| Translation Tables Library Design |
| ================================= |
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| This document describes the design of the translation tables library (version 2) |
| used by Trusted Firmware-A (TF-A). This library provides APIs to create page |
| tables based on a description of the memory layout, as well as setting up system |
| registers related to the Memory Management Unit (MMU) and performing the |
| required Translation Lookaside Buffer (TLB) maintenance operations. |
| |
| More specifically, some use cases that this library aims to support are: |
| |
| #. Statically allocate translation tables and populate them (at run-time) based |
| on a description of the memory layout. The memory layout is typically |
| provided by the platform port as a list of memory regions; |
| |
| #. Support for generating translation tables pertaining to a different |
| translation regime than the exception level the library code is executing at; |
| |
| #. Support for dynamic mapping and unmapping of regions, even while the MMU is |
| on. This can be used to temporarily map some memory regions and unmap them |
| later on when no longer needed; |
| |
| #. Support for non-identity virtual to physical mappings to compress the virtual |
| address space; |
| |
| #. Support for changing memory attributes of memory regions at run-time. |
| |
| |
| About version 1 and version 2 |
| ----------------------------- |
| |
| This document focuses on version 2 of the library, whose sources are available |
| in the `lib/xlat\_tables\_v2`_ directory. Version 1 of the library can still be |
| found in `lib/xlat\_tables`_ directory but it is less flexible and doesn't |
| support dynamic mapping. Although potential bug fixes will be applied to both |
| versions, future features enhancements will focus on version 2 and might not be |
| back-ported to version 1. Therefore, it is recommended to use version 2, |
| especially for new platform ports. |
| |
| However, please note that version 2 is still in active development and is not |
| considered stable yet. Hence, compatibility breaks might be introduced. |
| |
| From this point onwards, this document will implicitly refer to version 2 of the |
| library. |
| |
| |
| Design concepts and interfaces |
| ------------------------------ |
| |
| This section presents some of the key concepts and data structures used in the |
| translation tables library. |
| |
| `mmap` regions |
| ~~~~~~~~~~~~~~ |
| |
| An ``mmap_region`` is an abstract, concise way to represent a memory region to |
| map. It is one of the key interfaces to the library. It is identified by: |
| |
| - its physical base address; |
| - its virtual base address; |
| - its size; |
| - its attributes; |
| - its mapping granularity (optional). |
| |
| See the ``struct mmap_region`` type in `xlat\_tables\_v2.h`_. |
| |
| The user usually provides a list of such mmap regions to map and lets the |
| library transpose that in a set of translation tables. As a result, the library |
| might create new translation tables, update or split existing ones. |
| |
| The region attributes specify the type of memory (for example device or cached |
| normal memory) as well as the memory access permissions (read-only or |
| read-write, executable or not, secure or non-secure, and so on). In the case of |
| the EL1&0 translation regime, the attributes also specify whether the region is |
| a User region (EL0) or Privileged region (EL1). See the ``MT_xxx`` definitions |
| in `xlat\_tables\_v2.h`_. Note that for the EL1&0 translation regime the Execute |
| Never attribute is set simultaneously for both EL1 and EL0. |
| |
| The granularity controls the translation table level to go down to when mapping |
| the region. For example, assuming the MMU has been configured to use a 4KB |
| granule size, the library might map a 2MB memory region using either of the two |
| following options: |
| |
| - using a single level-2 translation table entry; |
| - using a level-2 intermediate entry to a level-3 translation table (which |
| contains 512 entries, each mapping 4KB). |
| |
| The first solution potentially requires less translation tables, hence |
| potentially less memory. However, if part of this 2MB region is later remapped |
| with different memory attributes, the library might need to split the existing |
| page tables to refine the mappings. If a single level-2 entry has been used |
| here, a level-3 table will need to be allocated on the fly and the level-2 |
| modified to point to this new level-3 table. This has a performance cost at |
| run-time. |
| |
| If the user knows upfront that such a remapping operation is likely to happen |
| then they might enforce a 4KB mapping granularity for this 2MB region from the |
| beginning; remapping some of these 4KB pages on the fly then becomes a |
| lightweight operation. |
| |
| The region's granularity is an optional field; if it is not specified the |
| library will choose the mapping granularity for this region as it sees fit (more |
| details can be found in `The memory mapping algorithm`_ section below). |
| |
