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Javier Almansa Sobrino37bf69c2022-04-07 18:26:49 +01001RMM-EL3 Communication interface
2*******************************
3
4This document defines the communication interface between RMM and EL3.
5There are two parts in this interface: the boot interface and the runtime
6interface.
7
8The Boot Interface defines the ABI between EL3 and RMM when the CPU enters
9R-EL2 for the first time after boot. The cold boot interface defines the ABI
10for the cold boot path and the warm boot interface defines the same for the
11warm path.
12
13The RMM-EL3 runtime interface defines the ABI for EL3 services which can be
14invoked by RMM as well as the register save-restore convention when handling an
15SMC call from NS.
16
17The below sections discuss these interfaces more in detail.
18
19.. _rmm_el3_ifc_versioning:
20
21RMM-EL3 Interface versioning
22____________________________
23
24The RMM Boot and Runtime Interface uses a version number to check
25compatibility with the register arguments passed as part of Boot Interface and
26RMM-EL3 runtime interface.
27
28The Boot Manifest, discussed later in section :ref:`rmm_el3_boot_manifest`,
29uses a separate version number but with the same scheme.
30
31The version number is a 32-bit type with the following fields:
32
33.. csv-table::
34 :header: "Bits", "Value"
35
36 [0:15],``VERSION_MINOR``
37 [16:30],``VERSION_MAJOR``
38 [31],RES0
39
40The version numbers are sequentially increased and the rules for updating them
41are explained below:
42
43 - ``VERSION_MAJOR``: This value is increased when changes break
44 compatibility with previous versions. If the changes
45 on the ABI are compatible with the previous one, ``VERSION_MAJOR``
46 remains unchanged.
47
48 - ``VERSION_MINOR``: This value is increased on any change that is backwards
49 compatible with the previous version. When ``VERSION_MAJOR`` is increased,
50 ``VERSION_MINOR`` must be set to 0.
51
52 - ``RES0``: Bit 31 of the version number is reserved 0 as to maintain
53 consistency with the versioning schemes used in other parts of RMM.
54
55This document specifies the 0.1 version of Boot Interface ABI and RMM-EL3
56services specification and the 0.1 version of the Boot Manifest.
57
58.. _rmm_el3_boot_interface:
59
60RMM Boot Interface
61__________________
62
63This section deals with the Boot Interface part of the specification.
64
65One of the goals of the Boot Interface is to allow EL3 firmware to pass
66down into RMM certain platform specific information dynamically. This allows
67RMM to be less platform dependent and be more generic across platform
68variations. It also allows RMM to be decoupled from the other boot loader
69images in the boot sequence and remain agnostic of any particular format used
70for configuration files.
71
72The Boot Interface ABI defines a set of register conventions and
73also a memory based manifest file to pass information from EL3 to RMM. The
74boot manifest and the associated platform data in it can be dynamically created
75by EL3 and there is no restriction on how the data can be obtained (e.g by DTB,
76hoblist or other).
77
78The register convention and the manifest are versioned separately to manage
79future enhancements and compatibility.
80
81RMM completes the boot by issuing the ``RMM_BOOT_COMPLETE`` SMC (0xC40001CF)
82back to EL3. After the RMM has finished the boot process, it can only be
83entered from EL3 as part of RMI handling.
84
85If RMM returns an error during boot (in any CPU), then RMM must not be entered
86from any CPU.
87
88.. _rmm_cold_boot_interface:
89
90Cold Boot Interface
91~~~~~~~~~~~~~~~~~~~
92
93During cold boot RMM expects the following register values:
94
95.. csv-table::
96 :header: "Register", "Value"
97 :widths: 1, 5
98
99 x0,Linear index of this PE. This index starts from 0 and must be less than the maximum number of CPUs to be supported at runtime (see x2).
100 x1,Version for this Boot Interface as defined in :ref:`rmm_el3_ifc_versioning`.
101 x2,Maximum number of CPUs to be supported at runtime. RMM should ensure that it can support this maximum number.
102 x3,Base address for the shared buffer used for communication between EL3 firmware and RMM. This buffer must be of 4KB size (1 page). The boot manifest must be present at the base of this shared buffer during cold boot.
