT not supported or disabled +"""""""""""""""""""""""""""""""""" + + If SMT is not supported by the processor or disabled in the BIOS or by + the kernel, it's only required to enforce L1D flushing on VMENTER. + + Conditional L1D flushing is the default behaviour and can be tuned. See + :ref:`mitigation_control_command_line` and :ref:`mitigation_control_kvm`. + +3.2. EPT not supported or disabled +"""""""""""""""""""""""""""""""""" + + If EPT is not supported by the processor or disabled in the hypervisor, + the system is fully protected. SMT can stay enabled and L1D flushing on + VMENTER is not required. + + EPT can be disabled in the hypervisor via the 'kvm-intel.ept' parameter. + +3.3. SMT and EPT supported and active +""""""""""""""""""""""""""""""""""""" + + If SMT and EPT are supported and active then various degrees of + mitigations can be employed: + + - L1D flushing on VMENTER: + + L1D flushing on VMENTER is the minimal protection requirement, but it + is only potent in combination with other mitigation methods. + + Conditional L1D flushing is the default behaviour and can be tuned. See + :ref:`mitigation_control_command_line` and :ref:`mitigation_control_kvm`. + + - Guest confinement: + + Confinement of guests to a single or a group of physical cores which + are not running any other processes, can reduce the attack surface + significantly, but interrupts, soft interrupts and kernel threads can + still expose valuable data to a potential attacker. See + :ref:`guest_confinement`. + + - Interrupt isolation: + + Isolating the guest CPUs from interrupts can reduce the attack surface + further, but still allows a malicious guest to explore a limited amount + of host physical memory. This can at least be used to gain knowledge + about the host address space layout. The interrupts which have a fixed + affinity to the CPUs which run the untrusted guests can depending on + the scenario still trigger soft interrupts and schedule kernel threads + which might expose valuable information. See + :ref:`interrupt_isolation`. + +The above three mitigation methods combined can provide protection to a +certain degree, but the risk of the remaining attack surface has to be +carefully analyzed. For full protection the following methods are +available: + + - Disabling SMT: + + Disabling SMT and enforcing the L1D flushing provides the maximum + amount of protection. This mitigation is not depending on any of the + above mitigation methods. + + SMT control and L1D flushing can be tuned by the command line + parameters 'nosmt', 'l1tf', 'kvm-intel.vmentry_l1d_flush' and at run + time with the matching sysfs control files. See :ref:`smt_control`, + :ref:`mitigation_control_command_line` and + :ref:`mitigation_control_kvm`. + + - Disabling EPT: + + Disabling EPT provides the maximum amount of protection as well. It is + not depending on any of the above mitigation methods. SMT can stay + enabled and L1D flushing is not required, but the performance impact is + significant. + + EPT can be disabled in the hypervisor via the 'kvm-intel.ept' + parameter. + +3.4. Nested virtual machines +"""""""""""""""""""""""""""" + +When nested virtualization is in use, three operating systems are involved: +the bare metal hypervisor, the nested hypervisor and the nested virtual +machine. VMENTER operations from the nested hypervisor into the nested +guest will always be processed by the bare metal hypervisor. If KVM is the +bare metal hypervisor it will: + + - Flush the L1D cache on every switch from the nested hypervisor to the + nested virtual machine, so that the nested hypervisor's secrets are not + exposed to the nested virtual machine; + + - Flush the L1D cache on every switch from the nested virtual machine to + the nested hypervisor; this is a complex operation, and flushing the L1D + cache avoids that the bare metal hypervisor's secrets are exposed to the + nested virtual machine; + + - Instruct the nested hypervisor to not perform any L1D cache flush. This + is an optimization to avoid double L1D flushing. + + +.. _default_mitigations: + +Default mitigations +------------------- + + The kernel default mitigations for vulnerable processors are: + + - PTE inversion to protect against malicious user space. This is done + unconditionally and cannot be controlled. The swap storage is limited + to ~16TB. + + - L1D conditional flushing on VMENTER when EPT is enabled for + a guest. + + The kernel does not by default enforce the disabling of SMT, which leaves + SMT systems vulnerable when running untrusted guests with EPT enabled. + + The rationale for this choice is: + + - Force disabling SMT can break existing setups, especially with + unattended updates. + + - If regular users run untrusted guests on their machine, then L1TF is + just an add on to other malware which might be embedded in an untrusted + guest, e.g. spam-bots or attacks on the local network. + + There is no technical way to prevent a user from running untrusted code + on their machines blindly. + + - It's technically extremely unlikely and from today's knowledge even + impossible that L1TF can be exploited via the most popular attack + mechanisms like JavaScript because these mechanisms have no way to + control PTEs. If this would be possible and not other mitigation would + be possible, then the default might be different. + + - The administrators of cloud and hosting setups have to carefully + analyze the risk for their scenarios and make the appropriate + mitigation choices, which might even vary across their deployed + machines and also result in other changes of their overall setup. + There is no way for the kernel to provide a sensible default for this + kind of scenarios. diff --git a/Documentation/admin-guide/hw-vuln/mds.rst b/Documentation/admin-guide/hw-vuln/mds.rst new file mode 100644 index 000000000000..e3a796c0d3a2 --- /dev/null +++ b/Documentation/admin-guide/hw-vuln/mds.rst @@ -0,0 +1,308 @@ +MDS - Microarchitectural Data Sampling +====================================== + +Microarchitectural Data Sampling is a hardware vulnerability which allows +unprivileged speculative access to data which is available in various CPU +internal buffers. + +Affected processors +------------------- + +This vulnerability affects a wide range of Intel processors. The +vulnerability is not present on: + + - Processors from AMD, Centaur and other non Intel vendors + + - Older processor models, where the CPU family is < 6 + + - Some Atoms (Bonnell, Saltwell, Goldmont, GoldmontPlus) + + - Intel processors which have the ARCH_CAP_MDS_NO bit set in the + IA32_ARCH_CAPABILITIES MSR. + +Whether a processor is affected or not can be read out from the MDS +vulnerability file in sysfs. See :ref:`mds_sys_info`. + +Not all processors are affected by all variants of MDS, but the mitigation +is identical for all of them so the kernel treats them as a single +vulnerability. + +Related CVEs +------------ + +The following CVE entries are related to the MDS vulnerability: + + ============== ===== =================================================== + CVE-2018-12126 MSBDS Microarchitectural Store Buffer Data Sampling + CVE-2018-12130 MFBDS Microarchitectural Fill Buffer Data Sampling + CVE-2018-12127 MLPDS Microarchitectural Load Port Data Sampling + CVE-2019-11091 MDSUM Microarchitectural Data Sampling Uncacheable Memory + ============== ===== =================================================== + +Problem +------- + +When performing store, load, L1 refill operations, processors write data +into temporary microarchitectural structures (buffers). The data in the +buffer can be forwarded to load operations as an optimization. + +Under certain conditions, usually a fault/assist caused by a load +operation, data unrelated to the load memory address can be speculatively +forwarded from the buffers. Because the load operation causes a fault or +assist and its result will be discarded, the forwarded data will not cause +incorrect program execution or state changes. But a malicious operation +may be able to forward this speculative data to a disclosure gadget which +allows in turn to infer the value via a cache side channel attack. + +Because the buffers are potentially shared between Hyper-Threads cross +Hyper-Thread attacks are possible. + +Deeper technical information is available in the MDS specific x86 +architecture section: :ref:`Documentation/x86/mds.rst <mds>`. + + +Attack scenarios +---------------- + +Attacks against the MDS vulnerabilities can be mounted from malicious non +priviledged user space applications running on hosts or guest. Malicious +guest OSes can obviously mount attacks as well. + +Contrary to other speculation based vulnerabilities the MDS vulnerability +does not allow the attacker to control the memory target address. As a +consequence the attacks are purely sampling based, but as demonstrated with +the TLBleed attack samples can be postprocessed successfully. + +Web-Browsers +^^^^^^^^^^^^ + + It's unclear whether attacks through Web-Browsers are possible at + all. The exploitation through Java-Script is considered very unlikely, + but other widely used web technologies like Webassembly could possibly be + abused. + + +.. _mds_sys_info: + +MDS system information +----------------------- + +The Linux kernel provides a sysfs interface to enumerate the current MDS +status of the system: whether the system is vulnerable, and which +mitigations are active. The relevant sysfs file is: + +/sys/devices/system/cpu/vulnerabilities/mds + +The possible values in this file are: + + .. list-table:: + + * - 'Not affected' + - The processor is not vulnerable + * - 'Vulnerable' + - The processor is vulnerable, but no mitigation enabled + * - 'Vulnerable: Clear CPU buffers attempted, no microcode' + - The processor is vulnerable but microcode is not updated. + + The mitigation is enabled on a best effort basis. See :ref:`vmwerv` + * - 'Mitigation: Clear CPU buffers' + - The processor is vulnerable and the CPU buffer clearing mitigation is + enabled. + +If the processor is vulnerable then the following information is appended +to the above information: + + ======================== ============================================ + 'SMT vulnerable' SMT is enabled + 'SMT mitigated' SMT is enabled and mitigated + 'SMT disabled' SMT is disabled + 'SMT Host state unknown' Kernel runs in a VM, Host SMT state unknown + ======================== ============================================ + +.. _vmwerv: + +Best effort mitigation mode +^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + If the processor is vulnerable, but the availability of the microcode based + mitigation mechanism is not advertised via CPUID the kernel selects a best + effort mitigation mode. This mode invokes the mitigation instructions + without a guarantee that they clear the CPU buffers. + + This is done to address virtualization scenarios where the host has the + microcode update applied, but the hypervisor is not yet updated to expose + the CPUID to the guest. If the host has updated microcode the protection + takes effect otherwise a few cpu cycles are wasted pointlessly. + + The state in the mds sysfs file