summaryrefslogtreecommitdiffstats
path: root/docs/components/secure-partition-manager.rst
diff options
context:
space:
mode:
Diffstat (limited to 'docs/components/secure-partition-manager.rst')
-rw-r--r--docs/components/secure-partition-manager.rst1565
1 files changed, 1565 insertions, 0 deletions
diff --git a/docs/components/secure-partition-manager.rst b/docs/components/secure-partition-manager.rst
new file mode 100644
index 0000000..cd439ad
--- /dev/null
+++ b/docs/components/secure-partition-manager.rst
@@ -0,0 +1,1565 @@
+Secure Partition Manager
+************************
+
+.. contents::
+
+.. toctree::
+ ffa-manifest-binding
+
+Acronyms
+========
+
++--------+--------------------------------------+
+| CoT | Chain of Trust |
++--------+--------------------------------------+
+| DMA | Direct Memory Access |
++--------+--------------------------------------+
+| DTB | Device Tree Blob |
++--------+--------------------------------------+
+| DTS | Device Tree Source |
++--------+--------------------------------------+
+| EC | Execution Context |
++--------+--------------------------------------+
+| FIP | Firmware Image Package |
++--------+--------------------------------------+
+| FF-A | Firmware Framework for Arm A-profile |
++--------+--------------------------------------+
+| IPA | Intermediate Physical Address |
++--------+--------------------------------------+
+| JOP | Jump-Oriented Programming |
++--------+--------------------------------------+
+| NWd | Normal World |
++--------+--------------------------------------+
+| ODM | Original Design Manufacturer |
++--------+--------------------------------------+
+| OEM | Original Equipment Manufacturer |
++--------+--------------------------------------+
+| PA | Physical Address |
++--------+--------------------------------------+
+| PE | Processing Element |
++--------+--------------------------------------+
+| PM | Power Management |
++--------+--------------------------------------+
+| PVM | Primary VM |
++--------+--------------------------------------+
+| ROP | Return-Oriented Programming |
++--------+--------------------------------------+
+| SMMU | System Memory Management Unit |
++--------+--------------------------------------+
+| SP | Secure Partition |
++--------+--------------------------------------+
+| SPD | Secure Payload Dispatcher |
++--------+--------------------------------------+
+| SPM | Secure Partition Manager |
++--------+--------------------------------------+
+| SPMC | SPM Core |
++--------+--------------------------------------+
+| SPMD | SPM Dispatcher |
++--------+--------------------------------------+
+| SiP | Silicon Provider |
++--------+--------------------------------------+
+| SWd | Secure World |
++--------+--------------------------------------+
+| TLV | Tag-Length-Value |
++--------+--------------------------------------+
+| TOS | Trusted Operating System |
++--------+--------------------------------------+
+| VM | Virtual Machine |
++--------+--------------------------------------+
+
+Foreword
+========
+
+Three implementations of a Secure Partition Manager co-exist in the TF-A
+codebase:
+
+#. S-EL2 SPMC based on the FF-A specification `[1]`_, enabling virtualization in
+ the secure world, managing multiple S-EL1 or S-EL0 partitions.
+#. EL3 SPMC based on the FF-A specification, managing a single S-EL1 partition
+ without virtualization in the secure world.
+#. EL3 SPM based on the MM specification, legacy implementation managing a
+ single S-EL0 partition `[2]`_.
+
+These implementations differ in their respective SW architecture and only one
+can be selected at build time. This document:
+
+- describes the implementation from bullet 1. when the SPMC resides at S-EL2.
+- is not an architecture specification and it might provide assumptions
+ on sections mandated as implementation-defined in the specification.
+- covers the implications to TF-A used as a bootloader, and Hafnium used as a
+ reference code base for an S-EL2/SPMC secure firmware on platforms
+ implementing the FEAT_SEL2 architecture extension.
+
+Terminology
+-----------
+
+- The term Hypervisor refers to the NS-EL2 component managing Virtual Machines
+ (or partitions) in the normal world.
+- The term SPMC refers to the S-EL2 component managing secure partitions in
+ the secure world when the FEAT_SEL2 architecture extension is implemented.
+- Alternatively, SPMC can refer to an S-EL1 component, itself being a secure
+ partition and implementing the FF-A ABI on platforms not implementing the
+ FEAT_SEL2 architecture extension.
+- The term VM refers to a normal world Virtual Machine managed by an Hypervisor.
+- The term SP refers to a secure world "Virtual Machine" managed by an SPMC.
+
+Support for legacy platforms
+----------------------------
+
+The SPM is split into a dispatcher and a core component (respectively SPMD and
+SPMC) residing at different exception levels. To permit the FF-A specification
+adoption and a smooth migration, the SPMD supports an SPMC residing either at
+S-EL1 or S-EL2:
+
+- The SPMD is located at EL3 and mainly relays the FF-A protocol from NWd
+ (Hypervisor or OS kernel) to the SPMC.
+- The same SPMD component is used for both S-EL1 and S-EL2 SPMC configurations.
+- The SPMC exception level is a build time choice.
+
+TF-A supports both cases:
+
+- S-EL1 SPMC for platforms not supporting the FEAT_SEL2 architecture
+ extension. The SPMD relays the FF-A protocol from EL3 to S-EL1.
+- S-EL2 SPMC for platforms implementing the FEAT_SEL2 architecture
+ extension. The SPMD relays the FF-A protocol from EL3 to S-EL2.
+
+Sample reference stack
+======================
+
+The following diagram illustrates a possible configuration when the
+FEAT_SEL2 architecture extension is implemented, showing the SPMD
+and SPMC, one or multiple secure partitions, with an optional
+Hypervisor:
+
+.. image:: ../resources/diagrams/ff-a-spm-sel2.png
+
+TF-A build options
+==================
+
+This section explains the TF-A build options involved in building with
+support for an FF-A based SPM where the SPMD is located at EL3 and the
+SPMC located at S-EL1, S-EL2 or EL3:
+
+- **SPD=spmd**: this option selects the SPMD component to relay the FF-A
+ protocol from NWd to SWd back and forth. It is not possible to
+ enable another Secure Payload Dispatcher when this option is chosen.
+- **SPMD_SPM_AT_SEL2**: this option adjusts the SPMC exception
+ level to being at S-EL2. It defaults to enabled (value 1) when
+ SPD=spmd is chosen.
+- **SPMC_AT_EL3**: this option adjusts the SPMC exception level to being
+ at EL3.
+- If neither ``SPMD_SPM_AT_SEL2`` or ``SPMC_AT_EL3`` are enabled the SPMC
+ exception level is set to S-EL1.
+- **CTX_INCLUDE_EL2_REGS**: this option permits saving (resp.
+ restoring) the EL2 system register context before entering (resp.
+ after leaving) the SPMC. It is mandatorily enabled when
+ ``SPMD_SPM_AT_SEL2`` is enabled. The context save/restore routine
+ and exhaustive list of registers is visible at `[4]`_.
+- **SP_LAYOUT_FILE**: this option specifies a text description file
+ providing paths to SP binary images and manifests in DTS format
+ (see `Describing secure partitions`_). It
+ is required when ``SPMD_SPM_AT_SEL2`` is enabled hence when multiple
+ secure partitions are to be loaded by BL2 on behalf of the SPMC.
+
++---------------+----------------------+------------------+-------------+
+| | CTX_INCLUDE_EL2_REGS | SPMD_SPM_AT_SEL2 | SPMC_AT_EL3 |
++---------------+----------------------+------------------+-------------+
+| SPMC at S-EL1 | 0 | 0 | 0 |
++---------------+----------------------+------------------+-------------+
+| SPMC at S-EL2 | 1 | 1 (default when | 0 |
+| | | SPD=spmd) | |
++---------------+----------------------+------------------+-------------+
+| SPMC at EL3 | 0 | 0 | 1 |
++---------------+----------------------+------------------+-------------+
+
+Other combinations of such build options either break the build or are not
+supported.
+
+Notes:
+
+- Only Arm's FVP platform is supported to use with the TF-A reference software
+ stack.
+- When ``SPMD_SPM_AT_SEL2=1``, the reference software stack assumes enablement
+ of FEAT_PAuth, FEAT_BTI and FEAT_MTE architecture extensions.
+- The ``CTX_INCLUDE_EL2_REGS`` option provides the generic support for
+ barely saving/restoring EL2 registers from an Arm arch perspective. As such
+ it is decoupled from the ``SPD=spmd`` option.
+- BL32 option is re-purposed to specify the SPMC image. It can specify either
+ the Hafnium binary path (built for the secure world) or the path to a TEE
+ binary implementing FF-A interfaces.
+- BL33 option can specify the TFTF binary or a normal world loader
+ such as U-Boot or the UEFI framework payload.