| Translation Context |
| ~~~~~~~~~~~~~~~~~~~ |
| |
| The library can create or modify translation tables pertaining to a different |
| translation regime than the exception level the library code is executing at. |
| For example, the library might be used by EL3 software (for instance BL31) to |
| create translation tables pertaining to the S-EL1&0 translation regime. |
| |
| This flexibility comes from the use of *translation contexts*. A *translation |
| context* constitutes the superset of information used by the library to track |
| the status of a set of translation tables for a given translation regime. |
| |
| The library internally allocates a default translation context, which pertains |
| to the translation regime of the current exception level. Additional contexts |
| may be explicitly allocated and initialized using the |
| ``REGISTER_XLAT_CONTEXT()`` macro. Separate APIs are provided to act either on |
| the default translation context or on an alternative one. |
| |
| To register a translation context, the user must provide the library with the |
| following information: |
| |
| * A name. |
| |
| The resulting translation context variable will be called after this name, to |
| which ``_xlat_ctx`` is appended. For example, if the macro name parameter is |
| ``foo``, the context variable name will be ``foo_xlat_ctx``. |
| |
| * The maximum number of `mmap` regions to map. |
| |
| Should account for both static and dynamic regions, if applicable. |
| |
| * The number of sub-translation tables to allocate. |
| |
| Number of translation tables to statically allocate for this context, |
| excluding the initial lookup level translation table, which is always |
| allocated. For example, if the initial lookup level is 1, this parameter would |
| specify the number of level-2 and level-3 translation tables to pre-allocate |
| for this context. |
| |
| * The size of the virtual address space. |
| |
| Size in bytes of the virtual address space to map using this context. This |
| will incidentally determine the number of entries in the initial lookup level |
| translation table : the library will allocate as many entries as is required |
| to map the entire virtual address space. |
| |
| * The size of the physical address space. |
| |
| Size in bytes of the physical address space to map using this context. |
| |
| The default translation context is internally initialized using information |
| coming (for the most part) from platform-specific defines: |
| |
| - name: hard-coded to ``tf`` ; hence the name of the default context variable is |
| ``tf_xlat_ctx``; |
| - number of `mmap` regions: ``MAX_MMAP_REGIONS``; |
| - number of sub-translation tables: ``MAX_XLAT_TABLES``; |
| - size of the virtual address space: ``PLAT_VIRT_ADDR_SPACE_SIZE``; |
| - size of the physical address space: ``PLAT_PHY_ADDR_SPACE_SIZE``. |
| |
| Please refer to the `Porting Guide`_ for more details about these macros. |
| |
| |
| Static and dynamic memory regions |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The library optionally supports dynamic memory mapping. This feature may be |
| enabled using the ``PLAT_XLAT_TABLES_DYNAMIC`` platform build flag. |
| |
| When dynamic memory mapping is enabled, the library categorises mmap regions as |
| *static* or *dynamic*. |
| |
| - *Static regions* are fixed for the lifetime of the system. They can only be |
| added early on, before the translation tables are created and populated. They |
| cannot be removed afterwards. |
| |
| - *Dynamic regions* can be added or removed any time. |
| |
| When the dynamic memory mapping feature is disabled, only static regions exist. |
| |
| The dynamic memory mapping feature may be used to map and unmap transient memory |
| areas. This is useful when the user needs to access some memory for a fixed |
| period of time, after which the memory may be discarded and reclaimed. For |
| example, a memory region that is only required at boot time while the system is |
| initializing, or to temporarily share a memory buffer between the normal world |
| and trusted world. Note that it is up to the caller to ensure that these regions |
| are not accessed concurrently while the regions are being added or removed. |
| |
| Although this feature provides some level of dynamic memory allocation, this |
| does not allow dynamically allocating an arbitrary amount of memory at an |
| arbitrary memory location. The user is still required to declare at compile-time |
| the limits of these allocations ; the library will deny any mapping request that |
| does not fit within this pre-allocated pool of memory. |
| |
| |
| Library APIs |
| ------------ |
| |
| The external APIs exposed by this library are declared and documented in the |
| `xlat\_tables\_v2.h`_ header file. This should be the reference point for |
| getting information about the usage of the different APIs this library |
| provides. This section just provides some extra details and clarifications. |
| |
| Although the ``mmap_region`` structure is a publicly visible type, it is not |
| recommended to populate these structures by hand. Instead, wherever APIs expect |