reflects this situation accordingly. + + +Mitigation mechanism +------------------------- + +The kernel detects the affected CPUs and the presence of the microcode +which is required. + +If a CPU is affected and the microcode is available, then the kernel +enables the mitigation by default. The mitigation can be controlled at boot +time via a kernel command line option. See +:ref:`mds_mitigation_control_command_line`. + +.. _cpu_buffer_clear: + +CPU buffer clearing +^^^^^^^^^^^^^^^^^^^ + + The mitigation for MDS clears the affected CPU buffers on return to user + space and when entering a guest. + + If SMT is enabled it also clears the buffers on idle entry when the CPU + is only affected by MSBDS and not any other MDS variant, because the + other variants cannot be protected against cross Hyper-Thread attacks. + + For CPUs which are only affected by MSBDS the user space, guest and idle + transition mitigations are sufficient and SMT is not affected. + +.. _virt_mechanism: + +Virtualization mitigation +^^^^^^^^^^^^^^^^^^^^^^^^^ + + The protection for host to guest transition depends on the L1TF + vulnerability of the CPU: + + - CPU is affected by L1TF: + + If the L1D flush mitigation is enabled and up to date microcode is + available, the L1D flush mitigation is automatically protecting the + guest transition. + + If the L1D flush mitigation is disabled then the MDS mitigation is + invoked explicit when the host MDS mitigation is enabled. + + For details on L1TF and virtualization see: + :ref:`Documentation/admin-guide/hw-vuln//l1tf.rst <mitigation_control_kvm>`. + + - CPU is not affected by L1TF: + + CPU buffers are flushed before entering the guest when the host MDS + mitigation is enabled. + + The resulting MDS protection matrix for the host to guest transition: + + ============ ===== ============= ============ ================= + L1TF MDS VMX-L1FLUSH Host MDS MDS-State + + Don't care No Don't care N/A Not affected + + Yes Yes Disabled Off Vulnerable + + Yes Yes Disabled Full Mitigated + + Yes Yes Enabled Don't care Mitigated + + No Yes N/A Off Vulnerable + + No Yes N/A Full Mitigated + ============ ===== ============= ============ ================= + + This only covers the host to guest transition, i.e. prevents leakage from + host to guest, but does not protect the guest internally. Guests need to + have their own protections. + +.. _xeon_phi: + +XEON PHI specific considerations +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + The XEON PHI processor family is affected by MSBDS which can be exploited + cross Hyper-Threads when entering idle states. Some XEON PHI variants allow + to use MWAIT in user space (Ring 3) which opens an potential attack vector + for malicious user space. The exposure can be disabled on the kernel + command line with the 'ring3mwait=disable' command line option. + + XEON PHI is not affected by the other MDS variants and MSBDS is mitigated + before the CPU enters a idle state. As XEON PHI is not affected by L1TF + either disabling SMT is not required for full protection. + +.. _mds_smt_control: + +SMT control +^^^^^^^^^^^ + + All MDS variants except MSBDS can be attacked cross Hyper-Threads. That + means on CPUs which are affected by MFBDS or MLPDS it is necessary to + disable SMT for full protection. These are most of the affected CPUs; the + exception is XEON PHI, see :ref:`xeon_phi`. + + Disabling SMT can have a significant performance impact, but the impact + depends on the type of workloads. + + See the relevant chapter in the L1TF mitigation documentation for details: + :ref:`Documentation/admin-guide/hw-vuln/l1tf.rst <smt_control>`. + + +.. _mds_mitigation_control_command_line: + +Mitigation control on the kernel command line +--------------------------------------------- + +The kernel command line allows to control the MDS mitigations at boot +time with the option "mds=". The valid arguments for this option are: + + ============ ============================================================= + full If the CPU is vulnerable, enable all available mitigations + for the MDS vulnerability, CPU buffer clearing on exit to + userspace and when entering a VM. Idle transitions are + protected as well if SMT is enabled. + + It does not automatically disable SMT. + + full,nosmt The same as mds=full, with SMT disabled on vulnerable + CPUs. This is the complete mitigation. + + off Disables MDS mitigations completely. + + ============ ============================================================= + +Not specifying this option is equivalent to "mds=full". + + +Mitigation selection guide +-------------------------- + +1. Trusted userspace +^^^^^^^^^^^^^^^^^^^^ + + If all userspace applications are from a trusted source and do not + execute untrusted code which is supplied externally, then the mitigation + can be disabled. + + +2. Virtualization with trusted guests +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + The same considerations as above versus trusted user space apply. + +3. Virtualization with untrusted guests +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + The protection depends on the state of the L1TF mitigations. + See :ref:`virt_mechanism`. + + If the MDS mitigation is enabled and SMT is disabled, guest to host and + guest to guest attacks are prevented. + +.. _mds_default_mitigations: + +Default mitigations +------------------- + + The kernel default mitigations for vulnerable processors are: + + - Enable CPU buffer clearing + + The kernel does not by default enforce the disabling of SMT, which leaves + SMT systems vulnerable when running untrusted code. The same rationale as + for L1TF applies. + See :ref:`Documentation/admin-guide/hw-vuln//l1tf.rst <default_mitigations>`. diff --git a/Documentation/admin-guide/index.rst b/Documentation/admin-guide/index.rst index 0a491676685e..42247516962a 100644 --- a/Documentation/admin-guide/index.rst +++ b/Documentation/admin-guide/index.rst @@ -17,14 +17,12 @@ etc. kernel-parameters devices -This section describes CPU vulnerabilities and provides an overview of the -possible mitigations along with guidance for selecting mitigations if they -are configurable at compile, boot or run time. +This section describes CPU vulnerabilities and their mitigations. .. toctree:: :maxdepth: 1 - l1tf + hw-vuln/index Here is a set of documents aimed at users who are trying to track down problems and bugs in particular. diff --git a/Documentation/admin-guide/kernel-parameters.txt b/Documentation/admin-guide/kernel-parameters.txt index 2b8ee90bb644..c7937f379d22 100644 --- a/Documentation/admin-guide/kernel-parameters.txt +++ b/Documentation/admin-guide/kernel-parameters.txt @@ -2141,7 +2141,7 @@ Default is 'flush'. - For details see: Documentation/admin-guide/l1tf.rst + For details see: Documentation/admin-guide/hw-vuln/l1tf.rst l2cr= [PPC] @@ -2387,6 +2387,32 @@ Format: <first>,<last> Specifies range of consoles to be captured by the MDA. + mds= [X86,INTEL] + Control mitigation for the Micro-architectural Data + Sampling (MDS) vulnerability. + + Certain CPUs are vulnerable to an exploit against CPU + internal buffers which can forward information to a + disclosure gadget under certain conditions. + + In vulnerable processors, the speculatively + forwarded data can be used in a cache side channel + attack, to access data to which the attacker does + not have direct access. + + This parameter controls the MDS mitigation. The + options are: + + full - Enable MDS mitigation on vulnerable CPUs + full,nosmt - Enable MDS mitigation and disable + SMT on vulnerable CPUs + off - Unconditionally disable MDS mitigation + + Not specifying this option is equivalent to + mds=full. + + For details see: Documentation/admin-guide/hw-vuln/mds.rst + mem=nn[KMG] [KNL,BOOT] Force usage of a specific amount of memory Amount of memory to be used when the kernel is not able to see the whole system memory or for test. @@ -2544,6 +2570,40 @@ in the "bleeding edge" mini2440 support kernel at http://repo.or.cz/w/linux-2.6/mini2440.git + mitigations= + [X86,PPC,S390] Control optional mitigations for CPU + vulnerabilities. This is a set of curated, + arch-independent options, each of which is an + aggregation of existing arch-specific options. + + off + Disable all optional CPU mitigations. This + improves system performance, but it may also + expose users to several CPU vulnerabilities. + Equivalent to: nopti [X86,PPC] + nospectre_v1 [PPC] + nobp=0 [S390] + nospectre_v2 [X86,PPC,S390] + spectre_v2_user=off [X86] + spec_store_bypass_disable=off [X86,PPC] + l1tf=off [X86] + mds=off [X86] + + auto (default) + Mitigate all CPU vulnerabilities, but leave SMT + enabled, even if it's vulnerable. This is for + users who don't want to be surprised by SMT + getting disabled across kernel upgrades, or who + have other ways of avoiding SMT-based attacks. + Equivalent to: (default behavior) + + auto,nosmt + Mitigate all CPU vulnerabilities, disabling SMT + if needed. This is for users who always want to + be fully mitigated, even if it means losing SMT. + Equivalent to: l1tf=flush,nosmt [X86] + mds=full,nosmt [X86] + mminit_loglevel= [KNL] When CONFIG_DEBUG_MEMORY_INIT is set, this parameter allows control of the logging verbosity for diff --git a/Documentation/admin-guide/l1tf.rst b/Documentation/admin-guide/l1tf.rst deleted file mode 100644 index 9af977384168..000000000000 --- a/Documentation/admin-guide/l1tf.rst +++ /dev/null @@ -1,614 +0,0 @@ -L1TF - L1 Terminal Fault -======================== - -L1 Terminal Fault is a hardware vulnerability which allows unprivileged -speculative access to data which is available in the Level 1 Data Cache -when the page table entry controlling the virtual address, which is used -for the access, has the Present bit cleared or other reserved bits set. - -Affected processors -------------------- - -This vulnerability affects a wide range of Intel processors. The -vulnerability is not present on: - - - Processors from AMD, Centaur and other non Intel vendors - - - Older processor models, where the CPU family is < 6 - - - A range of Intel ATOM processors (Cedarview, Cloverview, Lincroft, - Penwell, Pineview, Silvermont, Airmont, Merrifield) - - - The Intel XEON PHI family - - - Intel processors which have the ARCH_CAP_RDCL_NO bit set in the - IA32_ARCH_CAPABILITIES MSR. If the bit is set the CPU is not affected - by the Meltdown vulnerability either. These CPUs should become - available by end of 2018. - -Whether a processor is affected or not can be read out from the L1TF -vulnerability file in sysfs. See :ref:`l1tf_sys_info`. - -Related CVEs ------------- - -The following CVE entries are related to the L1TF vulnerability: - - ============= ================= ============================== - CVE-2018-3615 L1 Terminal Fault SGX related aspects - CVE-2018-3620 L1 Terminal Fault OS, SMM related aspects - CVE-2018-3646 L1 Terminal Fault Virtualization related aspects - ============= ================= ============================== - -Problem -------- - -If an instruction accesses a virtual address for which the relevant page -table entry (PTE) has the Present bit cleared or other reserved bits set, -then speculative execution