103
104During cold boot, EL3 firmware needs to allocate a 4K page that will be
105passed to RMM in x3. This memory will be used as shared buffer for communication
106between EL3 and RMM. It must be assigned to Realm world and must be mapped with
107Normal memory attributes (IWB-OWB-ISH) at EL3. At boot, this memory will be
108used to populate the Boot Manifest. Since the Boot Manifest can be accessed by
109RMM prior to enabling its MMU, EL3 must ensure that proper cache maintenance
110operations are performed after the Boot Manifest is populated.
111
112EL3 should also ensure that this shared buffer is always available for use by RMM
113during the lifetime of the system and that it can be used for runtime
114communication between RMM and EL3. For example, when RMM invokes attestation
115service commands in EL3, this buffer can be used to exchange data between RMM
116and EL3. It is also allowed for RMM to invoke runtime services provided by EL3
117utilizing this buffer during the boot phase, prior to return back to EL3 via
118RMM_BOOT_COMPLETE SMC.
119
120RMM should map this memory page into its Stage 1 page-tables using Normal
121memory attributes.
122
123During runtime, it is the RMM which initiates any communication with EL3. If that
124communication requires the use of the shared area, it is expected that RMM needs
125to do the necessary concurrency protection to prevent the use of the same buffer
126by other PEs.
127
128The following sequence diagram shows how a generic EL3 Firmware would boot RMM.
129
130.. image:: ../resources/diagrams/rmm_cold_boot_generic.png
131
132Warm Boot Interface
133~~~~~~~~~~~~~~~~~~~
134
135At warm boot, RMM is already initialized and only some per-CPU initialization
136is still pending. The only argument that is required by RMM at this stage is
137the CPU Id, which will be passed through register x0 whilst x1 to x3 are RES0.
138This is summarized in the following table:
139
140.. csv-table::
141 :header: "Register", "Value"
142 :widths: 1, 5
143
144 x0,Linear index of this PE. This index starts from 0 and must be less than the maximum number of CPUs to be supported at runtime (see x2).
145 x1 - x3,RES0
146
147Boot error handling and return values
148~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
149
150After boot up and initialization, RMM returns control back to EL3 through a
151``RMM_BOOT_COMPLETE`` SMC call. The only argument of this SMC call will
152be returned in x1 and it will encode a signed integer with the error reason
153as per the following table:
154
155.. csv-table::
156 :header: "Error code", "Description", "ID"
157 :widths: 2 4 1
158
159 ``E_RMM_BOOT_SUCCESS``,Boot successful,0
160 ``E_RMM_BOOT_ERR_UNKNOWN``,Unknown error,-1
161 ``E_RMM_BOOT_VERSION_NOT_VALID``,Boot Interface version reported by EL3 is not supported by RMM,-2
162 ``E_RMM_BOOT_CPUS_OUT_OF_RAGE``,Number of CPUs reported by EL3 larger than maximum supported by RMM,-3
163 ``E_RMM_BOOT_CPU_ID_OUT_OF_RAGE``,Current CPU Id is higher or equal than the number of CPUs supported by RMM,-4
164 ``E_RMM_BOOT_INVALID_SHARED_BUFFER``,Invalid pointer to shared memory area,-5
165 ``E_RMM_BOOT_MANIFEST_VERSION_NOT_SUPPORTED``,Version reported by the boot manifest not supported by RMM,-6
166 ``E_RMM_BOOT_MANIFEST_DATA_ERROR``,Error parsing core boot manifest,-7
167
168For any error detected in RMM during cold or warm boot, RMM will return back to
169EL3 using ``RMM_BOOT_COMPLETE`` SMC with an appropriate error code. It is
170expected that EL3 will take necessary action to disable Realm world for further
171entry from NS Host on receiving an error. This will be done across all the PEs
172in the system so as to present a symmetric view to the NS Host. Any further
173warm boot by any PE should not enter RMM using the warm boot interface.
174
175.. _rmm_el3_boot_manifest:
176
177Boot Manifest
178~~~~~~~~~~~~~
179
180During cold boot, EL3 Firmware passes a memory boot manifest to RMM containing
181platform information.
182
183This boot manifest is versioned independently of the boot interface, to help
184evolve the boot manifest independent of the rest of Boot Manifest.
185The current version for the boot manifest is ``v0.1`` and the rules explained
186in :ref:`rmm_el3_ifc_versioning` apply on this version as well.
187
188The boot manifest is divided into two different components:
189
190 - Core Manifest: This is the generic parameters passed to RMM by EL3 common to all platforms.