+
+Sample TF-A build command line when the SPMC is located at S-EL1
+(e.g. when the FEAT_SEL2 architecture extension is not implemented):
+
+.. code:: shell
+
+ make \
+ CROSS_COMPILE=aarch64-none-elf- \
+ SPD=spmd \
+ SPMD_SPM_AT_SEL2=0 \
+ BL32=<path-to-tee-binary> \
+ BL33=<path-to-bl33-binary> \
+ PLAT=fvp \
+ all fip
+
+Sample TF-A build command line when FEAT_SEL2 architecture extension is
+implemented and the SPMC is located at S-EL2:
+.. code:: shell
+
+ make \
+ CROSS_COMPILE=aarch64-none-elf- \
+ PLAT=fvp \
+ SPD=spmd \
+ CTX_INCLUDE_EL2_REGS=1 \
+ ARM_ARCH_MINOR=5 \
+ BRANCH_PROTECTION=1 \
+ CTX_INCLUDE_PAUTH_REGS=1 \
+ CTX_INCLUDE_MTE_REGS=1 \
+ BL32=<path-to-hafnium-binary> \
+ BL33=<path-to-bl33-binary> \
+ SP_LAYOUT_FILE=sp_layout.json \
+ all fip
+
+Sample TF-A build command line when FEAT_SEL2 architecture extension is
+implemented, the SPMC is located at S-EL2, and enabling secure boot:
+.. code:: shell
+
+ make \
+ CROSS_COMPILE=aarch64-none-elf- \
+ PLAT=fvp \
+ SPD=spmd \
+ CTX_INCLUDE_EL2_REGS=1 \
+ ARM_ARCH_MINOR=5 \
+ BRANCH_PROTECTION=1 \
+ CTX_INCLUDE_PAUTH_REGS=1 \
+ CTX_INCLUDE_MTE_REGS=1 \
+ BL32=<path-to-hafnium-binary> \
+ BL33=<path-to-bl33-binary> \
+ SP_LAYOUT_FILE=sp_layout.json \
+ MBEDTLS_DIR=<path-to-mbedtls-lib> \
+ TRUSTED_BOARD_BOOT=1 \
+ COT=dualroot \
+ ARM_ROTPK_LOCATION=devel_rsa \
+ ROT_KEY=plat/arm/board/common/rotpk/arm_rotprivk_rsa.pem \
+ GENERATE_COT=1 \
+ all fip
+
+Sample TF-A build command line when the SPMC is located at EL3:
+
+.. code:: shell
+
+ make \
+ CROSS_COMPILE=aarch64-none-elf- \
+ SPD=spmd \
+ SPMD_SPM_AT_SEL2=0 \
+ SPMC_AT_EL3=1 \
+ BL32=<path-to-tee-binary> \
+ BL33=<path-to-bl33-binary> \
+ PLAT=fvp \
+ all fip
+
+FVP model invocation
+====================
+
+The FVP command line needs the following options to exercise the S-EL2 SPMC:
+
++---------------------------------------------------+------------------------------------+
+| - cluster0.has_arm_v8-5=1 | Implements FEAT_SEL2, FEAT_PAuth, |
+| - cluster1.has_arm_v8-5=1 | and FEAT_BTI. |
++---------------------------------------------------+------------------------------------+
+| - pci.pci_smmuv3.mmu.SMMU_AIDR=2 | Parameters required for the |
+| - pci.pci_smmuv3.mmu.SMMU_IDR0=0x0046123B | SMMUv3.2 modeling. |
+| - pci.pci_smmuv3.mmu.SMMU_IDR1=0x00600002 | |
+| - pci.pci_smmuv3.mmu.SMMU_IDR3=0x1714 | |
+| - pci.pci_smmuv3.mmu.SMMU_IDR5=0xFFFF0472 | |
+| - pci.pci_smmuv3.mmu.SMMU_S_IDR1=0xA0000002 | |
+| - pci.pci_smmuv3.mmu.SMMU_S_IDR2=0 | |
+| - pci.pci_smmuv3.mmu.SMMU_S_IDR3=0 | |
++---------------------------------------------------+------------------------------------+
+| - cluster0.has_branch_target_exception=1 | Implements FEAT_BTI. |
+| - cluster1.has_branch_target_exception=1 | |
++---------------------------------------------------+------------------------------------+
+| - cluster0.has_pointer_authentication=2 | Implements FEAT_PAuth |
+| - cluster1.has_pointer_authentication=2 | |
++---------------------------------------------------+------------------------------------+
+| - cluster0.memory_tagging_support_level=2 | Implements FEAT_MTE2 |
+| - cluster1.memory_tagging_support_level=2 | |
+| - bp.dram_metadata.is_enabled=1 | |
++---------------------------------------------------+------------------------------------+
+
+Sample FVP command line invocation:
+
+.. code:: shell
+
+ <path-to-fvp-model>/FVP_Base_RevC-2xAEMvA -C pctl.startup=0.0.0.0 \
+ -C cluster0.NUM_CORES=4 -C cluster1.NUM_CORES=4 -C bp.secure_memory=1 \
+ -C bp.secureflashloader.fname=trusted-firmware-a/build/fvp/debug/bl1.bin \
+ -C bp.flashloader0.fname=trusted-firmware-a/build/fvp/debug/fip.bin \
+ -C bp.pl011_uart0.out_file=fvp-uart0.log -C bp.pl011_uart1.out_file=fvp-uart1.log \
+ -C bp.pl011_uart2.out_file=fvp-uart2.log \
+ -C cluster0.has_arm_v8-5=1 -C cluster1.has_arm_v8-5=1 \
+ -C cluster0.has_pointer_authentication=2 -C cluster1.has_pointer_authentication=2 \
+ -C cluster0.has_branch_target_exception=1 -C cluster1.has_branch_target_exception=1 \
+ -C cluster0.memory_tagging_support_level=2 -C cluster1.memory_tagging_support_level=2 \
+ -C bp.dram_metadata.is_enabled=1 \
+ -C pci.pci_smmuv3.mmu.SMMU_AIDR=2 -C pci.pci_smmuv3.mmu.SMMU_IDR0=0x0046123B \
+ -C pci.pci_smmuv3.mmu.SMMU_IDR1=0x00600002 -C pci.pci_smmuv3.mmu.SMMU_IDR3=0x1714 \
+ -C pci.pci_smmuv3.mmu.SMMU_IDR5=0xFFFF0472 -C pci.pci_smmuv3.mmu.SMMU_S_IDR1=0xA0000002 \
+ -C pci.pci_smmuv3.mmu.SMMU_S_IDR2=0 -C pci.pci_smmuv3.mmu.SMMU_S_IDR3=0
+
+Boot process
+============
+
+Loading Hafnium and secure partitions in the secure world
+---------------------------------------------------------
+
+TF-A BL2 is the bootlader for the SPMC and SPs in the secure world.
+
+SPs may be signed by different parties (SiP, OEM/ODM, TOS vendor, etc.).
+Thus they are supplied as distinct signed entities within the FIP flash
+image. The FIP image itself is not signed hence this provides the ability
+to upgrade SPs in the field.
+
+Booting through TF-A
+--------------------
+
+SP manifests
+~~~~~~~~~~~~
+
+An SP manifest describes SP attributes as defined in `[1]`_
+(partition manifest at virtual FF-A instance) in DTS format. It is
+represented as a single file associated with the SP. A sample is
+provided by `[5]`_. A binding document is provided by `[6]`_.
+
+Secure Partition packages
+~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Secure partitions are bundled as independent package files consisting
+of:
+
+- a header
+- a DTB
+- an image payload
+
+The header starts with a magic value and offset values to SP DTB and
+image payload. Each SP package is loaded independently by BL2 loader
+and verified for authenticity and integrity.
+
+The SP package identified by its UUID (matching FF-A uuid property) is
+inserted as a single entry into the FIP at end of the TF-A build flow
+as shown:
+
+.. code:: shell
+
+ Trusted Boot Firmware BL2: offset=0x1F0, size=0x8AE1, cmdline="--tb-fw"
+ EL3 Runtime Firmware BL31: offset=0x8CD1, size=0x13000, cmdline="--soc-fw"
+ Secure Payload BL32 (Trusted OS): offset=0x1BCD1, size=0x15270, cmdline="--tos-fw"
+ Non-Trusted Firmware BL33: offset=0x30F41, size=0x92E0, cmdline="--nt-fw"
+ HW_CONFIG: offset=0x3A221, size=0x2348, cmdline="--hw-config"
+ TB_FW_CONFIG: offset=0x3C569, size=0x37A, cmdline="--tb-fw-config"
+ SOC_FW_CONFIG: offset=0x3C8E3, size=0x48, cmdline="--soc-fw-config"
+ TOS_FW_CONFIG: offset=0x3C92B, size=0x427, cmdline="--tos-fw-config"
+ NT_FW_CONFIG: offset=0x3CD52, size=0x48, cmdline="--nt-fw-config"
+ B4B5671E-4A90-4FE1-B81F-FB13DAE1DACB: offset=0x3CD9A, size=0xC168, cmdline="--blob"
+ D1582309-F023-47B9-827C-4464F5578FC8: offset=0x48F02, size=0xC168, cmdline="--blob"
+
+.. uml:: ../resources/diagrams/plantuml/fip-secure-partitions.puml
+
+Describing secure partitions
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+A json-formatted description file is passed to the build flow specifying paths
+to the SP binary image and associated DTS partition manifest file. The latter
+is processed by the dtc compiler to generate a DTB fed into the SP package.