ignores the invalid PTE and loads the referenced -data if it is present in the Level 1 Data Cache, as if the page referenced -by the address bits in the PTE was still present and accessible. - -While this is a purely speculative mechanism and the instruction will raise -a page fault when it is retired eventually, the pure act of loading the -data and making it available to other speculative instructions opens up the -opportunity for side channel attacks to unprivileged malicious code, -similar to the Meltdown attack. - -While Meltdown breaks the user space to kernel space protection, L1TF -allows to attack any physical memory address in the system and the attack -works across all protection domains. It allows an attack of SGX and also -works from inside virtual machines because the speculation bypasses the -extended page table (EPT) protection mechanism. - - -Attack scenarios ----------------- - -1. Malicious user space -^^^^^^^^^^^^^^^^^^^^^^^ - - Operating Systems store arbitrary information in the address bits of a - PTE which is marked non present. This allows a malicious user space - application to attack the physical memory to which these PTEs resolve. - In some cases user-space can maliciously influence the information - encoded in the address bits of the PTE, thus making attacks more - deterministic and more practical. - - The Linux kernel contains a mitigation for this attack vector, PTE - inversion, which is permanently enabled and has no performance - impact. The kernel ensures that the address bits of PTEs, which are not - marked present, never point to cacheable physical memory space. - - A system with an up to date kernel is protected against attacks from - malicious user space applications. - -2. Malicious guest in a virtual machine -^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ - - The fact that L1TF breaks all domain protections allows malicious guest - OSes, which can control the PTEs directly, and malicious guest user - space applications, which run on an unprotected guest kernel lacking the - PTE inversion mitigation for L1TF, to attack physical host memory. - - A special aspect of L1TF in the context of virtualization is symmetric - multi threading (SMT). The Intel implementation of SMT is called - HyperThreading. The fact that Hyperthreads on the affected processors - share the L1 Data Cache (L1D) is important for this. As the flaw allows - only to attack data which is present in L1D, a malicious guest running - on one Hyperthread can attack the data which is brought into the L1D by - the context which runs on the sibling Hyperthread of the same physical - core. This context can be host OS, host user space or a different guest. - - If the processor does not support Extended Page Tables, the attack is - only possible, when the hypervisor does not sanitize the content of the - effective (shadow) page tables. - - While solutions exist to mitigate these attack vectors fully, these - mitigations are not enabled by default in the Linux kernel because they - can affect performance significantly. The kernel provides several - mechanisms which can be utilized to address the problem depending on the - deployment scenario. The mitigations, their protection scope and impact - are described in the next sections. - - The default mitigations and the rationale for choosing them are explained - at the end of this document. See :ref:`default_mitigations`. - -.. _l1tf_sys_info: - -L1TF system information ------------------------ - -The Linux kernel provides a sysfs interface to enumerate the current L1TF -status of the system: whether the system is vulnerable, and which -mitigations are active. The relevant sysfs file is: - -/sys/devices/system/cpu/vulnerabilities/l1tf - -The possible values in this file are: - - =========================== =============================== - 'Not affected' The processor is not vulnerable - 'Mitigation: PTE Inversion' The host protection is active - =========================== =============================== - -If KVM/VMX is enabled and the processor is vulnerable then the following -information is appended to the 'Mitigation: PTE Inversion' part: - - - SMT status: - - ===================== ================ - 'VMX: SMT vulnerable' SMT is enabled - 'VMX: SMT disabled' SMT is disabled - ===================== ================ - - - L1D Flush mode: - - ================================ ==================================== - 'L1D vulnerable' L1D flushing is disabled - - 'L1D conditional cache flushes' L1D flush is conditionally enabled - - 'L1D cache flushes' L1D flush is unconditionally enabled - ================================ ==================================== - -The resulting grade of protection is discussed in the following sections. - - -Host mitigation mechanism -------------------------- - -The kernel is unconditionally protected against L1TF attacks from malicious -user space running on the host. - - -Guest mitigation mechanisms ---------------------------- - -.. _l1d_flush: - -1. L1D flush on VMENTER -^^^^^^^^^^^^^^^^^^^^^^^ - - To make sure that a guest cannot attack data which is present in the L1D - the hypervisor flushes the L1D before entering the guest. - - Flushing the L1D evicts not only the data which should not be accessed - by a potentially malicious guest, it also flushes the guest - data. Flushing the L1D has a performance impact as the processor has to - bring the flushed guest data back into the L1D. Depending on the - frequency of VMEXIT/VMENTER and the type of computations in the guest - performance degradation in the range of 1% to 50% has been observed. For - scenarios where guest VMEXIT/VMENTER are rare the performance impact is - minimal. Virtio and mechanisms like posted interrupts are designed to - confine the VMEXITs to a bare minimum, but specific configurations and - application scenarios might still suffer from a high VMEXIT rate. - - The kernel provides two L1D flush modes: - - conditional ('cond') - - unconditional ('always') - - The conditional mode avoids L1D flushing after VMEXITs which execute - only audited code paths before the corresponding VMENTER. These code - paths have been verified that they cannot expose secrets or other - interesting data to an attacker, but they can leak information about the - address space layout of the hypervisor. - - Unconditional mode flushes L1D on all VMENTER invocations and provides - maximum protection. It has a higher overhead than the conditional - mode. The overhead cannot be quantified correctly as it depends on the - workload scenario and the resulting number of VMEXITs. - - The general recommendation is to enable L1D flush on VMENTER. The kernel - defaults to conditional mode on affected processors. - - **Note**, that L1D flush does not prevent the SMT problem because the - sibling thread will also bring back its data into the L1D which makes it - attackable again. - - L1D flush can be controlled by the administrator via the kernel command - line and sysfs control files. See :ref:`mitigation_control_command_line` - and :ref:`mitigation_control_kvm`. - -.. _guest_confinement: - -2. Guest VCPU confinement to dedicated physical cores -^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ - - To address the SMT problem, it is possible to make a guest or a group of - guests affine to one or more physical cores. The proper mechanism for - that is to utilize exclusive cpusets to ensure that no other guest or - host tasks can run on these cores. - - If only a single guest or related guests run on sibling SMT threads on - the same physical core then they can only attack their own memory and - restricted parts of the host memory. - - Host memory is attackable, when one of the sibling SMT threads runs in - host OS (hypervisor) context and the other in guest context. The amount - of valuable information from the host OS context depends on the context - which the host OS executes, i.e. interrupts, soft interrupts and kernel - threads. The amount of valuable data from these contexts cannot be - declared as non-interesting for an attacker without deep inspection of - the code. - - **Note**, that assigning guests to a fixed set of physical cores affects - the ability of the scheduler to do load balancing and might have - negative effects on CPU utilization depending on the hosting - scenario. Disabling SMT might be a viable alternative for particular - scenarios. - - For further information about confining guests to a single or to a group - of cores consult the cpusets documentation: - - https://www.kernel.org/doc/Documentation/cgroup-v1/cpusets.txt - -.. _interrupt_isolation: - -3. Interrupt affinity -^^^^^^^^^^^^^^^^^^^^^ - - Interrupts can be made affine to logical CPUs. This is not universally - true because there are types of interrupts which are truly per CPU - interrupts, e.g. the local timer interrupt. Aside of that multi queue - devices affine their interrupts to single CPUs or groups of CPUs per - queue without allowing the administrator to control the affinities. - - Moving the interrupts, which can be affinity controlled, away from CPUs - which run untrusted guests, reduces the attack vector space. - - Whether the interrupts with are affine to CPUs, which run untrusted - guests, provide interesting data for an attacker depends on the system - configuration and the scenarios which run on the system. While for some - of the interrupts it can be assumed that they won't expose interesting - information beyond exposing hints about the host OS memory layout, there - is no way to make general assumptions. - - Interrupt affinity can be controlled by the administrator via the - /proc/irq/$NR/smp_affinity[_list] files. Limited documentation is - available at: - - https://www.kernel.org/doc/Documentation/IRQ-affinity.txt - -.. _smt_control: - -4. SMT control -^^^^^^^^^^^^^^ - - To prevent the SMT issues of L1TF it might be necessary to disable SMT - completely. Disabling SMT can have a significant performance impact, but - the impact depends on the hosting scenario and the type of workloads. - The impact of disabling SMT needs also to be weighted against the impact - of other mitigation solutions like confining guests to dedicated cores. - - The kernel provides a sysfs interface to retrieve the status of SMT and - to control it. It also provides a kernel command line interface to - control SMT. - - The kernel command line interface consists of the following options: - - =========== ========================================================== - nosmt Affects the bring up of the secondary CPUs during boot. The - kernel tries to bring all present CPUs online during the - boot process. "nosmt" makes sure that from each physical - core only one - the so called primary (hyper) thread is - activated. Due to a design flaw of Intel processors related - to Machine Check Exceptions the non primary siblings have - to be brought up at least partially and are then shut down - again. "nosmt" can be undone via the sysfs interface. - - nosmt=force Has the same effect as "nosmt" but it does not allow to - undo the SMT disable via the sysfs interface. - =========== ========================================================== - - The