191 - Platform data: This is defined by the platform owner and contains information specific to that platform.
192
193For the current version of the manifest, the core manifest contains a pointer
194to the platform data. EL3 must ensure that the whole boot manifest,
195including the platform data, if available, fits inside the RMM EL3 shared
196buffer.
197
198For the type specification of the RMM Boot Manifest v0.1, refer to
199:ref:`rmm_el3_manifest_struct`
200
201.. _runtime_services_and_interface:
202
203RMMM-EL3 Runtime Interface
204__________________________
205
206This section defines the RMM-EL3 runtime interface which specifies the ABI for
207EL3 services expected by RMM at runtime as well as the register save and
208restore convention between EL3 and RMM as part of RMI call handling. It is
209important to note that RMM is allowed to invoke EL3-RMM runtime interface
210services during the boot phase as well. The EL3 runtime service handling must
211not result in a world switch to another world unless specified. Both the RMM
212and EL3 are allowed to make suitable optimizations based on this assumption.
213
214If the interface requires the use of memory, then the memory references should
215be within the shared buffer communicated as part of the boot interface. See
216:ref:`rmm_cold_boot_interface` for properties of this shared buffer which both
217EL3 and RMM must adhere to.
218
219RMM-EL3 runtime service return codes
220~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
221
222The return codes from EL3 to RMM is a 32 bit signed integer which encapsulates
223error condition as described in the following table:
224
225.. csv-table::
226 :header: "Error code", "Description", "ID"
227 :widths: 2 4 1
228
229 ``E_RMM_OK``,No errors detected,0
230 ``E_RMM_UNK``,Unknown/Generic error,-1
231 ``E_RMM_BAD_ADDR``,The value of an address used as argument was invalid,-2
232 ``E_RMM_BAD_PAS``,Incorrect PAS,-3
233 ``E_RMM_NOMEM``,Not enough memory to perform an operation,-4
234 ``E_RMM_INVAL``,The value of an argument was invalid,-5
235
236If multiple failure conditions are detected in an RMM to EL3 command, then EL3
237is allowed to return an error code corresponding to any of the failure
238conditions.
239
240RMM-EL3 runtime services
241~~~~~~~~~~~~~~~~~~~~~~~~
242
243The following table summarizes the RMM runtime services that need to be
244implemented by EL3 Firmware.
245
246.. csv-table::
247 :header: "FID", "Command"
248 :widths: 2 5
249
250 0xC40001B2,``RMM_ATTEST_GET_REALM_KEY``
251 0xC40001B3,``RMM_ATTEST_GET_PLAT_TOKEN``
252
253RMM_ATTEST_GET_REALM_KEY command
254================================
255
256Retrieve the Realm Attestation Token Signing key from EL3.
257
258FID
259---
260
261``0xC40001B2``
262
263Input values
264------------
265
266.. csv-table::
267 :header: "Name", "Register", "Field", "Type", "Description"
268 :widths: 1 1 1 1 5
269
270 fid,x0,[63:0],UInt64,Command FID
271 buf_pa,x1,[63:0],Address,PA where the Realm Attestation Key must be stored by EL3. The PA must belong to the shared buffer
272 buf_size,x2,[63:0],Size,Size in bytes of the Realm Attestation Key buffer. ``bufPa + bufSize`` must lie within the shared buffer
273 ecc_curve,x3,[63:0],Enum,Type of the elliptic curve to which the requested attestation key belongs to. See :ref:`ecc_curves`
274
275Output values
276-------------
277
278.. csv-table::
279 :header: "Name", "Register", "Field", "Type", "Description"
280 :widths: 1 1 1 1 5
281
282 Result,x0,[63:0],Error Code,Command return status
283 keySize,x1,[63:0],Size,Size of the Realm Attestation Key
284
285Failure conditions
286------------------
287
288The table below shows all the possible error codes returned in ``Result`` upon
289a failure. The errors are ordered by condition check.