| function arguments of type ``mmap_region_t``, these should be constructed using |
| the ``MAP_REGION*()`` family of helper macros. This is to limit the risk of |
| compatibility breaks, should the ``mmap_region`` structure type evolve in the |
| future. |
| |
| The ``MAP_REGION()`` and ``MAP_REGION_FLAT()`` macros do not allow specifying a |
| mapping granularity, which leaves the library implementation free to choose |
| it. However, in cases where a specific granularity is required, the |
| ``MAP_REGION2()`` macro might be used instead. |
| |
| As explained earlier in this document, when the dynamic mapping feature is |
| disabled, there is no notion of dynamic regions. Conceptually, there are only |
| static regions. For this reason (and to retain backward compatibility with the |
| version 1 of the library), the APIs that map static regions do not embed the |
| word *static* in their functions names (for example ``mmap_add_region()``), in |
| contrast with the dynamic regions APIs (for example |
| ``mmap_add_dynamic_region()``). |
| |
| Although the definition of static and dynamic regions is not based on the state |
| of the MMU, the two are still related in some way. Static regions can only be |
| added before ``init_xlat_tables()`` is called and ``init_xlat_tables()`` must be |
| called while the MMU is still off. As a result, static regions cannot be added |
| once the MMU has been enabled. Dynamic regions can be added with the MMU on or |
| off. In practice, the usual call flow would look like this: |
| |
| #. The MMU is initially off. |
| |
| #. Add some static regions, add some dynamic regions. |
| |
| #. Initialize translation tables based on the list of mmap regions (using one of |
| the ``init_xlat_tables*()`` APIs). |
| |
| #. At this point, it is no longer possible to add static regions. Dynamic |
| regions can still be added or removed. |
| |
| #. Enable the MMU. |
| |
| #. Dynamic regions can continue to be added or removed. |
| |
| Because static regions are added early on at boot time and are all in the |
| control of the platform initialization code, the ``mmap_add*()`` family of APIs |
| are not expected to fail. They do not return any error code. |
| |
| Nonetheless, these APIs will check upfront whether the region can be |
| successfully added before updating the translation context structure. If the |
| library detects that there is insufficient memory to meet the request, or that |
| the new region will overlap another one in an invalid way, or if any other |
| unexpected error is encountered, they will print an error message on the UART. |
| Additionally, when asserts are enabled (typically in debug builds), an assertion |
| will be triggered. Otherwise, the function call will just return straight away, |
| without adding the offending memory region. |
| |
| |
| Library limitations |
| ------------------- |
| |
| Dynamic regions are not allowed to overlap each other. Static regions are |
| allowed to overlap as long as one of them is fully contained inside the other |
| one. This is allowed for backwards compatibility with the previous behaviour in |
| the version 1 of the library. |
| |
| |
| Implementation details |
| ---------------------- |
| |
| Code structure |
| ~~~~~~~~~~~~~~ |
| |
| The library is divided into 2 modules: |
| |
| The core module |
| Provides the main functionality of the library. |
| |
| See `xlat\_tables\_internal.c`_. |
| |
| The architectural module |
| Provides functions that are dependent on the current execution state |
| (AArch32/AArch64), such as the functions used for TLB invalidation or MMU |
| setup. |
| |
| See `aarch32/xlat\_tables\_arch.c`_ and `aarch64/xlat\_tables\_arch.c`_. |
| |
| Core module |
| ~~~~~~~~~~~ |
| |
| From mmap regions to translation tables |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| All the APIs in this module work on a translation context. The translation |
| context contains the list of ``mmap_region``, which holds the information of all |
| the regions that are mapped at any given time. Whenever there is a request to |
| map (resp. unmap) a memory region, it is added to (resp. removed from) the |
| ``mmap_region`` list. |
| |
| The mmap regions list is a conceptual way to represent the memory layout. At |
| some point, the library has to convert this information into actual translation |
| tables to program into the MMU. |
| |
| Before the ``init_xlat_tables()`` API is called, the library only acts on the |
| mmap regions list. Adding a static or dynamic region at this point through one |
| of the ``mmap_add*()`` APIs does not affect the translation tables in any way, |
| they only get registered in the internal mmap region list. It is only when the |
| user calls the ``init_xlat_tables()`` that the translation tables are populated |
| in memory based on the list of mmap regions registered so far. This is an |
| optimization that allows creation of the initial set of translation tables in |
| one go, rather than having to edit them every time while the MMU is disabled. |
| |
| After the ``init_xlat_tables()`` API has been called, only dynamic regions can |