+Optionally, the partition's json description can contain offsets for both
+the image and partition manifest within the SP package. Both offsets need to be
+4KB aligned, because it is the translation granule supported by Hafnium SPMC.
+These fields can be leveraged to support SPs with S1 translation granules that
+differ from 4KB, and to configure the regions allocated within the SP package,
+as well as to comply with the requirements for the implementation of the boot
+information protocol (see `Passing boot data to the SP`_ for more details). In
+case the offsets are absent in their json node, they default to 0x1000 and
+0x4000 for the manifest offset and image offset respectively.
+This file also specifies the SP owner (as an optional field) identifying the
+signing domain in case of dual root CoT.
+The SP owner can either be the silicon or the platform provider. The
+corresponding "owner" field value can either take the value of "SiP" or "Plat".
+In absence of "owner" field, it defaults to "SiP" owner.
+The UUID of the partition can be specified as a field in the description file or
+if it does not exist there the UUID is extracted from the DTS partition
+manifest.
+
+.. code:: shell
+
+ {
+ "tee1" : {
+ "image": "tee1.bin",
+ "pm": "tee1.dts",
+ "owner": "SiP",
+ "uuid": "1b1820fe-48f7-4175-8999-d51da00b7c9f"
+ },
+
+ "tee2" : {
+ "image": "tee2.bin",
+ "pm": "tee2.dts",
+ "owner": "Plat"
+ },
+
+ "tee3" : {
+ "image": {
+ "file": "tee3.bin",
+ "offset":"0x2000"
+ },
+ "pm": {
+ "file": "tee3.dts",
+ "offset":"0x6000"
+ },
+ "owner": "Plat"
+ },
+ }
+
+SPMC manifest
+~~~~~~~~~~~~~
+
+This manifest contains the SPMC *attribute* node consumed by the SPMD at boot
+time. It implements `[1]`_ (SP manifest at physical FF-A instance) and serves
+two different cases:
+
+- The SPMC resides at S-EL1: the SPMC manifest is used by the SPMD to setup a
+ SP that co-resides with the SPMC and executes at S-EL1 or Secure Supervisor
+ mode.
+- The SPMC resides at S-EL2: the SPMC manifest is used by the SPMD to setup
+ the environment required by the SPMC to run at S-EL2. SPs run at S-EL1 or
+ S-EL0.
+
+.. code:: shell
+
+ attribute {
+ spmc_id = <0x8000>;
+ maj_ver = <0x1>;
+ min_ver = <0x1>;
+ exec_state = <0x0>;
+ load_address = <0x0 0x6000000>;
+ entrypoint = <0x0 0x6000000>;
+ binary_size = <0x60000>;
+ };
+
+- *spmc_id* defines the endpoint ID value that SPMC can query through
+ ``FFA_ID_GET``.
+- *maj_ver/min_ver*. SPMD checks provided version versus its internal
+ version and aborts if not matching.
+- *exec_state* defines the SPMC execution state (AArch64 or AArch32).
+ Notice Hafnium used as a SPMC only supports AArch64.
+- *load_address* and *binary_size* are mostly used to verify secondary
+ entry points fit into the loaded binary image.
+- *entrypoint* defines the cold boot primary core entry point used by
+ SPMD (currently matches ``BL32_BASE``) to enter the SPMC.
+
+Other nodes in the manifest are consumed by Hafnium in the secure world.
+A sample can be found at `[7]`_:
+
+- The *hypervisor* node describes SPs. *is_ffa_partition* boolean attribute
+ indicates a FF-A compliant SP. The *load_address* field specifies the load
+ address at which BL2 loaded the SP package.
+- *cpus* node provide the platform topology and allows MPIDR to VMPIDR mapping.
+ Note the primary core is declared first, then secondary cores are declared
+ in reverse order.
+- The *memory* node provides platform information on the ranges of memory
+ available to the SPMC.
+
+SPMC boot
+~~~~~~~~~
+
+The SPMC is loaded by BL2 as the BL32 image.
+
+The SPMC manifest is loaded by BL2 as the ``TOS_FW_CONFIG`` image `[9]`_.
+
+BL2 passes the SPMC manifest address to BL31 through a register.
+
+At boot time, the SPMD in BL31 runs from the primary core, initializes the core
+contexts and launches the SPMC (BL32) passing the following information through
+registers:
+
+- X0 holds the ``TOS_FW_CONFIG`` physical address (or SPMC manifest blob).
+- X1 holds the ``HW_CONFIG`` physical address.
+- X4 holds the currently running core linear id.
+
+Loading of SPs
+~~~~~~~~~~~~~~
+
+At boot time, BL2 loads SPs sequentially in addition to the SPMC as depicted
+below:
+
+.. uml:: ../resources/diagrams/plantuml/bl2-loading-sp.puml
+
+Note this boot flow is an implementation sample on Arm's FVP platform.
+Platforms not using TF-A's *Firmware CONFiguration* framework would adjust to a
+different boot flow. The flow restricts to a maximum of 8 secure partitions.
+
+Secure boot
+~~~~~~~~~~~
+
+The SP content certificate is inserted as a separate FIP item so that BL2 loads SPMC,
+SPMC manifest, secure partitions and verifies them for authenticity and integrity.
+Refer to TBBR specification `[3]`_.
+
+The multiple-signing domain feature (in current state dual signing domain `[8]`_) allows
+the use of two root keys namely S-ROTPK and NS-ROTPK:
+
+- SPMC (BL32) and SPMC manifest are signed by the SiP using the S-ROTPK.
+- BL33 may be signed by the OEM using NS-ROTPK.
+- An SP may be signed either by SiP (using S-ROTPK) or by OEM (using NS-ROTPK).
+- A maximum of 4 partitions can be signed with the S-ROTPK key and 4 partitions
+ signed with the NS-ROTPK key.
+
+Also refer to `Describing secure partitions`_ and `TF-A build options`_ sections.
+
+Hafnium in the secure world
+===========================
+
+General considerations
+----------------------
+
+Build platform for the secure world
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+In the Hafnium reference implementation specific code parts are only relevant to
+the secure world. Such portions are isolated in architecture specific files
+and/or enclosed by a ``SECURE_WORLD`` macro.
+
+Secure partitions scheduling
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The FF-A specification `[1]`_ provides two ways to relinquinsh CPU time to
+secure partitions. For this a VM (Hypervisor or OS kernel), or SP invokes one of:
+
+- the FFA_MSG_SEND_DIRECT_REQ interface.
+- the FFA_RUN interface.
+
+Additionally a secure interrupt can pre-empt the normal world execution and give
+CPU cycles by transitioning to EL3 and S-EL2.
+
+Platform topology
+~~~~~~~~~~~~~~~~~
+
+The *execution-ctx-count* SP manifest field can take the value of one or the
+total number of PEs. The FF-A specification `[1]`_ recommends the
+following SP types:
+
+- Pinned MP SPs: an execution context matches a physical PE. MP SPs must
+ implement the same number of ECs as the number of PEs in the platform.
+- Migratable UP SPs: a single execution context can run and be migrated on any
+ physical PE. Such SP declares a single EC in its SP manifest. An UP SP can
+ receive a direct message request originating from any physical core targeting
+ the single execution context.
+
+Parsing SP partition manifests
+------------------------------
+
+Hafnium consumes SP manifests as defined in `[1]`_ and `SP manifests`_.
+Note the current implementation may not implement all optional fields.
+
+The SP manifest may contain memory and device regions nodes. In case of
+an S-EL2 SPMC:
+
+- Memory regions are mapped in the SP EL1&0 Stage-2 translation regime at
+ load time (or EL1&0 Stage-1 for an S-EL1 SPMC). A memory region node can
+ specify RX/TX buffer regions in which case it is not necessary for an SP
+ to explicitly invoke the ``FFA_RXTX_MAP`` interface.
+- Device regions are mapped in the SP EL1&0 Stage-2 translation regime (or
+ EL1&0 Stage-1 for an S-EL1 SPMC) as peripherals and possibly allocate
+ additional resources (e.g. interrupts).
+
+For the S-EL2 SPMC, base addresses for memory and device region nodes are IPAs
+provided the SPMC identity maps IPAs to PAs within SP EL1&0 Stage-2 translation
+regime.
+
+Note: in the current implementation both VTTBR_EL2 and VSTTBR_EL2 point to the
+same set of page tables. It is still open whether two sets of page tables shall
+be provided per SP. The memory region node as defined in the specification
+provides a memory security attribute hinting to map either to the secure or
+non-secure EL1&0 Stage-2 table if it exists.