290
291.. csv-table::
292 :header: "ID", "Condition"
293 :widths: 1 5
294
295 ``E_RMM_BAD_ADDR``,``PA`` is outside the shared buffer
296 ``E_RMM_INVAL``,``PA + BSize`` is outside the shared buffer
297 ``E_RMM_INVAL``,``Curve`` is not one of the listed in :ref:`ecc_curves`
298 ``E_RMM_UNK``,An unknown error occurred whilst processing the command
299 ``E_RMM_OK``,No errors detected
300
301.. _ecc_curves:
302
303Supported ECC Curves
304--------------------
305
306.. csv-table::
307 :header: "ID", "Curve"
308 :widths: 1 5
309
310 0,ECC SECP384R1
311
312RMM_ATTEST_GET_PLAT_TOKEN command
313=================================
314
315Retrieve the Platform Token from EL3.
316
317FID
318---
319
320``0xC40001B3``
321
322Input values
323------------
324
325.. csv-table::
326 :header: "Name", "Register", "Field", "Type", "Description"
327 :widths: 1 1 1 1 5
328
329 fid,x0,[63:0],UInt64,Command FID
330 buf_pa,x1,[63:0],Address,PA of the platform attestation token. The challenge object is passed in this buffer. The PA must belong to the shared buffer
331 buf_size,x2,[63:0],Size,Size in bytes of the platform attestation token buffer. ``bufPa + bufSize`` must lie within the shared buffer
332 c_size,x3,[63:0],Size,Size in bytes of the challenge object. It corresponds to the size of one of the defined SHA algorithms
333
334Output values
335-------------
336
337.. csv-table::
338 :header: "Name", "Register", "Field", "Type", "Description"
339 :widths: 1 1 1 1 5
340
341 Result,x0,[63:0],Error Code,Command return status
342 tokenSize,x1,[63:0],Size,Size of the platform token
343
344Failure conditions
345------------------
346
347The table below shows all the possible error codes returned in ``Result`` upon
348a failure. The errors are ordered by condition check.
349
350.. csv-table::
351 :header: "ID", "Condition"
352 :widths: 1 5
353
354 ``E_RMM_BAD_ADDR``,``PA`` is outside the shared buffer
355 ``E_RMM_INVAL``,``PA + BSize`` is outside the shared buffer
356 ``E_RMM_INVAL``,``CSize`` does not represent the size of a supported SHA algorithm
357 ``E_RMM_UNK``,An unknown error occurred whilst processing the command
358 ``E_RMM_OK``,No errors detected
359
360RMM-EL3 world switch register save restore convention
361_____________________________________________________
362
363As part of NS world switch, EL3 is expected to maintain a register context
364specific to each world and will save and restore the registers
365appropriately. This section captures the contract between EL3 and RMM on the
366register set to be saved and restored.
367
368EL3 must maintain a separate register context for the following:
369
370 #. General purpose registers (x0-x30) and ``sp_el0``, ``sp_el2`` stack pointers
371 #. EL2 system register context for all enabled features by EL3. These include system registers with the ``_EL2`` prefix. The EL2 physical and virtual timer registers must not be included in this.
372
373It is the responsibility of EL3 that the above registers will not be leaked to
374the NS Host and to maintain the confidentiality of the Realm World.
375
376EL3 will not save some registers as mentioned in the below list. It is the
377responsibility of RMM to ensure that these are appropriately saved if the
378Realm World makes use of them:
379
380 #. FP/SIMD registers
381 #. SVE registers
382 #. SME registers
383 #. EL1/0 registers
384
385SMCCC v1.3 allows NS world to specify whether SVE context is in use. In this
386case, RMM could choose to not save the incoming SVE context but must ensure
387to clear SVE registers if they have been used in Realm World. The same applies
388to SME registers.
389
390Types
391_____
392
393.. _rmm_el3_manifest_struct:
394
395RMM-EL3 Boot Manifest Version
396~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
397
398The RMM-EL3 Boot Manifest structure contains platform boot information passed
399from EL3 to RMM. The width of the Boot Manifest is 128 bits
400
401.. image:: ../resources/diagrams/rmm_el3_manifest_struct.png
402
403The members of the RMM-EL3 Boot Manifest structure are shown in the following
404table:
405
406.. csv-table::
407 :header: "Name", "Range", "Type", Description
408 :widths: 2 1 1 4
409
410 ``Version Minor``,15:0,uint16_t,Version Minor part of the Boot Manifest Version.
411 ``Version Major``,30:16,uint16_t,Version Major part of the Boot Manifest Version.
412 ``RES0``,31,bit,Reserved. Set to 0.
413 ``Platform Data``,127:64,Address,Pointer to the Platform Data section of the Boot Manifest.