| be added. Changes to the translation tables (as well as the mmap regions list) |
| will take effect immediately. |
| |
| The memory mapping algorithm |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The mapping function is implemented as a recursive algorithm. It is however |
| bound by the level of depth of the translation tables (the Armv8-A architecture |
| allows up to 4 lookup levels). |
| |
| By default [#granularity-ref]_, the algorithm will attempt to minimize the |
| number of translation tables created to satisfy the user's request. It will |
| favour mapping a region using the biggest possible blocks, only creating a |
| sub-table if it is strictly necessary. This is to reduce the memory footprint of |
| the firmware. |
| |
| The most common reason for needing a sub-table is when a specific mapping |
| requires a finer granularity. Misaligned regions also require a finer |
| granularity than what the user may had originally expected, using a lot more |
| memory than expected. The reason is that all levels of translation are |
| restricted to address translations of the same granularity as the size of the |
| blocks of that level. For example, for a 4 KiB page size, a level 2 block entry |
| can only translate up to a granularity of 2 MiB. If the Physical Address is not |
| aligned to 2 MiB then additional level 3 tables are also needed. |
| |
| Note that not every translation level allows any type of descriptor. Depending |
| on the page size, levels 0 and 1 of translation may only allow table |
| descriptors. If a block entry could be able to describe a translation, but that |
| level does not allow block descriptors, a table descriptor will have to be used |
| instead, as well as additional tables at the next level. |
| |
| |Alignment Example| |
| |
| The mmap regions are sorted in a way that simplifies the code that maps |
| them. Even though this ordering is only strictly needed for overlapping static |
| regions, it must also be applied for dynamic regions to maintain a consistent |
| order of all regions at all times. As each new region is mapped, existing |
| entries in the translation tables are checked to ensure consistency. Please |
| refer to the comments in the source code of the core module for more details |
| about the sorting algorithm in use. |
| |
| .. [#granularity-ref] That is, when mmap regions do not enforce their mapping |
| granularity. |
| |
| TLB maintenance operations |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The library takes care of performing TLB maintenance operations when required. |
| For example, when the user requests removing a dynamic region, the library |
| invalidates all TLB entries associated to that region to ensure that these |
| changes are visible to subsequent execution, including speculative execution, |
| that uses the changed translation table entries. |
| |
| A counter-example is the initialization of translation tables. In this case, |
| explicit TLB maintenance is not required. The Armv8-A architecture guarantees |
| that all TLBs are disabled from reset and their contents have no effect on |
| address translation at reset [#tlb-reset-ref]_. Therefore, the TLBs invalidation |
| is deferred to the ``enable_mmu*()`` family of functions, just before the MMU is |
| turned on. |
| |
| TLB invalidation is not required when adding dynamic regions either. Dynamic |
| regions are not allowed to overlap existing memory region. Therefore, if the |
| dynamic mapping request is deemed legitimate, it automatically concerns memory |
| that was not mapped in this translation regime and the library will have |
| initialized its corresponding translation table entry to an invalid |
| descriptor. Given that the TLBs are not architecturally permitted to hold any |
| invalid translation table entry [#tlb-no-invalid-entry]_, this means that this |
| mapping cannot be cached in the TLBs. |
| |
| .. [#tlb-reset-ref] See section D4.8 `Translation Lookaside Buffers (TLBs)`, subsection `TLB behavior at reset` in Armv8-A, rev B.a. |
| |
| .. [#tlb-no-invalid-entry] See section D4.9.1 `General TLB maintenance requirements` in Armv8-A, rev B.a. |
| |
| Architectural module |
| ~~~~~~~~~~~~~~~~~~~~ |
| |
| This module contains functions that have different implementations for AArch32 |
| and AArch64. For example, it provides APIs to perform TLB maintenance operations, |
| enable the MMU or calculate the Physical Address Space size. They do not need a |
| translation context to work on. |
| |
| -------------- |
| |
| *Copyright (c) 2017-2018, Arm Limited and Contributors. All rights reserved.* |
| |
| .. _lib/xlat\_tables\_v2: ../lib/xlat_tables_v2 |
| .. _lib/xlat\_tables: ../lib/xlat_tables |
| .. _xlat\_tables\_v2.h: ../include/lib/xlat_tables/xlat_tables_v2.h |
| .. _xlat\_tables\_internal.c: ../lib/xlat_tables_v2/xlat_tables_internal.c |
| .. _aarch32/xlat\_tables\_arch.c: ../lib/xlat_tables_v2/aarch32/xlat_tables_arch.c |
| .. _aarch64/xlat\_tables\_arch.c: ../lib/xlat_tables_v2/aarch64/xlat_tables_arch.c |
| .. _Porting Guide: porting-guide.rst |
| .. |Alignment Example| image:: ./diagrams/xlat_align.png?raw=true |