+
+Passing boot data to the SP
+---------------------------
+
+In `[1]`_ , the section "Boot information protocol" defines a method for passing
+data to the SPs at boot time. It specifies the format for the boot information
+descriptor and boot information header structures, which describe the data to be
+exchanged between SPMC and SP.
+The specification also defines the types of data that can be passed.
+The aggregate of both the boot info structures and the data itself is designated
+the boot information blob, and is passed to a Partition as a contiguous memory
+region.
+
+Currently, the SPM implementation supports the FDT type which is used to pass the
+partition's DTB manifest.
+
+The region for the boot information blob is allocated through the SP package.
+
+.. image:: ../resources/diagrams/partition-package.png
+
+To adjust the space allocated for the boot information blob, the json description
+of the SP (see section `Describing secure partitions`_) shall be updated to contain
+the manifest offset. If no offset is provided the manifest offset defaults to 0x1000,
+which is the page size in the Hafnium SPMC.
+
+The configuration of the boot protocol is done in the SPs manifest. As defined by
+the specification, the manifest field 'gp-register-num' configures the GP register
+which shall be used to pass the address to the partitions boot information blob when
+booting the partition.
+In addition, the Hafnium SPMC implementation requires the boot information arguments
+to be listed in a designated DT node:
+
+.. code:: shell
+
+ boot-info {
+ compatible = "arm,ffa-manifest-boot-info";
+ ffa_manifest;
+ };
+
+The whole secure partition package image (see `Secure Partition packages`_) is
+mapped to the SP secure EL1&0 Stage-2 translation regime. As such, the SP can
+retrieve the address for the boot information blob in the designated GP register,
+process the boot information header and descriptors, access its own manifest
+DTB blob and extract its partition manifest properties.
+
+SP Boot order
+-------------
+
+SP manifests provide an optional boot order attribute meant to resolve
+dependencies such as an SP providing a service required to properly boot
+another SP. SPMC boots the SPs in accordance to the boot order attribute,
+lowest to the highest value. If the boot order attribute is absent from the FF-A
+manifest, the SP is treated as if it had the highest boot order value
+(i.e. lowest booting priority).
+
+It is possible for an SP to call into another SP through a direct request
+provided the latter SP has already been booted.
+
+Boot phases
+-----------
+
+Primary core boot-up
+~~~~~~~~~~~~~~~~~~~~
+
+Upon boot-up, BL31 hands over to the SPMC (BL32) on the primary boot physical
+core. The SPMC performs its platform initializations and registers the SPMC
+secondary physical core entry point physical address by the use of the
+`FFA_SECONDARY_EP_REGISTER`_ interface (SMC invocation from the SPMC to the SPMD
+at secure physical FF-A instance).
+
+The SPMC then creates secure partitions based on SP packages and manifests. Each
+secure partition is launched in sequence (`SP Boot order`_) on their "primary"
+execution context. If the primary boot physical core linear id is N, an MP SP is
+started using EC[N] on PE[N] (see `Platform topology`_). If the partition is a
+UP SP, it is started using its unique EC0 on PE[N].
+
+The SP primary EC (or the EC used when the partition is booted as described
+above):
+
+- Performs the overall SP boot time initialization, and in case of a MP SP,
+ prepares the SP environment for other execution contexts.
+- In the case of a MP SP, it invokes the FFA_SECONDARY_EP_REGISTER at secure
+ virtual FF-A instance (SMC invocation from SP to SPMC) to provide the IPA
+ entry point for other execution contexts.
+- Exits through ``FFA_MSG_WAIT`` to indicate successful initialization or
+ ``FFA_ERROR`` in case of failure.
+
+Secondary cores boot-up
+~~~~~~~~~~~~~~~~~~~~~~~
+
+Once the system is started and NWd brought up, a secondary physical core is
+woken up by the ``PSCI_CPU_ON`` service invocation. The TF-A SPD hook mechanism
+calls into the SPMD on the newly woken up physical core. Then the SPMC is
+entered at the secondary physical core entry point.
+
+In the current implementation, the first SP is resumed on the coresponding EC
+(the virtual CPU which matches the physical core). The implication is that the
+first SP must be a MP SP.
+
+In a linux based system, once secure and normal worlds are booted but prior to
+a NWd FF-A driver has been loaded:
+
+- The first SP has initialized all its ECs in response to primary core boot up
+ (at system initialization) and secondary core boot up (as a result of linux
+ invoking PSCI_CPU_ON for all secondary cores).
+- Other SPs have their first execution context initialized as a result of secure
+ world initialization on the primary boot core. Other ECs for those SPs have to
+ be run first through ffa_run to complete their initialization (which results
+ in the EC completing with FFA_MSG_WAIT).
+
+Refer to `Power management`_ for further details.
+
+Notifications
+-------------
+
+The FF-A v1.1 specification `[1]`_ defines notifications as an asynchronous
+communication mechanism with non-blocking semantics. It allows for one FF-A
+endpoint to signal another for service provision, without hindering its current
+progress.
+
+Hafnium currently supports 64 notifications. The IDs of each notification define
+a position in a 64-bit bitmap.
+
+The signaling of notifications can interchangeably happen between NWd and SWd
+FF-A endpoints.
+
+The SPMC is in charge of managing notifications from SPs to SPs, from SPs to
+VMs, and from VMs to SPs. An hypervisor component would only manage
+notifications from VMs to VMs. Given the SPMC has no visibility of the endpoints
+deployed in NWd, the Hypervisor or OS kernel must invoke the interface
+FFA_NOTIFICATION_BITMAP_CREATE to allocate the notifications bitmap per FF-A
+endpoint in the NWd that supports it.
+
+A sender can signal notifications once the receiver has provided it with
+permissions. Permissions are provided by invoking the interface
+FFA_NOTIFICATION_BIND.
+
+Notifications are signaled by invoking FFA_NOTIFICATION_SET. Henceforth
+they are considered to be in a pending sate. The receiver can retrieve its
+pending notifications invoking FFA_NOTIFICATION_GET, which, from that moment,
+are considered to be handled.
+
+Per the FF-A v1.1 spec, each FF-A endpoint must be associated with a scheduler
+that is in charge of donating CPU cycles for notifications handling. The
+FF-A driver calls FFA_NOTIFICATION_INFO_GET to retrieve the information about
+which FF-A endpoints have pending notifications. The receiver scheduler is
+called and informed by the FF-A driver, and it should allocate CPU cycles to the
+receiver.
+
+There are two types of notifications supported:
+
+- Global, which are targeted to a FF-A endpoint and can be handled within any of
+ its execution contexts, as determined by the scheduler of the system.
+- Per-vCPU, which are targeted to a FF-A endpoint and to be handled within a
+ a specific execution context, as determined by the sender.
+
+The type of a notification is set when invoking FFA_NOTIFICATION_BIND to give
+permissions to the sender.
+
+Notification signaling resorts to two interrupts:
+
+- Schedule Receiver Interrupt: non-secure physical interrupt to be handled by
+ the FF-A driver within the receiver scheduler. At initialization the SPMC
+ donates a SGI ID chosen from the secure SGI IDs range and configures it as
+ non-secure. The SPMC triggers this SGI on the currently running core when
+ there are pending notifications, and the respective receivers need CPU cycles
+ to handle them.
+- Notifications Pending Interrupt: virtual interrupt to be handled by the
+ receiver of the notification. Set when there are pending notifications for the
+ given secure partition. The NPI is pended when the NWd relinquishes CPU cycles
+ to an SP.
+
+The notifications receipt support is enabled in the partition FF-A manifest.
+
+Mandatory interfaces
+--------------------
+
+The following interfaces are exposed to SPs:
+
+- ``FFA_VERSION``
+- ``FFA_FEATURES``
+- ``FFA_RX_RELEASE``
+- ``FFA_RXTX_MAP``
+- ``FFA_RXTX_UNMAP``
+- ``FFA_PARTITION_INFO_GET``
+- ``FFA_ID_GET``
+- ``FFA_MSG_WAIT``
+- ``FFA_MSG_SEND_DIRECT_REQ``
+- ``FFA_MSG_SEND_DIRECT_RESP``
+- ``FFA_MEM_DONATE``
+- ``FFA_MEM_LEND``
+- ``FFA_MEM_SHARE``
+- ``FFA_MEM_RETRIEVE_REQ``
+- ``FFA_MEM_RETRIEVE_RESP``
+- ``FFA_MEM_RELINQUISH``
+- ``FFA_MEM_FRAG_RX``
+- ``FFA_MEM_FRAG_TX``
+- ``FFA_MEM_RECLAIM``
+- ``FFA_RUN``
+
+As part of the FF-A v1.1 support, the following interfaces were added:
+
+ - ``FFA_NOTIFICATION_BITMAP_CREATE``
+ - ``FFA_NOTIFICATION_BITMAP_DESTROY``
+ - ``FFA_NOTIFICATION_BIND``
+ - ``FFA_NOTIFICATION_UNBIND``
+ - ``FFA_NOTIFICATION_SET``
+ - ``FFA_NOTIFICATION_GET``
+ - ``FFA_NOTIFICATION_INFO_GET``
+ - ``FFA_SPM_ID_GET``
+ - ``FFA_SECONDARY_EP_REGISTER``
+ - ``FFA_MEM_PERM_GET``
+ - ``FFA_MEM_PERM_SET``
+ - ``FFA_MSG_SEND2``
+ - ``FFA_RX_ACQUIRE``
+
+FFA_VERSION
+~~~~~~~~~~~
+
+``FFA_VERSION`` requires a *requested_version* parameter from the caller.