sysfs interface provides two files: - - - /sys/devices/system/cpu/smt/control - - /sys/devices/system/cpu/smt/active - - /sys/devices/system/cpu/smt/control: - - This file allows to read out the SMT control state and provides the - ability to disable or (re)enable SMT. The possible states are: - - ============== =================================================== - on SMT is supported by the CPU and enabled. All - logical CPUs can be onlined and offlined without - restrictions. - - off SMT is supported by the CPU and disabled. Only - the so called primary SMT threads can be onlined - and offlined without restrictions. An attempt to - online a non-primary sibling is rejected - - forceoff Same as 'off' but the state cannot be controlled. - Attempts to write to the control file are rejected. - - notsupported The processor does not support SMT. It's therefore - not affected by the SMT implications of L1TF. - Attempts to write to the control file are rejected. - ============== =================================================== - - The possible states which can be written into this file to control SMT - state are: - - - on - - off - - forceoff - - /sys/devices/system/cpu/smt/active: - - This file reports whether SMT is enabled and active, i.e. if on any - physical core two or more sibling threads are online. - - SMT control is also possible at boot time via the l1tf kernel command - line parameter in combination with L1D flush control. See - :ref:`mitigation_control_command_line`. - -5. Disabling EPT -^^^^^^^^^^^^^^^^ - - Disabling EPT for virtual machines provides full mitigation for L1TF even - with SMT enabled, because the effective page tables for guests are - managed and sanitized by the hypervisor. Though disabling EPT has a - significant performance impact especially when the Meltdown mitigation - KPTI is enabled. - - EPT can be disabled in the hypervisor via the 'kvm-intel.ept' parameter. - -There is ongoing research and development for new mitigation mechanisms to -address the performance impact of disabling SMT or EPT. - -.. _mitigation_control_command_line: - -Mitigation control on the kernel command line ---------------------------------------------- - -The kernel command line allows to control the L1TF mitigations at boot -time with the option "l1tf=". The valid arguments for this option are: - - ============ ============================================================= - full Provides all available mitigations for the L1TF - vulnerability. Disables SMT and enables all mitigations in - the hypervisors, i.e. unconditional L1D flushing - - SMT control and L1D flush control via the sysfs interface - is still possible after boot. Hypervisors will issue a - warning when the first VM is started in a potentially - insecure configuration, i.e. SMT enabled or L1D flush - disabled. - - full,force Same as 'full', but disables SMT and L1D flush runtime - control. Implies the 'nosmt=force' command line option. - (i.e. sysfs control of SMT is disabled.) - - flush Leaves SMT enabled and enables the default hypervisor - mitigation, i.e. conditional L1D flushing - - SMT control and L1D flush control via the sysfs interface - is still possible after boot. Hypervisors will issue a - warning when the first VM is started in a potentially - insecure configuration, i.e. SMT enabled or L1D flush - disabled. - - flush,nosmt Disables SMT and enables the default hypervisor mitigation, - i.e. conditional L1D flushing. - - SMT control and L1D flush control via the sysfs interface - is still possible after boot. Hypervisors will issue a - warning when the first VM is started in a potentially - insecure configuration, i.e. SMT enabled or L1D flush - disabled. - - flush,nowarn Same as 'flush', but hypervisors will not warn when a VM is - started in a potentially insecure configuration. - - off Disables hypervisor mitigations and doesn't emit any - warnings. - It also drops the swap size and available RAM limit restrictions - on both hypervisor and bare metal. - - ============ ============================================================= - -The default is 'flush'. For details about L1D flushing see :ref:`l1d_flush`. - - -.. _mitigation_control_kvm: - -Mitigation control for KVM - module parameter -------------------------------------------------------------- - -The KVM hypervisor mitigation mechanism, flushing the L1D cache when -entering a guest, can be controlled with a module parameter. - -The option/parameter is "kvm-intel.vmentry_l1d_flush=". It takes the -following arguments: - - ============ ============================================================== - always L1D cache flush on every VMENTER. - - cond Flush L1D on VMENTER only when the code between VMEXIT and - VMENTER can leak host memory which is considered - interesting for an attacker. This still can leak host memory - which allows e.g. to determine the hosts address space layout. - - never Disables the mitigation - ============ ============================================================== - -The parameter can be provided on the kernel command line, as a module -parameter when loading the modules and at runtime modified via the sysfs -file: - -/sys/module/kvm_intel/parameters/vmentry_l1d_flush - -The default is 'cond'. If 'l1tf=full,force' is given on the kernel command -line, then 'always' is enforced and the kvm-intel.vmentry_l1d_flush -module parameter is ignored and writes to the sysfs file are rejected. - - -Mitigation selection guide --------------------------- - -1. No virtualization in use -^^^^^^^^^^^^^^^^^^^^^^^^^^^ - - The system is protected by the kernel unconditionally and no further - action is required. - -2. Virtualization with trusted guests -^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ - - If the guest comes from a trusted source and the guest OS kernel is - guaranteed to have the L1TF mitigations in place the system is fully - protected against L1TF and no further action is required. - - To avoid the overhead of the default L1D flushing on VMENTER the - administrator can disable the flushing via the kernel command line and - sysfs control files. See :ref:`mitigation_control_command_line` and - :ref:`mitigation_control_kvm`. - - -3. Virtualization with untrusted guests -^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ - -3.1. SMT not supported or disabled -"""""""""""""""""""""""""""""""""" - - If SMT is not supported by the processor or disabled in the BIOS or by - the kernel, it's only required to enforce L1D flushing on VMENTER. - - Conditional L1D flushing is the default behaviour and can be tuned. See - :ref:`mitigation_control_command_line` and :ref:`mitigation_control_kvm`. - -3.2. EPT not supported or disabled -"""""""""""""""""""""""""""""""""" - - If EPT is not supported by the processor or disabled in the hypervisor, - the system is fully protected. SMT can stay enabled and L1D flushing on - VMENTER is not required. - - EPT can be disabled in the hypervisor via the 'kvm-intel.ept' parameter. - -3.3. SMT and EPT supported and active -""""""""""""""""""""""""""""""""""""" - - If SMT and EPT are supported and active then various degrees of - mitigations can be employed: - - - L1D flushing on VMENTER: - - L1D flushing on VMENTER is the minimal protection requirement, but it - is only potent in combination with other mitigation methods. - - Conditional L1D flushing is the default behaviour and can be tuned. See - :ref:`mitigation_control_command_line` and :ref:`mitigation_control_kvm`. - - - Guest confinement: - - Confinement of guests to a single or a group of physical cores which - are not running any other processes, can reduce the attack surface - significantly, but interrupts, soft interrupts and kernel threads can - still expose valuable data to a potential attacker. See - :ref:`guest_confinement`. - - - Interrupt isolation: - - Isolating the guest CPUs from interrupts can reduce the attack surface - further, but still allows a malicious guest to explore a limited amount - of host physical memory. This can at least be used to gain knowledge - about the host address space layout. The interrupts which have a fixed - affinity to the CPUs which run the untrusted guests can depending on - the scenario still trigger soft interrupts and schedule kernel threads - which might expose valuable information. See - :ref:`interrupt_isolation`. - -The above three mitigation methods combined can provide protection to a -certain degree, but the risk of the remaining attack surface has to be -carefully analyzed. For full protection the following methods are -available: - - - Disabling SMT: - - Disabling SMT and enforcing the L1D flushing provides the maximum - amount of protection. This mitigation is not depending on any of the - above mitigation methods. - - SMT control and L1D flushing can be tuned by the command line - parameters 'nosmt', 'l1tf', 'kvm-intel.vmentry_l1d_flush' and at run - time with the matching sysfs control files. See :ref:`smt_control`, - :ref:`mitigation_control_command_line` and - :ref:`mitigation_control_kvm`. - - - Disabling EPT: - - Disabling EPT provides the maximum amount of protection as well. It is - not depending on any of the above mitigation methods. SMT can stay - enabled and L1D flushing is not required, but the performance impact is - significant. - - EPT can be disabled in the hypervisor via the 'kvm-intel.ept' - parameter. - -3.4. Nested virtual machines -"""""""""""""""""""""""""""" - -When nested virtualization is in use, three operating systems are involved: -the bare metal hypervisor, the nested hypervisor and the nested virtual -machine. VMENTER operations from the nested hypervisor into the nested -guest will always be processed by the bare metal hypervisor. If KVM is the -bare metal hypervisor it will: - - - Flush the L1D cache on every switch from the nested hypervisor to the - nested virtual machine, so that the nested hypervisor's secrets are not - exposed to the nested virtual machine; - - - Flush the L1D cache on every switch from the nested virtual machine to - the nested hypervisor; this is a complex operation, and flushing the L1D - cache avoids that the bare metal hypervisor's secrets are exposed to the - nested virtual machine; - - - Instruct the nested hypervisor to not perform any L1D cache flush. This - is an optimization to avoid double L1D flushing. - - -.. _default_mitigations: - -Default mitigations -------------------- - - The kernel default mitigations for vulnerable processors are: - - - PTE inversion to protect against malicious user space. This is done - unconditionally and cannot be controlled. The swap storage is limited - to ~16TB. - - - L1D conditional flushing on VMENTER when EPT is enabled for - a guest. - - The kernel does not by default enforce the disabling of SMT, which leaves - SMT systems vulnerable when running untrusted guests with EPT enabled. - - The rationale for this choice is: - - - Force disabling SMT can break existing setups, especially with - unattended updates. - - - If regular users run untrusted guests on their machine, then L1TF is - just an add on to other malware which might be embedded