xref: /openbmc/qemu/docs/system/i386/sgx.rst (revision 3df4c288)
1Software Guard eXtensions (SGX)
2===============================
3
4Overview
5--------
6
7Intel Software Guard eXtensions (SGX) is a set of instructions and mechanisms
8for memory accesses in order to provide security accesses for sensitive
9applications and data. SGX allows an application to use its particular
10address space as an *enclave*, which is a protected area provides confidentiality
11and integrity even in the presence of privileged malware. Accesses to the
12enclave memory area from any software not resident in the enclave are prevented,
13including those from privileged software.
14
15Virtual SGX
16-----------
17
18SGX feature is exposed to guest via SGX CPUID. Looking at SGX CPUID, we can
19report the same CPUID info to guest as on host for most of SGX CPUID. With
20reporting the same CPUID guest is able to use full capacity of SGX, and KVM
21doesn't need to emulate those info.
22
23The guest's EPC base and size are determined by QEMU, and KVM needs QEMU to
24notify such info to it before it can initialize SGX for guest.
25
26Virtual EPC
27~~~~~~~~~~~
28
29By default, QEMU does not assign EPC to a VM, i.e. fully enabling SGX in a VM
30requires explicit allocation of EPC to the VM. Similar to other specialized
31memory types, e.g. hugetlbfs, EPC is exposed as a memory backend.
32
33SGX EPC is enumerated through CPUID, i.e. EPC "devices" need to be realized
34prior to realizing the vCPUs themselves, which occurs long before generic
35devices are parsed and realized.  This limitation means that EPC does not
36require -maxmem as EPC is not treated as {cold,hot}plugged memory.
37
38QEMU does not artificially restrict the number of EPC sections exposed to a
39guest, e.g. QEMU will happily allow you to create 64 1M EPC sections. Be aware
40that some kernels may not recognize all EPC sections, e.g. the Linux SGX driver
41is hardwired to support only 8 EPC sections.
42
43The following QEMU snippet creates two EPC sections, with 64M pre-allocated
44to the VM and an additional 28M mapped but not allocated::
45
46 -object memory-backend-epc,id=mem1,size=64M,prealloc=on \
47 -object memory-backend-epc,id=mem2,size=28M \
48 -M sgx-epc.0.memdev=mem1,sgx-epc.1.memdev=mem2
49
50Note:
51
52The size and location of the virtual EPC are far less restricted compared
53to physical EPC. Because physical EPC is protected via range registers,
54the size of the physical EPC must be a power of two (though software sees
55a subset of the full EPC, e.g. 92M or 128M) and the EPC must be naturally
56aligned.  KVM SGX's virtual EPC is purely a software construct and only
57requires the size and location to be page aligned. QEMU enforces the EPC
58size is a multiple of 4k and will ensure the base of the EPC is 4k aligned.
59To simplify the implementation, EPC is always located above 4g in the guest
60physical address space.
61
62Migration
63~~~~~~~~~
64
65QEMU/KVM doesn't prevent live migrating SGX VMs, although from hardware's
66perspective, SGX doesn't support live migration, since both EPC and the SGX
67key hierarchy are bound to the physical platform. However live migration
68can be supported in the sense if guest software stack can support recreating
69enclaves when it suffers sudden lose of EPC; and if guest enclaves can detect
70SGX keys being changed, and handle gracefully. For instance, when ERESUME fails
71with #PF.SGX, guest software can gracefully detect it and recreate enclaves;
72and when enclave fails to unseal sensitive information from outside, it can
73detect such error and sensitive information can be provisioned to it again.
74
75CPUID
76~~~~~
77
78Due to its myriad dependencies, SGX is currently not listed as supported
79in any of QEMU's built-in CPU configuration. To expose SGX (and SGX Launch
80Control) to a guest, you must either use ``-cpu host`` to pass-through the
81host CPU model, or explicitly enable SGX when using a built-in CPU model,
82e.g. via ``-cpu <model>,+sgx`` or ``-cpu <model>,+sgx,+sgxlc``.