+The returned value depends on the caller:
+
+- Hypervisor or OS kernel in NS-EL1/EL2: the SPMD returns the SPMC version
+ specified in the SPMC manifest.
+- SP: the SPMC returns its own implemented version.
+- SPMC at S-EL1/S-EL2: the SPMD returns its own implemented version.
+
+FFA_FEATURES
+~~~~~~~~~~~~
+
+FF-A features supported by the SPMC may be discovered by secure partitions at
+boot (that is prior to NWd is booted) or run-time.
+
+The SPMC calling FFA_FEATURES at secure physical FF-A instance always get
+FFA_SUCCESS from the SPMD.
+
+The request made by an Hypervisor or OS kernel is forwarded to the SPMC and
+the response relayed back to the NWd.
+
+FFA_RXTX_MAP/FFA_RXTX_UNMAP
+~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+When invoked from a secure partition FFA_RXTX_MAP maps the provided send and
+receive buffers described by their IPAs to the SP EL1&0 Stage-2 translation
+regime as secure buffers in the MMU descriptors.
+
+When invoked from the Hypervisor or OS kernel, the buffers are mapped into the
+SPMC EL2 Stage-1 translation regime and marked as NS buffers in the MMU
+descriptors. The provided addresses may be owned by a VM in the normal world,
+which is expected to receive messages from the secure world. The SPMC will in
+this case allocate internal state structures to facilitate RX buffer access
+synchronization (through FFA_RX_ACQUIRE interface), and to permit SPs to send
+messages.
+
+The FFA_RXTX_UNMAP unmaps the RX/TX pair from the translation regime of the
+caller, either it being the Hypervisor or OS kernel, as well as a secure
+partition.
+
+FFA_PARTITION_INFO_GET
+~~~~~~~~~~~~~~~~~~~~~~
+
+Partition info get call can originate:
+
+- from SP to SPMC
+- from Hypervisor or OS kernel to SPMC. The request is relayed by the SPMD.
+
+FFA_ID_GET
+~~~~~~~~~~
+
+The FF-A id space is split into a non-secure space and secure space:
+
+- FF-A ID with bit 15 clear relates to VMs.
+- FF-A ID with bit 15 set related to SPs.
+- FF-A IDs 0, 0xffff, 0x8000 are assigned respectively to the Hypervisor, SPMD
+ and SPMC.
+
+The SPMD returns:
+
+- The default zero value on invocation from the Hypervisor.
+- The ``spmc_id`` value specified in the SPMC manifest on invocation from
+ the SPMC (see `SPMC manifest`_)
+
+This convention helps the SPMC to determine the origin and destination worlds in
+an FF-A ABI invocation. In particular the SPMC shall filter unauthorized
+transactions in its world switch routine. It must not be permitted for a VM to
+use a secure FF-A ID as origin world by spoofing:
+
+- A VM-to-SP direct request/response shall set the origin world to be non-secure
+ (FF-A ID bit 15 clear) and destination world to be secure (FF-A ID bit 15
+ set).
+- Similarly, an SP-to-SP direct request/response shall set the FF-A ID bit 15
+ for both origin and destination IDs.
+
+An incoming direct message request arriving at SPMD from NWd is forwarded to
+SPMC without a specific check. The SPMC is resumed through eret and "knows" the
+message is coming from normal world in this specific code path. Thus the origin
+endpoint ID must be checked by SPMC for being a normal world ID.
+
+An SP sending a direct message request must have bit 15 set in its origin
+endpoint ID and this can be checked by the SPMC when the SP invokes the ABI.
+
+The SPMC shall reject the direct message if the claimed world in origin endpoint
+ID is not consistent:
+
+- It is either forwarded by SPMD and thus origin endpoint ID must be a "normal
+ world ID",
+- or initiated by an SP and thus origin endpoint ID must be a "secure world ID".
+
+
+FFA_MSG_SEND_DIRECT_REQ/FFA_MSG_SEND_DIRECT_RESP
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+This is a mandatory interface for secure partitions consisting in direct request
+and responses with the following rules:
+
+- An SP can send a direct request to another SP.
+- An SP can receive a direct request from another SP.
+- An SP can send a direct response to another SP.
+- An SP cannot send a direct request to an Hypervisor or OS kernel.
+- An Hypervisor or OS kernel can send a direct request to an SP.
+- An SP can send a direct response to an Hypervisor or OS kernel.
+
+FFA_NOTIFICATION_BITMAP_CREATE/FFA_NOTIFICATION_BITMAP_DESTROY
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The secure partitions notifications bitmap are statically allocated by the SPMC.
+Hence, this interface is not to be issued by secure partitions.
+
+At initialization, the SPMC is not aware of VMs/partitions deployed in the
+normal world. Hence, the Hypervisor or OS kernel must use both ABIs for SPMC
+to be prepared to handle notifications for the provided VM ID.
+
+FFA_NOTIFICATION_BIND/FFA_NOTIFICATION_UNBIND
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Pair of interfaces to manage permissions to signal notifications. Prior to
+handling notifications, an FF-A endpoint must allow a given sender to signal a
+bitmap of notifications.
+
+If the receiver doesn't have notification support enabled in its FF-A manifest,
+it won't be able to bind notifications, hence forbidding it to receive any
+notifications.
+
+FFA_NOTIFICATION_SET/FFA_NOTIFICATION_GET
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+FFA_NOTIFICATION_GET retrieves all pending global notifications and
+per-vCPU notifications targeted to the current vCPU.
+
+Hafnium maintains a global count of pending notifications which gets incremented
+and decremented when handling FFA_NOTIFICATION_SET and FFA_NOTIFICATION_GET
+respectively. A delayed SRI is triggered if the counter is non-zero when the
+SPMC returns to normal world.
+
+FFA_NOTIFICATION_INFO_GET
+~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Hafnium maintains a global count of pending notifications whose information
+has been retrieved by this interface. The count is incremented and decremented
+when handling FFA_NOTIFICATION_INFO_GET and FFA_NOTIFICATION_GET respectively.
+It also tracks notifications whose information has been retrieved individually,
+such that it avoids duplicating returned information for subsequent calls to
+FFA_NOTIFICATION_INFO_GET. For each notification, this state information is
+reset when receiver called FFA_NOTIFICATION_GET to retrieve them.
+
+FFA_SPM_ID_GET
+~~~~~~~~~~~~~~
+
+Returns the FF-A ID allocated to an SPM component which can be one of SPMD
+or SPMC.
+
+At initialization, the SPMC queries the SPMD for the SPMC ID, using the
+FFA_ID_GET interface, and records it. The SPMC can also query the SPMD ID using
+the FFA_SPM_ID_GET interface at the secure physical FF-A instance.
+
+Secure partitions call this interface at the virtual FF-A instance, to which
+the SPMC returns the priorly retrieved SPMC ID.
+
+The Hypervisor or OS kernel can issue the FFA_SPM_ID_GET call handled by the
+SPMD, which returns the SPMC ID.
+
+FFA_SECONDARY_EP_REGISTER
+~~~~~~~~~~~~~~~~~~~~~~~~~
+
+When the SPMC boots, all secure partitions are initialized on their primary
+Execution Context.
+
+The FFA_SECONDARY_EP_REGISTER interface is to be used by a secure partition
+from its first execution context, to provide the entry point address for
+secondary execution contexts.
+
+A secondary EC is first resumed either upon invocation of PSCI_CPU_ON from
+the NWd or by invocation of FFA_RUN.
+
+FFA_RX_ACQUIRE/FFA_RX_RELEASE
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+The RX buffers can be used to pass information to an FF-A endpoint in the
+following scenarios:
+
+ - When it was targetted by a FFA_MSG_SEND2 invokation from another endpoint.
+ - Return the result of calling ``FFA_PARTITION_INFO_GET``.
+ - In a memory share operation, as part of the ``FFA_MEM_RETRIEVE_RESP``,
+ with the memory descriptor of the shared memory.
+
+If a normal world VM is expected to exchange messages with secure world,
+its RX/TX buffer addresses are forwarded to the SPMC via FFA_RXTX_MAP ABI,
+and are from this moment owned by the SPMC.
+The hypervisor must call the FFA_RX_ACQUIRE interface before attempting
+to use the RX buffer, in any of the aforementioned scenarios. A successful
+call to FFA_RX_ACQUIRE transfers ownership of RX buffer to hypervisor, such
+that it can be safely used.