in an untrusted - guest, e.g. spam-bots or attacks on the local network. - - There is no technical way to prevent a user from running untrusted code - on their machines blindly. - - - It's technically extremely unlikely and from today's knowledge even - impossible that L1TF can be exploited via the most popular attack - mechanisms like JavaScript because these mechanisms have no way to - control PTEs. If this would be possible and not other mitigation would - be possible, then the default might be different. - - - The administrators of cloud and hosting setups have to carefully - analyze the risk for their scenarios and make the appropriate - mitigation choices, which might even vary across their deployed - machines and also result in other changes of their overall setup. - There is no way for the kernel to provide a sensible default for this - kind of scenarios. diff --git a/Documentation/index.rst b/Documentation/index.rst index 80a421cb935e..3511400dc092 100644 --- a/Documentation/index.rst +++ b/Documentation/index.rst @@ -102,6 +102,7 @@ implementation. :maxdepth: 2 sh/index + x86/index Filesystem Documentation ------------------------ diff --git a/Documentation/x86/conf.py b/Documentation/x86/conf.py new file mode 100644 index 000000000000..33c5c3142e20 --- /dev/null +++ b/Documentation/x86/conf.py @@ -0,0 +1,10 @@ +# -*- coding: utf-8; mode: python -*- + +project = "X86 architecture specific documentation" + +tags.add("subproject") + +latex_documents = [ + ('index', 'x86.tex', project, + 'The kernel development community', 'manual'), +] diff --git a/Documentation/x86/index.rst b/Documentation/x86/index.rst new file mode 100644 index 000000000000..ef389dcf1b1d --- /dev/null +++ b/Documentation/x86/index.rst @@ -0,0 +1,8 @@ +========================== +x86 architecture specifics +========================== + +.. toctree:: + :maxdepth: 1 + + mds diff --git a/Documentation/x86/mds.rst b/Documentation/x86/mds.rst new file mode 100644 index 000000000000..534e9baa4e1d --- /dev/null +++ b/Documentation/x86/mds.rst @@ -0,0 +1,225 @@ +Microarchitectural Data Sampling (MDS) mitigation +================================================= + +.. _mds: + +Overview +-------- + +Microarchitectural Data Sampling (MDS) is a family of side channel attacks +on internal buffers in Intel CPUs. The variants are: + + - Microarchitectural Store Buffer Data Sampling (MSBDS) (CVE-2018-12126) + - Microarchitectural Fill Buffer Data Sampling (MFBDS) (CVE-2018-12130) + - Microarchitectural Load Port Data Sampling (MLPDS) (CVE-2018-12127) + - Microarchitectural Data Sampling Uncacheable Memory (MDSUM) (CVE-2019-11091) + +MSBDS leaks Store Buffer Entries which can be speculatively forwarded to a +dependent load (store-to-load forwarding) as an optimization. The forward +can also happen to a faulting or assisting load operation for a different +memory address, which can be exploited under certain conditions. Store +buffers are partitioned between Hyper-Threads so cross thread forwarding is +not possible. But if a thread enters or exits a sleep state the store +buffer is repartitioned which can expose data from one thread to the other. + +MFBDS leaks Fill Buffer Entries. Fill buffers are used internally to manage +L1 miss situations and to hold data which is returned or sent in response +to a memory or I/O operation. Fill buffers can forward data to a load +operation and also write data to the cache. When the fill buffer is +deallocated it can retain the stale data of the preceding operations which +can then be forwarded to a faulting or assisting load operation, which can +be exploited under certain conditions. Fill buffers are shared between +Hyper-Threads so cross thread leakage is possible. + +MLPDS leaks Load Port Data. Load ports are used to perform load operations +from memory or I/O. The received data is then forwarded to the register +file or a subsequent operation. In some implementations the Load Port can +contain stale data from a previous operation which can be forwarded to +faulting or assisting loads under certain conditions, which again can be +exploited eventually. Load ports are shared between Hyper-Threads so cross +thread leakage is possible. + +MDSUM is a special case of MSBDS, MFBDS and MLPDS. An uncacheable load from +memory that takes a fault or assist can leave data in a microarchitectural +structure that may later be observed using one of the same methods used by +MSBDS, MFBDS or MLPDS. + +Exposure assumptions +-------------------- + +It is assumed that attack code resides in user space or in a guest with one +exception. The rationale behind this assumption is that the code construct +needed for exploiting MDS requires: + + - to control the load to trigger a fault or assist + + - to have a disclosure gadget which exposes the speculatively accessed + data for consumption through a side channel. + + - to control the pointer through which the disclosure gadget exposes the + data + +The existence of such a construct in the kernel cannot be excluded with +100% certainty, but the complexity involved makes it extremly unlikely. + +There is one exception, which is untrusted BPF. The functionality of +untrusted BPF is limited, but it needs to be thoroughly investigated +whether it can be used to create such a construct. + + +Mitigation strategy +------------------- + +All variants have the same mitigation strategy at least for the single CPU +thread case (SMT off): Force the CPU to clear the affected buffers. + +This is achieved by using the otherwise unused and obsolete VERW +instruction in combination with a microcode update. The microcode clears +the affected CPU buffers when the VERW instruction is executed. + +For virtualization there are two ways to achieve CPU buffer +clearing. Either the modified VERW instruction or via the L1D Flush +command. The latter is issued when L1TF mitigation is enabled so the extra +VERW can be avoided. If the CPU is not affected by L1TF then VERW needs to +be issued. + +If the VERW instruction with the supplied segment selector argument is +executed on a CPU without the microcode update there is no side effect +other than a small number of pointlessly wasted CPU cycles. + +This does not protect against cross Hyper-Thread attacks except for MSBDS +which is only exploitable cross Hyper-thread when one of the Hyper-Threads +enters a C-state. + +The kernel provides a function to invoke the buffer clearing: + + mds_clear_cpu_buffers() + +The mitigation is invoked on kernel/userspace, hypervisor/guest and C-state +(idle) transitions. + +As a special quirk to address virtualization scenarios where the host has +the microcode updated, but the hypervisor does not (yet) expose the +MD_CLEAR CPUID bit to guests, the kernel issues the VERW instruction in the +hope that it might actually clear the buffers. The state is reflected +accordingly. + +According to current knowledge additional mitigations inside the kernel +itself are not required because the necessary gadgets to expose the leaked +data cannot be controlled in a way which allows exploitation from malicious +user space or VM guests. + +Kernel internal mitigation modes +-------------------------------- + + ======= ============================================================ + off Mitigation is disabled. Either the CPU is not affected or + mds=off is supplied on the kernel command line + + full Mitigation is enabled. CPU is affected and MD_CLEAR is + advertised in CPUID. + + vmwerv Mitigation is enabled. CPU is affected and MD_CLEAR is not + advertised in CPUID. That is mainly for virtualization + scenarios where the host has the updated microcode but the + hypervisor does not expose MD_CLEAR in CPUID. It's a best + effort approach without guarantee. + ======= ============================================================ + +If the CPU is affected and mds=off is not supplied on the kernel command +line then the kernel selects the appropriate mitigation mode depending on +the availability of the MD_CLEAR CPUID bit. + +Mitigation points +----------------- + +1. Return to user space +^^^^^^^^^^^^^^^^^^^^^^^ + + When transitioning from kernel to user space the CPU buffers are flushed + on affected CPUs when the mitigation is not disabled on the kernel + command line. The migitation is enabled through the static key + mds_user_clear. + + The mitigation is invoked in prepare_exit_to_usermode() which covers + most of the kernel to user space transitions. There are a few exceptions + which are not invoking prepare_exit_to_usermode() on return to user + space. These exceptions use the paranoid exit code. + + - Non Maskable Interrupt (NMI): + + Access to sensible data like keys, credentials in the NMI context is + mostly theoretical: The CPU can do prefetching or execute a + misspeculated code path and thereby fetching data which might end up + leaking through a buffer. + + But for mounting other attacks the kernel stack address of the task is + already valuable information. So in full mitigation mode, the NMI is + mitigated on the return from do_nmi() to provide almost complete + coverage. + + - Double fault (#DF): + + A double fault is usually fatal, but the ESPFIX workaround, which can + be triggered from user space through modify_ldt(2) is a recoverable + double fault. #DF uses the paranoid exit path, so explicit mitigation + in the double fault handler is required. + + - Machine Check Exception (#MC): + + Another corner case is a #MC which hits between the CPU buffer clear + invocation and the actual return to user. As this still is in kernel + space it takes the paranoid exit path which does not clear the CPU + buffers. So the #MC handler repopulates the buffers to some + extent. Machine checks are not reliably controllable and the window is + extremly small so mitigation would just tick a checkbox that this + theoretical corner case is covered. To keep the amount of special + cases small, ignore #MC. + + - Debug Exception (#DB): + + This takes the paranoid exit path only when the INT1 breakpoint is in + kernel space. #DB on a user space address takes the regular exit path, + so no extra mitigation required. + + +2. C-State transition +^^^^^^^^^^^^^^^^^^^^^ + + When a CPU goes idle and enters a C-State the CPU buffers need to be + cleared on affected CPUs when SMT is active. This addresses the + repartitioning of the store buffer when one of the Hyper-Threads enters + a C-State. + + When SMT is inactive, i.e. either the CPU does not support it or all + sibling threads are offline CPU buffer clearing is not required. + + The idle clearing is enabled on CPUs which are only affected by MSBDS + and not by any other MDS variant. The other MDS variants cannot be + protected against cross Hyper-Thread attacks because the Fill Buffer and + the Load Ports are shared. So on CPUs affected by other variants, the + idle clearing would be a window dressing exercise and is therefore not + activated. + + The invocation is controlled by the static key mds_idle_clear which is + switched depending on the chosen mitigation mode and the SMT state of + the system. + + The buffer clear is only invoked before entering the C-State to prevent + that