83
84All SGX sub-features enumerated through CPUID, e.g. SGX2, MISCSELECT,
85ATTRIBUTES, etc... can be restricted via CPUID flags. Be aware that enforcing
86restriction of MISCSELECT, ATTRIBUTES and XFRM requires intercepting ECREATE,
87i.e. may marginally reduce SGX performance in the guest. All SGX sub-features
88controlled via -cpu are prefixed with "sgx", e.g.::
89
90  $ qemu-system-x86_64 -cpu help | xargs printf "%s\n" | grep sgx
91  sgx
92  sgx-debug
93  sgx-encls-c
94  sgx-enclv
95  sgx-exinfo
96  sgx-kss
97  sgx-mode64
98  sgx-provisionkey
99  sgx-tokenkey
100  sgx1
101  sgx2
102  sgxlc
103
104The following QEMU snippet passes through the host CPU but restricts access to
105the provision and EINIT token keys::
106
107 -cpu host,-sgx-provisionkey,-sgx-tokenkey
108
109SGX sub-features cannot be emulated, i.e. sub-features that are not present
110in hardware cannot be forced on via '-cpu'.
111
112Virtualize SGX Launch Control
113~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
114
115QEMU SGX support for Launch Control (LC) is passive, in the sense that it
116does not actively change the LC configuration.  QEMU SGX provides the user
117the ability to set/clear the CPUID flag (and by extension the associated
118IA32_FEATURE_CONTROL MSR bit in fw_cfg) and saves/restores the LE Hash MSRs
119when getting/putting guest state, but QEMU does not add new controls to
120directly modify the LC configuration.  Similar to hardware behavior, locking
121the LC configuration to a non-Intel value is left to guest firmware.  Unlike
122host bios setting for SGX launch control(LC), there is no special bios setting
123for SGX guest by our design. If host is in locked mode, we can still allow
124creating VM with SGX.
125
126Feature Control
127~~~~~~~~~~~~~~~
128
129QEMU SGX updates the ``etc/msr_feature_control`` fw_cfg entry to set the SGX
130(bit 18) and SGX LC (bit 17) flags based on their respective CPUID support,
131i.e. existing guest firmware will automatically set SGX and SGX LC accordingly,
132assuming said firmware supports fw_cfg.msr_feature_control.
133
134Launching a guest
135-----------------
136
137To launch a SGX guest:
138
139.. parsed-literal::
140
141  |qemu_system_x86| \\
142   -cpu host,+sgx-provisionkey \\
143   -object memory-backend-epc,id=mem1,size=64M,prealloc=on \\
144   -M sgx-epc.0.memdev=mem1,sgx-epc.0.node=0
145
146Utilizing SGX in the guest requires a kernel/OS with SGX support.
147The support can be determined in guest by::
148
149  $ grep sgx /proc/cpuinfo
150
151and SGX epc info by::
152
153  $ dmesg | grep sgx
154  [    0.182807] sgx: EPC section 0x140000000-0x143ffffff
155  [    0.183695] sgx: [Firmware Bug]: Unable to map EPC section to online node. Fallback to the NUMA node 0.
156
157To launch a SGX numa guest:
158
159.. parsed-literal::
160
161  |qemu_system_x86| \\
162   -cpu host,+sgx-provisionkey \\
163   -object memory-backend-ram,size=2G,host-nodes=0,policy=bind,id=node0 \\
164   -object memory-backend-epc,id=mem0,size=64M,prealloc=on,host-nodes=0,policy=bind \\
165   -numa node,nodeid=0,cpus=0-1,memdev=node0 \\
166   -object memory-backend-ram,size=2G,host-nodes=1,policy=bind,id=node1 \\
167   -object memory-backend-epc,id=mem1,size=28M,prealloc=on,host-nodes=1,policy=bind \\
168   -numa node,nodeid=1,cpus=2-3,memdev=node1 \\
169   -M sgx-epc.0.memdev=mem0,sgx-epc.0.node=0,sgx-epc.1.memdev=mem1,sgx-epc.1.node=1
170
171and SGX epc numa info by::
172
173  $ dmesg | grep sgx
174  [    0.369937] sgx: EPC section 0x180000000-0x183ffffff
175  [    0.370259] sgx: EPC section 0x184000000-0x185bfffff
176
177  $ dmesg | grep SRAT
178  [    0.009981] ACPI: SRAT: Node 0 PXM 0 [mem 0x180000000-0x183ffffff]
179  [    0.009982] ACPI: SRAT: Node 1 PXM 1 [mem 0x184000000-0x185bfffff]
180
181References
182----------
183
184- `SGX Homepage <https://software.intel.com/sgx>`__
185
186- `SGX SDK <https://github.com/intel/linux-sgx.git>`__
187
188- SGX specification: Intel SDM Volume 3
189