+
+The FFA_RX_RELEASE interface is used after the FF-A endpoint is done with
+processing the data received in its RX buffer. If the RX buffer has been
+acquired by the hypervisor, the FFA_RX_RELEASE call must be forwarded to
+the SPMC to reestablish SPMC's RX ownership.
+
+An attempt from an SP to send a message to a normal world VM whose RX buffer
+was acquired by the hypervisor fails with error code FFA_BUSY, to preserve
+the RX buffer integrity.
+The operation could then be conducted after FFA_RX_RELEASE.
+
+FFA_MSG_SEND2
+~~~~~~~~~~~~~
+
+Hafnium copies a message from the sender TX buffer into receiver's RX buffer.
+For messages from SPs to VMs, operation is only possible if the SPMC owns
+the receiver's RX buffer.
+
+Both receiver and sender need to enable support for indirect messaging,
+in their respective partition manifest. The discovery of support
+of such feature can be done via FFA_PARTITION_INFO_GET.
+
+On a successful message send, Hafnium pends an RX buffer full framework
+notification for the receiver, to inform it about a message in the RX buffer.
+
+The handling of framework notifications is similar to that of
+global notifications. Binding of these is not necessary, as these are
+reserved to be used by the hypervisor or SPMC.
+
+SPMC-SPMD direct requests/responses
+-----------------------------------
+
+Implementation-defined FF-A IDs are allocated to the SPMC and SPMD.
+Using those IDs in source/destination fields of a direct request/response
+permits SPMD to SPMC communication and either way.
+
+- SPMC to SPMD direct request/response uses SMC conduit.
+- SPMD to SPMC direct request/response uses ERET conduit.
+
+This is used in particular to convey power management messages.
+
+PE MMU configuration
+--------------------
+
+With secure virtualization enabled (``HCR_EL2.VM = 1``) and for S-EL1
+partitions, two IPA spaces (secure and non-secure) are output from the
+secure EL1&0 Stage-1 translation.
+The EL1&0 Stage-2 translation hardware is fed by:
+
+- A secure IPA when the SP EL1&0 Stage-1 MMU is disabled.
+- One of secure or non-secure IPA when the secure EL1&0 Stage-1 MMU is enabled.
+
+``VTCR_EL2`` and ``VSTCR_EL2`` provide configuration bits for controlling the
+NS/S IPA translations. The following controls are set up:
+``VSTCR_EL2.SW = 0`` , ``VSTCR_EL2.SA = 0``, ``VTCR_EL2.NSW = 0``,
+``VTCR_EL2.NSA = 1``:
+
+- Stage-2 translations for the NS IPA space access the NS PA space.
+- Stage-2 translation table walks for the NS IPA space are to the secure PA space.
+
+Secure and non-secure IPA regions (rooted to by ``VTTBR_EL2`` and ``VSTTBR_EL2``)
+use the same set of Stage-2 page tables within a SP.
+
+The ``VTCR_EL2/VSTCR_EL2/VTTBR_EL2/VSTTBR_EL2`` virtual address space
+configuration is made part of a vCPU context.
+
+For S-EL0 partitions with VHE enabled, a single secure EL2&0 Stage-1 translation
+regime is used for both Hafnium and the partition.
+
+Schedule modes and SP Call chains
+---------------------------------
+
+An SP execution context is said to be in SPMC scheduled mode if CPU cycles are
+allocated to it by SPMC. Correspondingly, an SP execution context is said to be
+in Normal world scheduled mode if CPU cycles are allocated by the normal world.
+
+A call chain represents all SPs in a sequence of invocations of a direct message
+request. When execution on a PE is in the secure state, only a single call chain
+that runs in the Normal World scheduled mode can exist. FF-A v1.1 spec allows
+any number of call chains to run in the SPMC scheduled mode but the Hafnium
+SPMC restricts the number of call chains in SPMC scheduled mode to only one for
+keeping the implementation simple.
+
+Partition runtime models
+------------------------
+
+The runtime model of an endpoint describes the transitions permitted for an
+execution context between various states. These are the four partition runtime
+models supported (refer to `[1]`_ section 7):
+
+ - RTM_FFA_RUN: runtime model presented to an execution context that is
+ allocated CPU cycles through FFA_RUN interface.
+ - RTM_FFA_DIR_REQ: runtime model presented to an execution context that is
+ allocated CPU cycles through FFA_MSG_SEND_DIRECT_REQ interface.
+ - RTM_SEC_INTERRUPT: runtime model presented to an execution context that is
+ allocated CPU cycles by SPMC to handle a secure interrupt.
+ - RTM_SP_INIT: runtime model presented to an execution context that is
+ allocated CPU cycles by SPMC to initialize its state.
+
+If an endpoint execution context attempts to make an invalid transition or a
+valid transition that could lead to a loop in the call chain, SPMC denies the
+transition with the help of above runtime models.
+
+Interrupt management
+--------------------
+
+GIC ownership
+~~~~~~~~~~~~~
+
+The SPMC owns the GIC configuration. Secure and non-secure interrupts are
+trapped at S-EL2. The SPMC manages interrupt resources and allocates interrupt
+IDs based on SP manifests. The SPMC acknowledges physical interrupts and injects
+virtual interrupts by setting the use of vIRQ/vFIQ bits before resuming a SP.
+
+Abbreviations:
+
+ - NS-Int: A non-secure physical interrupt. It requires a switch to the normal
+ world to be handled if it triggers while execution is in secure world.
+ - Other S-Int: A secure physical interrupt targeted to an SP different from
+ the one that is currently running.
+ - Self S-Int: A secure physical interrupt targeted to the SP that is currently
+ running.
+
+Non-secure interrupt handling
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+This section documents the actions supported in SPMC in response to a non-secure
+interrupt as per the guidance provided by FF-A v1.1 EAC0 specification.
+An SP specifies one of the following actions in its partition manifest:
+
+ - Non-secure interrupt is signaled.
+ - Non-secure interrupt is signaled after a managed exit.
+ - Non-secure interrupt is queued.
+
+An SP execution context in a call chain could specify a less permissive action
+than subsequent SP execution contexts in the same call chain. The less
+permissive action takes precedence over the more permissive actions specified
+by the subsequent execution contexts. Please refer to FF-A v1.1 EAC0 section
+8.3.1 for further explanation.
+
+Secure interrupt handling
+~~~~~~~~~~~~~~~~~~~~~~~~~
+
+This section documents the support implemented for secure interrupt handling in
+SPMC as per the guidance provided by FF-A v1.1 EAC0 specification.
+The following assumptions are made about the system configuration:
+
+ - In the current implementation, S-EL1 SPs are expected to use the para
+ virtualized ABIs for interrupt management rather than accessing the virtual
+ GIC interface.
+ - Unless explicitly stated otherwise, this support is applicable only for
+ S-EL1 SPs managed by SPMC.
+ - Secure interrupts are configured as G1S or G0 interrupts.
+ - All physical interrupts are routed to SPMC when running a secure partition
+ execution context.
+ - All endpoints with multiple execution contexts have their contexts pinned
+ to corresponding CPUs. Hence, a secure virtual interrupt cannot be signaled
+ to a target vCPU that is currently running or blocked on a different
+ physical CPU.
+
+A physical secure interrupt could trigger while CPU is executing in normal world
+or secure world.
+The action of SPMC for a secure interrupt depends on: the state of the target
+execution context of the SP that is responsible for handling the interrupt;
+whether the interrupt triggered while execution was in normal world or secure
+world.
+
+Secure interrupt signaling mechanisms
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Signaling refers to the mechanisms used by SPMC to indicate to the SP execution
+context that it has a pending virtual interrupt and to further run the SP
+execution context, such that it can handle the virtual interrupt. SPMC uses
+either the FFA_INTERRUPT interface with ERET conduit or vIRQ signal for signaling
+to S-EL1 SPs. When normal world execution is preempted by a secure interrupt,
+the SPMD uses the FFA_INTERRUPT ABI with ERET conduit to signal interrupt to SPMC
+running in S-EL2.
+
++-----------+---------+---------------+---------------------------------------+
+| SP State | Conduit | Interface and | Description |
+| | | parameters | |
++-----------+---------+---------------+---------------------------------------+
+| WAITING | ERET, | FFA_INTERRUPT,| SPMC signals to SP the ID of pending |
+| | vIRQ | Interrupt ID | interrupt. It pends vIRQ signal and |
+| | | | resumes execution context of SP |
+| | | | through ERET. |
++-----------+---------+---------------+---------------------------------------+
+| BLOCKED | ERET, | FFA_INTERRUPT | SPMC signals to SP that an interrupt |
+| | vIRQ | | is pending. It pends vIRQ signal and |
+| | | | resumes execution context of SP |
+| | | | through ERET. |
++-----------+---------+---------------+---------------------------------------+
+| PREEMPTED | vIRQ | NA | SPMC pends the vIRQ signal but does |
+| | | | not resume execution context of SP. |
++-----------+---------+---------------+---------------------------------------+
+| RUNNING | ERET, | NA | SPMC pends the vIRQ signal and resumes|
+| | vIRQ | | execution context of SP through ERET. |
++-----------+---------+---------------+---------------------------------------+
+
+Secure interrupt completion mechanisms
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+A SP signals secure interrupt handling completion to the SPMC through the
+following mechanisms:
+
+ - ``FFA_MSG_WAIT`` ABI if it was in WAITING state.