stale data from the idling CPU from spilling to the Hyper-Thread + sibling after the store buffer got repartitioned and all entries are + available to the non idle sibling. + + When coming out of idle the store buffer is partitioned again so each + sibling has half of it available. The back from idle CPU could be then + speculatively exposed to contents of the sibling. The buffers are + flushed either on exit to user space or on VMENTER so malicious code + in user space or the guest cannot speculatively access them. + + The mitigation is hooked into all variants of halt()/mwait(), but does + not cover the legacy ACPI IO-Port mechanism because the ACPI idle driver + has been superseded by the intel_idle driver around 2010 and is + preferred on all affected CPUs which are expected to gain the MD_CLEAR + functionality in microcode. Aside of that the IO-Port mechanism is a + legacy interface which is only used on older systems which are either + not affected or do not receive microcode updates anymore. diff --git a/Makefile b/Makefile index bf604f77e5e5..58ec07990e76 100644 --- a/Makefile +++ b/Makefile @@ -1,7 +1,7 @@ # SPDX-License-Identifier: GPL-2.0 VERSION = 5 PATCHLEVEL = 1 -SUBLEVEL = 1 +SUBLEVEL = 2 EXTRAVERSION = NAME = Shy Crocodile diff --git a/arch/powerpc/kernel/security.c b/arch/powerpc/kernel/security.c index b33bafb8fcea..70568ccbd9fd 100644 --- a/arch/powerpc/kernel/security.c +++ b/arch/powerpc/kernel/security.c @@ -57,7 +57,7 @@ void setup_barrier_nospec(void) enable = security_ftr_enabled(SEC_FTR_FAVOUR_SECURITY) && security_ftr_enabled(SEC_FTR_BNDS_CHK_SPEC_BAR); - if (!no_nospec) + if (!no_nospec && !cpu_mitigations_off()) enable_barrier_nospec(enable); } @@ -116,7 +116,7 @@ static int __init handle_nospectre_v2(char *p) early_param("nospectre_v2", handle_nospectre_v2); void setup_spectre_v2(void) { - if (no_spectrev2) + if (no_spectrev2 || cpu_mitigations_off()) do_btb_flush_fixups(); else btb_flush_enabled = true; @@ -300,7 +300,7 @@ void setup_stf_barrier(void) stf_enabled_flush_types = type; - if (!no_stf_barrier) + if (!no_stf_barrier && !cpu_mitigations_off()) stf_barrier_enable(enable); } diff --git a/arch/powerpc/kernel/setup_64.c b/arch/powerpc/kernel/setup_64.c index ba404dd9ce1d..4f49e1a3594c 100644 --- a/arch/powerpc/kernel/setup_64.c +++ b/arch/powerpc/kernel/setup_64.c @@ -932,7 +932,7 @@ void setup_rfi_flush(enum l1d_flush_type types, bool enable) enabled_flush_types = types; - if (!no_rfi_flush) + if (!no_rfi_flush && !cpu_mitigations_off()) rfi_flush_enable(enable); } diff --git a/arch/s390/kernel/nospec-branch.c b/arch/s390/kernel/nospec-branch.c index bdddaae96559..649135cbedd5 100644 --- a/arch/s390/kernel/nospec-branch.c +++ b/arch/s390/kernel/nospec-branch.c @@ -1,6 +1,7 @@ // SPDX-License-Identifier: GPL-2.0 #include <linux/module.h> #include <linux/device.h> +#include <linux/cpu.h> #include <asm/nospec-branch.h> static int __init nobp_setup_early(char *str) @@ -58,7 +59,7 @@ early_param("nospectre_v2", nospectre_v2_setup_early); void __init nospec_auto_detect(void) { - if (test_facility(156)) { + if (test_facility(156) || cpu_mitigations_off()) { /* * The machine supports etokens. * Disable expolines and disable nobp. diff --git a/arch/x86/entry/common.c b/arch/x86/entry/common.c index 7bc105f47d21..19f650d729f5 100644 --- a/arch/x86/entry/common.c +++ b/arch/x86/entry/common.c @@ -31,6 +31,7 @@ #include <asm/vdso.h> #include <linux/uaccess.h> #include <asm/cpufeature.h> +#include <asm/nospec-branch.h> #define CREATE_TRACE_POINTS #include <trace/events/syscalls.h> @@ -212,6 +213,8 @@ __visible inline void prepare_exit_to_usermode(struct pt_regs *regs) #endif user_enter_irqoff(); + + mds_user_clear_cpu_buffers(); } #define SYSCALL_EXIT_WORK_FLAGS \ diff --git a/arch/x86/include/asm/cpufeatures.h b/arch/x86/include/asm/cpufeatures.h index 981ff9479648..75f27ee2c263 100644 --- a/arch/x86/include/asm/cpufeatures.h +++ b/arch/x86/include/asm/cpufeatures.h @@ -344,6 +344,7 @@ /* Intel-defined CPU features, CPUID level 0x00000007:0 (EDX), word 18 */ #define X86_FEATURE_AVX512_4VNNIW (18*32+ 2) /* AVX-512 Neural Network Instructions */ #define X86_FEATURE_AVX512_4FMAPS (18*32+ 3) /* AVX-512 Multiply Accumulation Single precision */ +#define X86_FEATURE_MD_CLEAR (18*32+10) /* VERW clears CPU buffers */ #define X86_FEATURE_TSX_FORCE_ABORT (18*32+13) /* "" TSX_FORCE_ABORT */ #define X86_FEATURE_PCONFIG (18*32+18) /* Intel PCONFIG */ #define X86_FEATURE_SPEC_CTRL (18*32+26) /* "" Speculation Control (IBRS + IBPB) */ @@ -382,5 +383,7 @@ #define X86_BUG_SPECTRE_V2 X86_BUG(16) /* CPU is affected by Spectre variant 2 attack with indirect branches */ #define X86_BUG_SPEC_STORE_BYPASS X86_BUG(17) /* CPU is affected by speculative store bypass attack */ #define X86_BUG_L1TF X86_BUG(18) /* CPU is affected by L1 Terminal Fault */ +#define X86_BUG_MDS X86_BUG(19) /* CPU is affected by Microarchitectural data sampling */ +#define X86_BUG_MSBDS_ONLY X86_BUG(20) /* CPU is only affected by the MSDBS variant of BUG_MDS */ #endif /* _ASM_X86_CPUFEATURES_H */ diff --git a/arch/x86/include/asm/irqflags.h b/arch/x86/include/asm/irqflags.h index 058e40fed167..8a0e56e1dcc9 100644 --- a/arch/x86/include/asm/irqflags.h +++ b/arch/x86/include/asm/irqflags.h @@ -6,6 +6,8 @@ #ifndef __ASSEMBLY__ +#include <asm/nospec-branch.h> + /* Provide __cpuidle; we can't safely include <linux/cpu.h> */ #define __cpuidle __attribute__((__section__(".cpuidle.text"))) @@ -54,11 +56,13 @@ static inline void native_irq_enable(void) static inline __cpuidle void native_safe_halt(void) { + mds_idle_clear_cpu_buffers(); asm volatile("sti; hlt": : :"memory"); } static inline __cpuidle void native_halt(void) { + mds_idle_clear_cpu_buffers(); asm volatile("hlt": : :"memory"); } diff --git a/arch/x86/include/asm/msr-index.h b/arch/x86/include/asm/msr-index.h index ca5bc0eacb95..20f7da552e90 100644 --- a/arch/x86/include/asm/msr-index.h +++ b/arch/x86/include/asm/msr-index.h @@ -2,6 +2,8 @@ #ifndef _ASM_X86_MSR_INDEX_H #define _ASM_X86_MSR_INDEX_H +#include <linux/bits.h> + /* * CPU model specific register (MSR) numbers. * @@ -40,14 +42,14 @@ /* Intel MSRs. Some also available on other CPUs */ #define MSR_IA32_SPEC_CTRL 0x00000048 /* Speculation Control */ -#define SPEC_CTRL_IBRS (1 << 0) /* Indirect Branch Restricted Speculation */ +#define SPEC_CTRL_IBRS BIT(0) /* Indirect Branch Restricted Speculation */ #define SPEC_CTRL_STIBP_SHIFT 1 /* Single Thread Indirect Branch Predictor (STIBP) bit */ -#define SPEC_CTRL_STIBP (1 << SPEC_CTRL_STIBP_SHIFT) /* STIBP mask */ +#define SPEC_CTRL_STIBP BIT(SPEC_CTRL_STIBP_SHIFT) /* STIBP mask */ #define SPEC_CTRL_SSBD_SHIFT 2 /* Speculative Store Bypass Disable bit */ -#define SPEC_CTRL_SSBD (1 << SPEC_CTRL_SSBD_SHIFT) /* Speculative Store Bypass Disable */ +#define SPEC_CTRL_SSBD BIT(SPEC_CTRL_SSBD_SHIFT) /* Speculative Store Bypass Disable */ #define MSR_IA32_PRED_CMD 0x00000049 /* Prediction Command */ -#define PRED_CMD_IBPB (1 << 0) /* Indirect Branch Prediction Barrier */ +#define PRED_CMD_IBPB BIT(0) /* Indirect Branch Prediction Barrier */ #define MSR_PPIN_CTL 0x0000004e #define MSR_PPIN 0x0000004f @@ -69,20 +71,25 @@ #define MSR_MTRRcap 0x000000fe #define MSR_IA32_ARCH_CAPABILITIES 0x0000010a -#define ARCH_CAP_RDCL_NO (1 << 0) /* Not susceptible to Meltdown */ -#define ARCH_CAP_IBRS_ALL (1 << 1) /* Enhanced IBRS support */ -#define ARCH_CAP_SKIP_VMENTRY_L1DFLUSH (1 << 3) /* Skip L1D flush on vmentry */ -#define ARCH_CAP_SSB_NO (1 << 4) /* - * Not susceptible to Speculative Store Bypass - * attack, so no Speculative Store Bypass - * control required. - */ +#define ARCH_CAP_RDCL_NO BIT(0) /* Not susceptible to Meltdown */ +#define ARCH_CAP_IBRS_ALL BIT(1) /* Enhanced IBRS support */ +#define ARCH_CAP_SKIP_VMENTRY_L1DFLUSH BIT(3) /* Skip L1D flush on vmentry */ +#define ARCH_CAP_SSB_NO BIT(4) /* + * Not susceptible to Speculative Store Bypass + * attack, so no Speculative Store Bypass + * control required. + */ +#define ARCH_CAP_MDS_NO BIT(5) /* + * Not susceptible to + * Microarchitectural Data + * Sampling (MDS) vulnerabilities. + */ #define MSR_IA32_FLUSH_CMD 0x0000010b -#define L1D_FLUSH (1 << 0) /* - * Writeback and invalidate the - * L1 data cache. - */ +#define L1D_FLUSH BIT(0) /* + * Writeback and invalidate the + * L1 data cache. + */ #define MSR_IA32_BBL_CR_CTL 0x00000119 #define MSR_IA32_BBL_CR_CTL3 0x0000011e diff --git a/arch/x86/include/asm/mwait.h b/arch/x86/include/asm/mwait.h index 39a2fb29378a..eb0f80ce8524 100644 --- a/arch/x86/include/asm/mwait.h +++ b/arch/x86/include/asm/mwait.h @@ -6,6 +6,7 @@ #include <linux/sched/idle.h> #include <asm/cpufeature.h> +#include <asm/nospec-branch.h> #define MWAIT_SUBSTATE_MASK 0xf #define MWAIT_CSTATE_MASK 0xf @@ -40,6 +41,8 @@ static inline void __monitorx(const void *eax, unsigned long ecx, static inline void __mwait(unsigned long eax, unsigned long ecx) { + mds_idle_clear_cpu_buffers(); + /* "mwait %eax, %ecx;" */ asm volatile(".byte 0x0f, 0x01, 0xc9;" :: "a" (eax), "c" (ecx)); @@ -74,6 +77,8 @@ static inline void __mwait(unsigned long eax, unsigned long ecx) static inline void __mwaitx(unsigned long eax, unsigned long ebx, unsigned long ecx) { + /* No MDS buffer clear as this is AMD/HYGON only */ + /* "mwaitx %eax, %ebx, %ecx;" */ asm volatile(".byte 0x0f, 0x01, 0xfb;" :: "a" (eax), "b" (ebx), "c" (ecx)); @@ -81,6 +86,8 @@ static inline void __mwaitx(unsigned long eax, unsigned long ebx, static inline void __sti_mwait(unsigned long eax, unsigned long ecx) { + mds_idle_clear_cpu_buffers(); + trace_hardirqs_on(); /* "mwait %eax, %ecx;" */ asm volatile("sti; .byte 0x0f, 0x01, 0xc9;" diff --git a/arch/x86/include/asm/nospec-branch.h b/arch/x86/include/asm/nospec-branch.h index dad12b767ba0..4e970390110f 100644 --- a/arch/x86/include/asm/nospec-branch.h +++ b/arch/x86/include/asm/nospec-branch.h @@ -318,6 +318,56 @@ DECLARE_STATIC_KEY_FALSE(switch_to_cond_stibp); DECLARE_STATIC_KEY_FALSE(switch_mm_cond_ibpb); DECLARE_STATIC_KEY_FALSE(switch_mm_always_ibpb); +DECLARE_STATIC_KEY_FALSE(mds_user_clear); +DECLARE_STATIC_KEY_FALSE(mds_idle_clear); + +#include <asm/segment.h> + +/** + * mds_clear_cpu_buffers - Mitigation for MDS vulnerability + * + * This uses the otherwise unused and obsolete VERW instruction in + * combination with microcode which triggers a CPU buffer flush when the + * instruction is executed. + */ +static inline void mds_clear_cpu_buffers(void) +{ + static const u16 ds = __KERNEL_DS; + + /* + * Has to be the memory-operand variant because only that + * guarantees the CPU buffer flush functionality according to + * documentation. The register-operand variant does not. + * Works with any segment selector, but a valid writable + * data segment is the fastest variant. + * + * "cc" clobber is required because VERW modifies ZF. + */ + asm volatile("verw %[ds]" : : [ds] "m" (ds) : "cc"); +} + +/** + * mds_user_clear_cpu_buffers - Mitigation for MDS vulnerability + * + * Clear CPU buffers if the corresponding static key is enabled + */ +static inline void mds_user_clear_cpu_buffers(void) +{ + if (static_branch_likely(&mds_user_clear)) + mds_clear_cpu_buffers(); +} + +/** + * mds_idle_clear_cpu_buffers - Mitigation for MDS vulnerability + * + * Clear CPU buffers if the corresponding static key is enabled + */ +static inline void mds_idle_clear_cpu_buffers(void) +{ + if (static_branch_likely(&mds_idle_clear)) + mds_clear_cpu_buffers(); +} + #endif /* __ASSEMBLY__ */ /* diff --git a/arch/x86/include/asm/processor.h b/arch/x86/include/asm/processor.h index 2bb3a648fc12..31e9895db75e 100644 --- a/arch/x86/include/asm/processor.h +++ b/arch/x86/include/asm/processor.h @@ -991,4 +991,10 @@ enum l1tf_mitigations { extern enum l1tf_mitigations l1tf_mitigation; +enum mds_mitigations { + MDS_MITIGATION_OFF, + MDS_MITIGATION_FULL, + MDS_MITIGATION_VMWERV, +}; + #endif /* _ASM_X86_PROCESSOR_H */ diff --git a/arch/x86/kernel/cpu/bugs.c b/arch/x86/kernel/cpu/bugs.c index b91b3bfa5cfb..03b4cc0ec3a7 100644 --- a/arch/x86/kernel/cpu/bugs.c +++ b/arch/x86/kernel/cpu/bugs.c @@ -37,6 +37,7 @@ static void __init spectre_v2_select_mitigation(void); static void __init ssb_select_mitigation(void); static void __init l1tf_select_mitigation(void); +static void __init mds_select_mitigation(void); /* The base value of the SPEC_CTRL MSR that always has to be preserved. */ u64 x86_spec_ctrl_base; @@ -63,6 +64,13 @@ DEFINE_STATIC_KEY_FALSE(switch_mm_cond_ibpb); /* Control unconditional IBPB in switch_mm() */ DEFINE_STATIC_KEY_FALSE(switch_mm_always_ibpb); +/* Control MDS CPU buffer clear before returning to user space */ +DEFINE_STATIC_KEY_FALSE(mds_user_clear); +EXPORT_SYMBOL_GPL(mds_user_clear); +/* Control MDS CPU buffer clear before idling (halt, mwait) */ +DEFINE_STATIC_KEY_FALSE(mds_idle_clear); +EXPORT_SYMBOL_GPL(mds_idle_clear); + void __init check_bugs(void) { identify_boot_cpu(); @@ -101,6 +109,10 @@ void __init check_bugs(void) l1tf_select_mitigation(); + mds_select_mitigation(); + + arch_smt_update(); + #ifdef CONFIG_X86_32 /* * Check whether we are able to run this kernel safely on SMP. @@ -206,6 +218,61 @@ static void x86_amd_ssb_disable(void) wrmsrl(MSR_AMD64_LS_CFG, msrval); } +#undef pr_fmt +#define pr_fmt(fmt) "MDS: " fmt + +/* Default mitigation for MDS-affected CPUs */ +static enum mds_mitigations mds_mitigation __ro_after_init = MDS_MITIGATION_FULL; +static bool mds_nosmt __ro_after_init = false; + +static const char * const mds_strings[] = { + [MDS_MITIGATION_OFF] = "Vulnerable", + [MDS_MITIGATION_FULL] = "Mitigation: Clear CPU buffers", + [MDS_MITIGATION_VMWERV] = "Vulnerable: Clear CPU buffers attempted, no microcode", +}; + +static void __init mds_select_mitigation(void) +{ + if (!boot_cpu_has_bug(X86_BUG_MDS) || cpu_mitigations_off()) { + mds_mitigation = MDS_MITIGATION_OFF; + return; + } + + if (mds_mitigation == MDS_MITIGATION_FULL) { + if (!boot_cpu_has(X86_FEATURE_MD_CLEAR)) + mds_mitigation = MDS_MITIGATION_VMWERV; + + static_branch_enable(&mds_user_clear); + + if (!boot_cpu_has(X86_BUG_MSBDS_ONLY) && + (mds_nosmt || cpu_mitigations_auto_nosmt())) + cpu_smt_disable(false); + } + + pr_info("%s\n", mds_strings[mds_mitigation]); +} + +static int __init mds_cmdline(char *str) +{ + if (!boot_cpu_has_bug(X86_BUG_MDS)) + return 0; + + if (!str) + return -EINVAL; + + if (!strcmp(str, "off")) + mds_mitigation = MDS_MITIGATION_OFF; + else if (!strcmp(str, "full")) + mds_mitigation = MDS_MITIGATION_FULL; + else if (!strcmp(str, "full,nosmt")) { + mds_mitigation = MDS_MITIGATION_FULL; + mds_nosmt = true; + } + + return 0; +} +early_param("mds", mds_cmdline); + #undef pr_fmt #define pr_fmt(fmt) "Spectre V2 : " fmt @@ -440,7 +507,8 @@ static enum spectre_v2_mitigation_cmd __init spectre_v2_parse_cmdline(void) char arg[20]; int ret, i; - if (cmdline_find_option_bool(boot_command_line, "nospectre_v2")) + if (cmdline_find_option_bool(boot_command_line, "nospectre_v2") || + cpu_mitigations_off()) return SPECTRE_V2_CMD_NONE; ret = cmdline_find_option(boot_command_line, "spectre_v2", arg, sizeof(arg)); @@ -574,9 +642,6 @@ static void __init spectre_v2_select_mitigation(void) /* Set up IBPB and STIBP depending on the general spectre V2 command */ spectre_v2_user_select_mitigation(cmd); - - /* Enable STIBP if appropriate */ - arch_smt_update(); } static void update_stibp_msr(void * __unused) @@ -610,6 +675,31 @@ static void update_indir_branch_cond(void) static_branch_disable(&switch_to_cond_stibp); } +#undef pr_fmt +#define pr_fmt(fmt) fmt + +/* Update the static key controlling the MDS CPU buffer clear in idle */ +static void update_mds_branch_idle(void) +{ + /* + * Enable the idle clearing if SMT is active on CPUs which are + * affected only by MSBDS and not any other MDS variant. + * + * The other variants cannot be mitigated when SMT is enabled, so + * clearing the buffers on idle just to prevent the Store Buffer + * repartitioning leak would be a window dressing exercise. + */ + if (!boot_cpu_has_bug(X86_BUG_MSBDS_ONLY)) + return; + + if (sched_smt_active()) + static_branch_enable(&mds_idle_clear); + else + static_branch_disable(&mds_idle_clear); +} + +#define MDS_MSG_SMT "MDS CPU bug present and SMT on, data leak possible. See https://www.kernel.org/doc/html/latest/admin-guide/hw-vuln/mds.html for more details.\n" + void arch_smt_update(void) { /* Enhanced IBRS implies STIBP. No update required. */ @@ -631,6 +721,17 @@ void arch_smt_update(void) break; } + switch (mds_mitigation) { + case MDS_MITIGATION_FULL: + case MDS_MITIGATION_VMWERV: + if (sched_smt_active() && !boot_cpu_has(X86_BUG_MSBDS_ONLY)) + pr_warn_once(MDS_MSG_SMT); + update_mds_branch_idle(); + break; + case MDS_MITIGATION_OFF: + break; + } + mutex_unlock(&spec_ctrl_mutex); } @@ -672,7 +773,8 @@ static enum ssb_mitigation_cmd __init ssb_parse_cmdline(void) char arg[20]; int ret, i; - if (cmdline_find_option_bool(boot_command_line, "nospec_store_bypass_disable")) { + if (cmdline_find_option_bool(boot_command_line, "nospec_store_bypass_disable") || + cpu_mitigations_off()) { return SPEC_STORE_BYPASS_CMD_NONE; } else { ret = cmdline_find_option(boot_command_line, "spec_store_bypass_disable", @@ -1008,6 +1110,11 @@ static void __init l1tf_select_mitigation(void) if (!boot_cpu_has_bug(X86_BUG_L1TF)) return; + if (cpu_mitigations_off()) + l1tf_mitigation = L1TF_MITIGATION_OFF; + else if (cpu_mitigations_auto_nosmt()) + l1tf_mitigation = L1TF_MITIGATION_FLUSH_NOSMT; + override_cache_bits(&boot_cpu_data); switch (l1tf_mitigation) { @@ -1036,7 +1143,7 @@ static void __init l1tf_select_mitigation(void) pr_info("You may make it effective by booting the kernel with mem=%llu parameter.\n", half_pa); pr_info("However, doing so will make a part of your RAM unusable.\n"); - pr_info("Reading https://www.kernel.org/doc/html/latest/admin-guide/l1tf.html might help you decide.\n"); + pr_info("Reading https://www.kernel.org/doc/html/latest/admin-guide/hw-vuln/l1tf.html might help you decide.\n"); return; } @@ -1069,6 +1176,7 @@ static int __init l1tf_cmdline(char *str) early_param("l1tf", l1tf_cmdline); #undef pr_fmt +#define pr_fmt(fmt) fmt #ifdef CONFIG_SYSFS @@ -1107,6 +1215,23 @@ static ssize_t l1tf_show_state(char *buf) } #endif +static ssize_t mds_show_state(char *buf) +{ + if (!hypervisor_is_type(X86_HYPER_NATIVE)) { + return sprintf(buf, "%s; SMT Host state unknown\n", + mds_strings[mds_mitigation]); + } + + if (boot_cpu_has(X86_BUG_MSBDS_ONLY)) { + return sprintf(buf, "%s; SMT %s\n", mds_strings[mds_mitigation], + (mds_mitigation == MDS_MITIGATION_OFF ? "vulnerable" : + sched_smt_active() ? "mitigated" : "disabled")); + } + + return sprintf(buf, "%s; SMT %s\n", mds_strings[mds_mitigation], + sched_smt_active() ? "vulnerable" : "disabled"); +} + static char *stibp_state(void) { if (spectre_v2_enabled == SPECTRE_V2_IBRS_ENHANCED) @@ -1173,6 +1298,10 @@ static ssize_t cpu_show_common(struct device *dev, struct device_attribute *attr if (boot_cpu_has(X86_FEATURE_L1TF_PTEINV)) return l1tf_show_state(buf); break; + + case X86_BUG_MDS: + return mds_show_state(buf); + default: break; } @@ -1204,4 +1333,9 @@ ssize_t cpu_show_l1tf(struct device *dev, struct device_attribute *attr, char *b { return cpu_show_common(dev, attr, buf, X86_BUG_L1TF); } + +ssize_t cpu_show_mds(struct device *dev, struct device_attribute *attr, char *buf) +{ + return cpu_show_common(dev, attr, buf, X86_BUG_MDS); +} #endif diff --git a/arch/x86/kernel/cpu/common.c b/arch/x86/kernel/cpu/common.c index cb28e98a0659..132a63dc5a76 100644 --- a/arch/x86/kernel/cpu/common.c +++ b/arch/x86/kernel/cpu/common.c @@ -948,61 +948,77 @@ static void identify_cpu_without_cpuid(struct cpuinfo_x86 *c) #endif } -static const __initconst struct x86_cpu_id cpu_no_speculation[] = { - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SALTWELL, X86_FEATURE_ANY }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SALTWELL_TABLET, X86_FEATURE_ANY }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_BONNELL_MID, X86_FEATURE_ANY }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SALTWELL_MID, X86_FEATURE_ANY }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_BONNELL, X86_FEATURE_ANY }, - { X86_VENDOR_CENTAUR, 5 }, - { X86_VENDOR_INTEL, 5 }, - { X86_VENDOR_NSC, 5 }, - { X86_VENDOR_ANY, 4 }, +#define NO_SPECULATION BIT(0) +#define NO_MELTDOWN BIT(1) +#define NO_SSB BIT(2) +#define NO_L1TF BIT(3) +#define NO_MDS BIT(4) +#define MSBDS_ONLY BIT(5) + +#define VULNWL(_vendor, _family, _model, _whitelist) \ + { X86_VENDOR_##_vendor, _family, _model, X86_FEATURE_ANY, _whitelist } + +#define VULNWL_INTEL(model, whitelist) \ + VULNWL(INTEL, 6, INTEL_FAM6_##model, whitelist) + +#define VULNWL_AMD(family, whitelist) \ + VULNWL(AMD, family, X86_MODEL_ANY, whitelist) + +#define VULNWL_HYGON(family, whitelist) \ + VULNWL(HYGON, family, X86_MODEL_ANY, whitelist) + +static const __initconst struct x86_cpu_id cpu_vuln_whitelist[] = { + VULNWL(ANY, 4, X86_MODEL_ANY, NO_SPECULATION), + VULNWL(CENTAUR, 5, X86_MODEL_ANY, NO_SPECULATION), + VULNWL(INTEL, 5, X86_MODEL_ANY, NO_SPECULATION), + VULNWL(NSC, 5, X86_MODEL_ANY, NO_SPECULATION), + + /* Intel Family 6 */ + VULNWL_INTEL(ATOM_SALTWELL, NO_SPECULATION), + VULNWL_INTEL(ATOM_SALTWELL_TABLET, NO_SPECULATION), + VULNWL_INTEL(ATOM_SALTWELL_MID, NO_SPECULATION), + VULNWL_INTEL(ATOM_BONNELL, NO_SPECULATION), + VULNWL_INTEL(ATOM_BONNELL_MID, NO_SPECULATION), + + VULNWL_INTEL(ATOM_SILVERMONT, NO_SSB | NO_L1TF | MSBDS_ONLY), + VULNWL_INTEL(ATOM_SILVERMONT_X, NO_SSB | NO_L1TF | MSBDS_ONLY), + VULNWL_INTEL(ATOM_SILVERMONT_MID, NO_SSB | NO_L1TF | MSBDS_ONLY), + VULNWL_INTEL(ATOM_AIRMONT, NO_SSB | NO_L1TF | MSBDS_ONLY), + VULNWL_INTEL(XEON_PHI_KNL, NO_SSB | NO_L1TF | MSBDS_ONLY), + VULNWL_INTEL(XEON_PHI_KNM, NO_SSB | NO_L1TF | MSBDS_ONLY), + + VULNWL_INTEL(CORE_YONAH, NO_SSB), + + VULNWL_INTEL(ATOM_AIRMONT_MID, NO_L1TF | MSBDS_ONLY), + + VULNWL_INTEL(ATOM_GOLDMONT, NO_MDS | NO_L1TF), + VULNWL_INTEL(ATOM_GOLDMONT_X, NO_MDS | NO_L1TF), + VULNWL_INTEL(ATOM_GOLDMONT_PLUS, NO_MDS | NO_L1TF), + + /* AMD Family 0xf - 0x12 */ + VULNWL_AMD(0x0f, NO_MELTDOWN | NO_SSB | NO_L1TF | NO_MDS), + VULNWL_AMD(0x10, NO_MELTDOWN | NO_SSB | NO_L1TF | NO_MDS), + VULNWL_AMD(0x11, NO_MELTDOWN | NO_SSB | NO_L1TF | NO_MDS), + VULNWL_AMD(0x12, NO_MELTDOWN | NO_SSB | NO_L1TF | NO_MDS), + + /* FAMILY_ANY must be last, otherwise 0x0f - 0x12 matches won't work */ + VULNWL_AMD(X86_FAMILY_ANY, NO_MELTDOWN | NO_L1TF | NO_MDS), + VULNWL_HYGON(X86_FAMILY_ANY, NO_MELTDOWN | NO_L1TF | NO_MDS), {} }; -static const __initconst struct x86_cpu_id cpu_no_meltdown[] = { - { X86_VENDOR_AMD }, - { X86_VENDOR_HYGON }, - {} -}; - -/* Only list CPUs which speculate but are non susceptible to SSB */ -static const __initconst struct x86_cpu_id cpu_no_spec_store_bypass[] = { - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SILVERMONT }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_AIRMONT }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SILVERMONT_X }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SILVERMONT_MID }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_CORE_YONAH }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_XEON_PHI_KNL }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_XEON_PHI_KNM }, - { X86_VENDOR_AMD, 0x12, }, - { X86_VENDOR_AMD, 0x11, }, - { X86_VENDOR_AMD, 0x10, }, - { X86_VENDOR_AMD, 0xf, }, - {} -}; +static bool __init cpu_matches(unsigned long which) +{ + const struct x86_cpu_id *m = x86_match_cpu(cpu_vuln_whitelist); -static const __initconst struct x86_cpu_id cpu_no_l1tf[] = { - /* in addition to cpu_no_speculation */ - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SILVERMONT }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SILVERMONT_X }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_AIRMONT }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_SILVERMONT_MID }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_AIRMONT_MID }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_GOLDMONT }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_GOLDMONT_X }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_GOLDMONT_PLUS }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_XEON_PHI_KNL }, - { X86_VENDOR_INTEL, 6, INTEL_FAM6_XEON_PHI_KNM }, - {} -}; + return m && !!(m->driver_data & which); +} static void __init cpu_set_bug_bits(struct cpuinfo_x86 *c) { u64 ia32_cap = 0; - if (x86_match_cpu(cpu_no_speculation)) + if (cpu_matches(NO_SPECULATION)) return; setup_force_cpu_bug(X86_BUG_SPECTRE_V1); @@ -1011,15 +1027,20 @@ static void __init cpu_set_bug_bits(struct cpuinfo_x86 *c) if (cpu_has(c, X86_FEATURE_ARCH_CAPABILITIES)) rdmsrl(MSR_IA32_ARCH_CAPABILITIES, ia32_cap); - if (!x86_match_cpu(cpu_no_spec_store_bypass) && - !(ia32_cap & ARCH_CAP_SSB_NO) && + if (!cpu_matches(NO_SSB) && !(ia32_cap & ARCH_CAP_SSB_NO) && !cpu_has(c, X86_FEATURE_AMD_SSB_NO)) setup_force_cpu_bug(X86_BUG_SPEC_STORE_BYPASS); if (ia32_cap & ARCH_CAP_IBRS_ALL) setup_force_cpu_cap(X86_FEATURE_IBRS_ENHANCED); - if (x86_match_cpu(cpu_no_meltdown)) + if (!cpu_matches(NO_MDS) && !(ia32_cap & ARCH_CAP_MDS_NO)) { + setup_force_cpu_bug(X86_BUG_MDS); + if (cpu_matches(MSBDS_ONLY)) + setup_force_cpu_bug(X86_BUG_MSBDS_ONLY); + } + + if (cpu_matches(NO_MELTDOWN)) return; /* Rogue Data Cache Load? No! */ @@ -1028,7 +1049,7 @@ static void __init cpu_set_bug_bits(struct cpuinfo_x86 *c) setup_force_cpu_bug(X86_BUG_CPU_MELTDOWN); - if (x86_match_cpu(cpu_no_l1tf)) + if (cpu_matches(NO_L1TF)) return; setup_force_cpu_bug(X86_BUG_L1TF); diff --git a/arch/x86/kernel/nmi.c b/arch/x86/kernel/nmi.c index 18bc9b51ac9b..086cf1d1d71d 100644 --- a/arch/x86/kernel/nmi.c +++ b/arch/x86/kernel/nmi.c @@ -34,6 +34,7 @@ #include <asm/x86_init.h> #include <asm/reboot.h> #include <asm/cache.h> +#include <asm/nospec-branch.h> #define CREATE_TRACE_POINTS #include <trace/events/nmi.h> @@ -533,6 +534,9 @@ do_nmi(struct pt_regs *regs, long error_code) write_cr2(this_cpu_read(nmi_cr2)); if (this_cpu_dec_return(nmi_state)) goto nmi_restart; + + if (user_mode(regs)) + mds_user_clear_cpu_buffers(); } NOKPROBE_SYMBOL(do_nmi); diff --git a/arch/x86/kernel/traps.c b/arch/x86/kernel/traps.c index d26f9e9c3d83..07c7bbe79e8b 100644 --- a/arch/x86/kernel/traps.c +++ b/arch/x86/kernel/traps.c @@ -58,6 +58,7 @@ #include <asm/alternative.h> #include <asm/fpu/xstate.h> #include <asm/trace/mpx.h> +#include <asm/nospec-branch.h> #include <asm/mpx.h> #include <asm/vm86.h> #include <asm/umip.h> @@ -367,6 +368,13 @@ dotraplinkage void do_double_fault(struct pt_regs *regs, long error_code) regs->ip = (unsigned long)general_protection; regs->sp = (unsigned long)&gpregs->orig_ax; + /* + * This situation can be triggered by userspace via + * modify_ldt(2) and the return does not take the regular + * user space exit, so a CPU buffer clear is required when + * MDS mitigation is enabled. + */ + mds_user_clear_cpu_buffers(); return; } #endif diff --git a/arch/x86/kvm/cpuid.c b/arch/x86/kvm/cpuid.c index fd3951638ae4..bbbe611f0c49 100644 --- a/arch/x86/kvm/cpuid.c +++ b/arch/x86/kvm/cpuid.c @@ -410,7 +410,8 @@ static inline int __do_cpuid_ent(struct kvm_cpuid_entry2 *entry, u32 function, /* cpuid 7.0.edx*/ const u32 kvm_cpuid_7_0_edx_x86_features = F(AVX512_4VNNIW) | F(AVX512_4FMAPS) | F(SPEC_CTRL) | - F(SPEC_CTRL_SSBD) | F(ARCH_CAPABILITIES) | F(INTEL_STIBP); + F(SPEC_CTRL_SSBD) | F(ARCH_CAPABILITIES) | F(INTEL_STIBP) | + F(MD_CLEAR); /* all calls to cpuid_count() should be made on the same cpu */ get_cpu(); diff --git a/arch/x86/kvm/vmx/vmx.c b/arch/x86/kvm/vmx/vmx.c index 0c955bb286ff..194c6ec11f4c 100644 --- a/arch/x86/kvm/vmx/vmx.c +++ b/arch/x86/kvm/vmx/vmx.c @@ -6431,8 +6431,11 @@ static void vmx_vcpu_run(struct kvm_vcpu *vcpu) */ x86_spec_ctrl_set_guest(vmx->spec_ctrl, 0); + /* L1D Flush includes CPU buffer clear to mitigate MDS */ if (static_branch_unlikely(&vmx_l1d_should_flush)) vmx_l1d_flush(vcpu); + else if (static_branch_unlikely(&mds_user_clear)) + mds_clear_cpu_buffers(); if (vcpu->arch.cr2 != read_cr2()) write_cr2(vcpu->arch.cr2); @@ -6668,8 +6671,8 @@ static struct kvm_vcpu *vmx_create_vcpu(struct kvm *kvm, unsigned int id) return ERR_PTR(err); } -#define L1TF_MSG_SMT "L1TF CPU bug present and SMT on, data leak possible. See CVE-2018-3646 and https://www.kernel.org/doc/html/latest/admin-guide/l1tf.html for details.\n" -#define L1TF_MSG_L1D "L1TF CPU bug present and virtualization mitigation disabled, data leak possible. See CVE-2018-3646 and https://www.kernel.org/doc/html/latest/admin-guide/l1tf.html for details.\n" +#define L1TF_MSG_SMT "L1TF CPU bug present and SMT on, data leak possible. See CVE-2018-3646 and https://www.kernel.org/doc/html/latest/admin-guide/hw-vuln/l1tf.html for details.\n" +#define L1TF_MSG_L1D "L1TF CPU bug present and virtualization mitigation disabled, data leak possible. See CVE-2018-3646 and https://www.kernel.org/doc/html/latest/admin-guide/hw-vuln/l1tf.html for details.\n" static int vmx_vm_init(struct kvm *kvm) { diff --git a/arch/x86/mm/pti.c b/arch/x86/mm/pti.c index 139b28a01ce4..d0255d64edce 100644 --- a/arch/x86/mm/pti.c +++ b/arch/x86/mm/pti.c @@ -35,6 +35,7 @@ #include <linux/spinlock.h> #include <linux/mm.h> #include <linux/uaccess.h> +#include <linux/cpu.h> #include <asm/cpufeature.h> #include <asm/hypervisor.h> @@ -115,7 +116,8 @@ void __init pti_check_boottime_disable(void) } } - if (cmdline_find_option_bool(boot_command_line, "nopti")) { + if (cmdline_find_option_bool(boot_command_line, "nopti") || + cpu_mitigations_off()) { pti_mode = PTI_FORCE_OFF; pti_print_if_insecure("disabled on command line."); return; diff --git a/drivers/base/cpu.c b/drivers/base/cpu.c index 668139cfa664..cc37511de866 100644 --- a/drivers/base/cpu.c +++ b/drivers/base/cpu.c @@ -548,11 +548,18 @@ ssize_t __weak cpu_show_l1tf(struct device *dev, return sprintf(buf, "Not affected\n"); } +ssize_t __weak cpu_show_mds(struct device *dev, + struct device_attribute *attr, char *buf) +{ + return sprintf(buf, "Not affected\n"); +} + static DEVICE_ATTR(meltdown, 0444, cpu_show_meltdown, NULL); static DEVICE_ATTR(spectre_v1, 0444, cpu_show_spectre_v1, NULL); static DEVICE_ATTR(spectre_v2, 0444, cpu_show_spectre_v2, NULL); static DEVICE_ATTR(spec_store_bypass, 0444, cpu_show_spec_store_bypass, NULL); static DEVICE_ATTR(l1tf, 0444, cpu_show_l1tf, NULL); +static DEVICE_ATTR(mds, 0444, cpu_show_mds, NULL); static struct attribute *cpu_root_vulnerabilities_attrs[] = { &dev_attr_meltdown.attr, @@ -560,6 +567,7 @@ static struct attribute *cpu_root_vulnerabilities_attrs[] = { &dev_attr_spectre_v2.attr, &dev_attr_spec_store_bypass.attr, &dev_attr_l1tf.attr, + &dev_attr_mds.attr, NULL }; diff --git a/include/linux/cpu.h b/include/linux/cpu.h index 5041357d0297..57ae83c4d5f4 100644 --- a/include/linux/cpu.h +++ b/include/linux/cpu.h @@ -57,6 +57,8 @@ extern ssize_t cpu_show_spec_store_bypass(struct device *dev, struct device_attribute *attr, char *buf); extern ssize_t cpu_show_l1tf(struct device *dev, struct device_attribute *attr, char *buf); +extern ssize_t cpu_show_mds(struct device *dev, + struct device_attribute *attr, char *buf); extern __printf(4, 5) struct device *cpu_device_create(struct device *parent, void *drvdata, @@ -187,4 +189,28 @@ static inline void cpu_smt_disable(bool force) { } static inline void cpu_smt_check_topology(void) { } #endif +/* + * These are used for a global "mitigations=" cmdline option for toggling + * optional CPU mitigations. + */ +enum cpu_mitigations { + CPU_MITIGATIONS_OFF, + CPU_MITIGATIONS_AUTO, + CPU_MITIGATIONS_AUTO_NOSMT, +}; + +extern enum cpu_mitigations cpu_mitigations; + +/* mitigations=off */ +static inline bool cpu_mitigations_off(void) +{ + return cpu_mitigations == CPU_MITIGATIONS_OFF; +} + +/* mitigations=auto,nosmt */ +static inline bool cpu_mitigations_auto_nosmt(void) +{ + return cpu_mitigations == CPU_MITIGATIONS_AUTO_NOSMT; +} + #endif /* _LINUX_CPU_H_ */ diff --git a/kernel/cpu.c b/kernel/cpu.c index 6754f3ecfd94..43e741e88691 100644 --- a/kernel/cpu.c +++ b/kernel/cpu.c @@ -2304,3 +2304,18 @@ void __init boot_cpu_hotplug_init(void) #endif this_cpu_write(cpuhp_state.state, CPUHP_ONLINE); } + +enum cpu_mitigations cpu_mitigations __ro_after_init = CPU_MITIGATIONS_AUTO; + +static int __init mitigations_parse_cmdline(char *arg) +{ + if (!strcmp(arg, "off")) + cpu_mitigations = CPU_MITIGATIONS_OFF; + else if (!strcmp(arg, "auto")) + cpu_mitigations = CPU_MITIGATIONS_AUTO; + else if (!strcmp(arg, "auto,nosmt")) + cpu_mitigations = CPU_MITIGATIONS_AUTO_NOSMT; + + return 0; +} +early_param("mitigations", mitigations_parse_cmdline); diff --git a/tools/power/x86/turbostat/Makefile b/tools/power/x86/turbostat/Makefile index 1598b4fa0b11..045f5f7d68ab 100644 --- a/tools/power/x86/turbostat/Makefile +++ b/tools/power/x86/turbostat/Makefile @@ -9,7 +9,7 @@ ifeq ("$(origin O)", "command line") endif turbostat : turbostat.c -override CFLAGS += -Wall +override CFLAGS += -Wall -I../../../include override CFLAGS += -DMSRHEADER='"../../../../arch/x86/include/asm/msr-index.h"' override CFLAGS += -DINTEL_FAMILY_HEADER='"../../../../arch/x86/include/asm/intel-family.h"' diff --git a/tools/power/x86/x86_energy_perf_policy/Makefile b/tools/power/x86/x86_energy_perf_policy/Makefile index ae7a0e09b722..1fdeef864e7c 100644 --- a/tools/power/x86/x86_energy_perf_policy/Makefile +++ b/tools/power/x86/x86_energy_perf_policy/Makefile @@ -9,7 +9,7 @@ ifeq ("$(origin O)", "command line") endif x86_energy_perf_policy : x86_energy_perf_policy.c -override CFLAGS += -Wall +override CFLAGS += -Wall -I../../../include override CFLAGS += -DMSRHEADER='"../../../../arch/x86/include/asm/msr-index.h"' %: %.c