+ - ``FFA_RUN`` ABI if its was in BLOCKED state.
+
+This is a remnant of SPMC implementation based on the FF-A v1.0 specification.
+In the current implementation, S-EL1 SPs use the para-virtualized HVC interface
+implemented by SPMC to perform priority drop and interrupt deactivation (SPMC
+configures EOImode = 0, i.e. priority drop and deactivation are done together).
+The SPMC performs checks to deny the state transition upon invocation of
+either FFA_MSG_WAIT or FFA_RUN interface if the SP didn't perform the
+deactivation of the secure virtual interrupt.
+
+If the current SP execution context was preempted by a secure interrupt to be
+handled by execution context of target SP, SPMC resumes current SP after signal
+completion by target SP execution context.
+
+Actions for a secure interrupt triggered while execution is in normal world
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
++-------------------+----------+-----------------------------------------------+
+| State of target | Action | Description |
+| execution context | | |
++-------------------+----------+-----------------------------------------------+
+| WAITING | Signaled | This starts a new call chain in SPMC scheduled|
+| | | mode. |
++-------------------+----------+-----------------------------------------------+
+| PREEMPTED | Queued | The target execution must have been preempted |
+| | | by a non-secure interrupt. SPMC queues the |
+| | | secure virtual interrupt now. It is signaled |
+| | | when the target execution context next enters |
+| | | the RUNNING state. |
++-------------------+----------+-----------------------------------------------+
+| BLOCKED, RUNNING | NA | The target execution context is blocked or |
+| | | running on a different CPU. This is not |
+| | | supported by current SPMC implementation and |
+| | | execution hits panic. |
++-------------------+----------+-----------------------------------------------+
+
+If normal world execution was preempted by a secure interrupt, SPMC uses
+FFA_NORMAL_WORLD_RESUME ABI to indicate completion of secure interrupt handling
+and further returns execution to normal world.
+
+The following figure describes interrupt handling flow when a secure interrupt
+triggers while execution is in normal world:
+
+.. image:: ../resources/diagrams/ffa-secure-interrupt-handling-nwd.png
+
+A brief description of the events:
+
+ - 1) Secure interrupt triggers while normal world is running.
+ - 2) FIQ gets trapped to EL3.
+ - 3) SPMD signals secure interrupt to SPMC at S-EL2 using FFA_INTERRUPT ABI.
+ - 4) SPMC identifies target vCPU of SP and injects virtual interrupt (pends
+ vIRQ).
+ - 5) Assuming SP1 vCPU is in WAITING state, SPMC signals virtual interrupt
+ using FFA_INTERRUPT with interrupt id as an argument and resumes the SP1
+ vCPU using ERET in SPMC scheduled mode.
+ - 6) Execution traps to vIRQ handler in SP1 provided that the virtual
+ interrupt is not masked i.e., PSTATE.I = 0
+ - 7) SP1 queries for the pending virtual interrupt id using a paravirtualized
+ HVC call. SPMC clears the pending virtual interrupt state management
+ and returns the pending virtual interrupt id.
+ - 8) SP1 services the virtual interrupt and invokes the paravirtualized
+ de-activation HVC call. SPMC de-activates the physical interrupt,
+ clears the fields tracking the secure interrupt and resumes SP1 vCPU.
+ - 9) SP1 performs secure interrupt completion through FFA_MSG_WAIT ABI.
+ - 10) SPMC returns control to EL3 using FFA_NORMAL_WORLD_RESUME.
+ - 11) EL3 resumes normal world execution.
+
+Actions for a secure interrupt triggered while execution is in secure world
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
++-------------------+----------+------------------------------------------------+
+| State of target | Action | Description |
+| execution context | | |
++-------------------+----------+------------------------------------------------+
+| WAITING | Signaled | This starts a new call chain in SPMC scheduled |
+| | | mode. |
++-------------------+----------+------------------------------------------------+
+| PREEMPTED by Self | Signaled | The target execution context reenters the |
+| S-Int | | RUNNING state to handle the secure virtual |
+| | | interrupt. |
++-------------------+----------+------------------------------------------------+
+| PREEMPTED by | Queued | SPMC queues the secure virtual interrupt now. |
+| NS-Int | | It is signaled when the target execution |
+| | | context next enters the RUNNING state. |
++-------------------+----------+------------------------------------------------+
+| BLOCKED | Signaled | Both preempted and target execution contexts |
+| | | must have been part of the Normal world |
+| | | scheduled call chain. Refer scenario 1 of |
+| | | Table 8.4 in the FF-A v1.1 EAC0 spec. |
++-------------------+----------+------------------------------------------------+
+| RUNNING | NA | The target execution context is running on a |
+| | | different CPU. This scenario is not supported |
+| | | by current SPMC implementation and execution |
+| | | hits panic. |
++-------------------+----------+------------------------------------------------+
+
+The following figure describes interrupt handling flow when a secure interrupt
+triggers while execution is in secure world. We assume OS kernel sends a direct
+request message to SP1. Further, SP1 sends a direct request message to SP2. SP1
+enters BLOCKED state and SPMC resumes SP2.
+
+.. image:: ../resources/diagrams/ffa-secure-interrupt-handling-swd.png
+
+A brief description of the events:
+
+ - 1) Secure interrupt triggers while SP2 is running.
+ - 2) SP2 gets preempted and execution traps to SPMC as IRQ.
+ - 3) SPMC finds the target vCPU of secure partition responsible for handling
+ this secure interrupt. In this scenario, it is SP1.
+ - 4) SPMC pends vIRQ for SP1 and signals through FFA_INTERRUPT interface.
+ SPMC further resumes SP1 through ERET conduit. Note that SP1 remains in
+ Normal world schedule mode.
+ - 6) Execution traps to vIRQ handler in SP1 provided that the virtual
+ interrupt is not masked i.e., PSTATE.I = 0
+ - 7) SP1 queries for the pending virtual interrupt id using a paravirtualized
+ HVC call. SPMC clears the pending virtual interrupt state management
+ and returns the pending virtual interrupt id.
+ - 8) SP1 services the virtual interrupt and invokes the paravirtualized
+ de-activation HVC call. SPMC de-activates the physical interrupt and
+ clears the fields tracking the secure interrupt and resumes SP1 vCPU.
+ - 9) Since SP1 direct request completed with FFA_INTERRUPT, it resumes the
+ direct request to SP2 by invoking FFA_RUN.
+ - 9) SPMC resumes the pre-empted vCPU of SP2.
+
+Power management
+----------------
+
+In platforms with or without secure virtualization:
+
+- The NWd owns the platform PM policy.
+- The Hypervisor or OS kernel is the component initiating PSCI service calls.
+- The EL3 PSCI library is in charge of the PM coordination and control
+ (eventually writing to platform registers).
+- While coordinating PM events, the PSCI library calls backs into the Secure
+ Payload Dispatcher for events the latter has statically registered to.
+
+When using the SPMD as a Secure Payload Dispatcher:
+
+- A power management event is relayed through the SPD hook to the SPMC.
+- In the current implementation only cpu on (svc_on_finish) and cpu off
+ (svc_off) hooks are registered.
+- The behavior for the cpu on event is described in `Secondary cores boot-up`_.
+ The SPMC is entered through its secondary physical core entry point.
+- The cpu off event occurs when the NWd calls PSCI_CPU_OFF. The PM event is
+ signaled to the SPMC through a power management framework message.
+ It consists in a SPMD-to-SPMC direct request/response (`SPMC-SPMD direct
+ requests/responses`_) conveying the event details and SPMC response.
+ The SPMD performs a synchronous entry into the SPMC. The SPMC is entered and
+ updates its internal state to reflect the physical core is being turned off.
+ In the current implementation no SP is resumed as a consequence. This behavior
+ ensures a minimal support for CPU hotplug e.g. when initiated by the NWd linux
+ userspace.
+
+Arm architecture extensions for security hardening
+==================================================
+
+Hafnium supports the following architecture extensions for security hardening:
+
+- Pointer authentication (FEAT_PAuth): the extension permits detection of forged
+ pointers used by ROP type of attacks through the signing of the pointer
+ value. Hafnium is built with the compiler branch protection option to permit
+ generation of a pointer authentication code for return addresses (pointer
+ authentication for instructions). The APIA key is used while Hafnium runs.
+ A random key is generated at boot time and restored upon entry into Hafnium
+ at run-time. APIA and other keys (APIB, APDA, APDB, APGA) are saved/restored
+ in vCPU contexts permitting to enable pointer authentication in VMs/SPs.
+- Branch Target Identification (FEAT_BTI): the extension permits detection of
+ unexpected indirect branches used by JOP type of attacks. Hafnium is built
+ with the compiler branch protection option, inserting land pads at function
+ prologues that are reached by indirect branch instructions (BR/BLR).
+ Hafnium code pages are marked as guarded in the EL2 Stage-1 MMU descriptors
+ such that an indirect branch must always target a landpad. A fault is
+ triggered otherwise. VMs/SPs can (independently) mark their code pages as
+ guarded in the EL1&0 Stage-1 translation regime.
+- Memory Tagging Extension (FEAT_MTE): the option permits detection of out of
+ bound memory array accesses or re-use of an already freed memory region.
+ Hafnium enables the compiler option permitting to leverage MTE stack tagging
+ applied to core stacks. Core stacks are marked as normal tagged memory in the
+ EL2 Stage-1 translation regime. A synchronous data abort is generated upon tag
+ check failure on load/stores. A random seed is generated at boot time and
+ restored upon entry into Hafnium. MTE system registers are saved/restored in
+ vCPU contexts permitting MTE usage from VMs/SPs.
+
+SMMUv3 support in Hafnium
+=========================
+
+An SMMU is analogous to an MMU in a CPU. It performs address translations for
+Direct Memory Access (DMA) requests from system I/O devices.
+The responsibilities of an SMMU include:
+
+- Translation: Incoming DMA requests are translated from bus address space to
+ system physical address space using translation tables compliant to
+ Armv8/Armv7 VMSA descriptor format.
+- Protection: An I/O device can be prohibited from read, write access to a
+ memory region or allowed.
+- Isolation: Traffic from each individial device can be independently managed.
+ The devices are differentiated from each other using unique translation
+ tables.
+
+The following diagram illustrates a typical SMMU IP integrated in a SoC with
+several I/O devices along with Interconnect and Memory system.
+
+.. image:: ../resources/diagrams/MMU-600.png
+
+SMMU has several versions including SMMUv1, SMMUv2 and SMMUv3. Hafnium provides
+support for SMMUv3 driver in both normal and secure world. A brief introduction
+of SMMUv3 functionality and the corresponding software support in Hafnium is
+provided here.
+
+SMMUv3 features
+---------------
+
+- SMMUv3 provides Stage1, Stage2 translation as well as nested (Stage1 + Stage2)
+ translation support. It can either bypass or abort incoming translations as
+ well.
+- Traffic (memory transactions) from each upstream I/O peripheral device,
+ referred to as Stream, can be independently managed using a combination of
+ several memory based configuration structures. This allows the SMMUv3 to
+ support a large number of streams with each stream assigned to a unique
+ translation context.
+- Support for Armv8.1 VMSA where the SMMU shares the translation tables with
+ a Processing Element. AArch32(LPAE) and AArch64 translation table format
+ are supported by SMMUv3.
+- SMMUv3 offers non-secure stream support with secure stream support being
+ optional. Logically, SMMUv3 behaves as if there is an indepdendent SMMU
+ instance for secure and non-secure stream support.
+- It also supports sub-streams to differentiate traffic from a virtualized
+ peripheral associated with a VM/SP.
+- Additionally, SMMUv3.2 provides support for PEs implementing Armv8.4-A
+ extensions. Consequently, SPM depends on Secure EL2 support in SMMUv3.2
+ for providing Secure Stage2 translation support to upstream peripheral
+ devices.
+
+SMMUv3 Programming Interfaces
+-----------------------------
+
+SMMUv3 has three software interfaces that are used by the Hafnium driver to
+configure the behaviour of SMMUv3 and manage the streams.
+
+- Memory based data strutures that provide unique translation context for
+ each stream.
+- Memory based circular buffers for command queue and event queue.
+- A large number of SMMU configuration registers that are memory mapped during
+ boot time by Hafnium driver. Except a few registers, all configuration
+ registers have independent secure and non-secure versions to configure the
+ behaviour of SMMUv3 for translation of secure and non-secure streams
+ respectively.
+
+Peripheral device manifest
+--------------------------
+
+Currently, SMMUv3 driver in Hafnium only supports dependent peripheral devices.
+These devices are dependent on PE endpoint to initiate and receive memory
+management transactions on their behalf. The acccess to the MMIO regions of
+any such device is assigned to the endpoint during boot. Moreover, SMMUv3 driver
+uses the same stage 2 translations for the device as those used by partition
+manager on behalf of the PE endpoint. This ensures that the peripheral device
+has the same visibility of the physical address space as the endpoint. The
+device node of the corresponding partition manifest (refer to `[1]`_ section 3.2
+) must specify these additional properties for each peripheral device in the
+system :
+
+- smmu-id: This field helps to identify the SMMU instance that this device is
+ upstream of.
+- stream-ids: List of stream IDs assigned to this device.
+
+.. code:: shell
+
+ smmuv3-testengine {
+ base-address = <0x00000000 0x2bfe0000>;
+ pages-count = <32>;
+ attributes = <0x3>;
+ smmu-id = <0>;
+ stream-ids = <0x0 0x1>;
+ interrupts = <0x2 0x3>, <0x4 0x5>;
+ exclusive-access;
+ };
+
+SMMUv3 driver limitations
+-------------------------
+
+The primary design goal for the Hafnium SMMU driver is to support secure
+streams.
+
+- Currently, the driver only supports Stage2 translations. No support for
+ Stage1 or nested translations.
+- Supports only AArch64 translation format.
+- No support for features such as PCI Express (PASIDs, ATS, PRI), MSI, RAS,
+ Fault handling, Performance Monitor Extensions, Event Handling, MPAM.
+- No support for independent peripheral devices.
+
+S-EL0 Partition support
+=======================
+The SPMC (Hafnium) has limited capability to run S-EL0 FF-A partitions using
+FEAT_VHE (mandatory with ARMv8.1 in non-secure state, and in secure world
+with ARMv8.4 and FEAT_SEL2).
+
+S-EL0 partitions are useful for simple partitions that don't require full
+Trusted OS functionality. It is also useful to reduce jitter and cycle
+stealing from normal world since they are more lightweight than VMs.
+
+S-EL0 partitions are presented, loaded and initialized the same as S-EL1 VMs by
+the SPMC. They are differentiated primarily by the 'exception-level' property
+and the 'execution-ctx-count' property in the SP manifest. They are host apps
+under the single EL2&0 Stage-1 translation regime controlled by the SPMC and
+call into the SPMC through SVCs as opposed to HVCs and SMCs. These partitions
+can use FF-A defined services (FFA_MEM_PERM_*) to update or change permissions
+for memory regions.
+
+S-EL0 partitions are required by the FF-A specification to be UP endpoints,
+capable of migrating, and the SPMC enforces this requirement. The SPMC allows
+a S-EL0 partition to accept a direct message from secure world and normal world,
+and generate direct responses to them.
+All S-EL0 partitions must use AArch64. AArch32 S-EL0 partitions are not supported.
+
+Memory sharing, indirect messaging, and notifications functionality with S-EL0
+partitions is supported.
+
+Interrupt handling is not supported with S-EL0 partitions and is work in
+progress.
+
+References
+==========
+
+.. _[1]:
+
+[1] `Arm Firmware Framework for Arm A-profile <https://developer.arm.com/docs/den0077/latest>`__
+
+.. _[2]:
+
+[2] :ref:`Secure Partition Manager using MM interface<Secure Partition Manager (MM)>`
+
+.. _[3]:
+
+[3] `Trusted Boot Board Requirements
+Client <https://developer.arm.com/documentation/den0006/d/>`__
+
+.. _[4]:
+
+[4] https://git.trustedfirmware.org/TF-A/trusted-firmware-a.git/tree/lib/el3_runtime/aarch64/context.S#n45
+
+.. _[5]:
+
+[5] https://git.trustedfirmware.org/TF-A/tf-a-tests.git/tree/spm/cactus/plat/arm/fvp/fdts/cactus.dts
+
+.. _[6]:
+
+[6] https://trustedfirmware-a.readthedocs.io/en/latest/components/ffa-manifest-binding.html
+
+.. _[7]:
+
+[7] https://git.trustedfirmware.org/TF-A/trusted-firmware-a.git/tree/plat/arm/board/fvp/fdts/fvp_spmc_manifest.dts
+
+.. _[8]:
+
+[8] https://lists.trustedfirmware.org/archives/list/tf-a@lists.trustedfirmware.org/thread/CFQFGU6H2D5GZYMUYGTGUSXIU3OYZP6U/
+
+.. _[9]:
+
+[9] https://trustedfirmware-a.readthedocs.io/en/latest/design/firmware-design.html#dynamic-configuration-during-cold-boot
+
+--------------
+
+*Copyright (c) 2020-2022, Arm Limited and Contributors. All rights reserved.*