docs/components/romlib-design.rst - filogic/atf - Gitiles

 Library at ROM
 ==============

 This document provides an overview of the "library at ROM" implementation in
 Trusted Firmware-A (TF-A).

 Introduction
 ~~~~~~~~~~~~

 The "library at ROM" feature allows platforms to build a library of functions to
 be placed in ROM. This reduces SRAM usage by utilising the available space in
 ROM. The "library at ROM" contains a jump table with the list of functions that
 are placed in ROM. The capabilities of the "library at ROM" are:

 1. Functions can be from one or several libraries.

 2. Functions can be patched after they have been programmed into ROM.

 3. Platform-specific libraries can be placed in ROM.

 4. Functions can be accessed by one or more BL images.

 Index file
 ~~~~~~~~~~

 .. image:: ../resources/diagrams/romlib_design.png
     :width: 600

 Library at ROM is described by an index file with the list of functions to be
 placed in ROM. The index file is platform specific and its format is:

 ::

     lib function    [patch]

     lib      -- Name of the library the function belongs to
     function -- Name of the function to be placed in library at ROM
     [patch]  -- Option to patch the function

 It is also possible to insert reserved spaces in the list by using the keyword
 "reserved" rather than the "lib" and "function" names as shown below:

 ::

     reserved

 The reserved spaces can be used to add more functions in the future without
 affecting the order and location of functions already existing in the jump
 table. Also, for additional flexibility and modularity, the index file can
 include other index files.

 For an index file example, refer to ``lib/romlib/jmptbl.i``.

 Wrapper functions
 ~~~~~~~~~~~~~~~~~

 .. image:: ../resources/diagrams/romlib_wrapper.png
     :width: 600

 When invoking a function of the "library at ROM", the calling sequence is as
 follows:

 BL image --> wrapper function --> jump table entry --> library at ROM

 The index file is used to create a jump table which is placed in ROM. Then, the
 wrappers refer to the jump table to call the "library at ROM" functions. The
 wrappers essentially contain a branch instruction to the jump table entry
 corresponding to the original function. Finally, the original function in the BL
 image(s) is replaced with the wrapper function.

 The "library at ROM" contains a necessary init function that initialises the
 global variables defined by the functions inside "library at ROM".

 Script
 ~~~~~~

 There is a ``romlib_generate.py`` Python script that generates the necessary
 files for the "library at ROM" to work. It implements multiple functions:

 1. ``romlib_generate.py gentbl [args]`` - Generates the jump table by parsing
    the index file.

 2. ``romlib_generator.py genvar [args]`` - Generates the jump table global
    variable (**not** the jump table itself) with the absolute address in ROM.
    This global variable is, basically, a pointer to the jump table.

 3. ``romlib_generator.py genwrappers [args]`` - Generates a wrapper function for
    each entry in the index file except for the ones that contain the keyword
    ``patch``. The generated wrapper file is called ``<fn_name>.s``.

 4. ``romlib_generator.py pre [args]`` - Preprocesses the index file which means
    it resolves all the include commands in the file recursively. It can also
    generate a dependency file of the included index files which can be directly
    used in makefiles.

 Each ``romlib_generate.py`` function has its own manual which is accessible by
 runing ``romlib_generator.py [function] --help``.

 ``romlib_generate.py`` requires Python 3 environment.


 Patching of functions in library at ROM
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 The ``romlib_generator.py genwrappers`` does not generate wrappers for the
 entries in the index file that contain the keyword ``patch``. Thus, it allows
 calling the function from the actual library by breaking the link to the
 "library at ROM" version of this function.

 The calling sequence for a patched function is as follows:

 BL image --> function

 Memory impact
 ~~~~~~~~~~~~~

 Using library at ROM will modify the memory layout of the BL images:

 - The ROM library needs a page aligned RAM section to hold the RW data. This
   section is defined by the ROMLIB_RW_BASE and ROMLIB_RW_END macros.
   On Arm platforms a section of 1 page (0x1000) is allocated at the top of SRAM.
   This will have for effect to shift down all the BL images by 1 page.

 - Depending on the functions moved to the ROM library, the size of the BL images
   will be reduced.
   For example: moving MbedTLS function into the ROM library reduces BL1 and
   BL2, but not BL31.

 - This change in BL images size can be taken into consideration to optimize the
   memory layout when defining the BLx_BASE macros.

 Build library at ROM
 ~~~~~~~~~~~~~~~~~~~~~

 The environment variable ``CROSS_COMPILE`` must be set appropriately. Refer to
 :ref:`Performing an Initial Build` for more information about setting this
 variable.

 In the below example the usage of ROMLIB together with mbed TLS is demonstrated
 to showcase the benefits of library at ROM - it's not mandatory.

 .. code:: shell

     make PLAT=fvp                                                   \
     MBEDTLS_DIR=</path/to/mbedtls/>                                 \
     TRUSTED_BOARD_BOOT=1 GENERATE_COT=1                             \
     ARM_ROTPK_LOCATION=devel_rsa                                    \
     ROT_KEY=plat/arm/board/common/rotpk/arm_rotprivk_rsa.pem        \
     BL33=</path/to/bl33.bin>                                        \
     USE_ROMLIB=1                                                    \
     all fip

 --------------

 *Copyright (c) 2019, Arm Limited. All rights reserved.*
	Library at ROM
	==============

	This document provides an overview of the "library at ROM" implementation in
	Trusted Firmware-A (TF-A).

	Introduction
	~~~~~~~~~~~~

	The "library at ROM" feature allows platforms to build a library of functions to
	be placed in ROM. This reduces SRAM usage by utilising the available space in
	ROM. The "library at ROM" contains a jump table with the list of functions that
	are placed in ROM. The capabilities of the "library at ROM" are:

	1. Functions can be from one or several libraries.

	2. Functions can be patched after they have been programmed into ROM.

	3. Platform-specific libraries can be placed in ROM.

	4. Functions can be accessed by one or more BL images.

	Index file
	~~~~~~~~~~

	.. image:: ../resources/diagrams/romlib_design.png
	:width: 600

	Library at ROM is described by an index file with the list of functions to be
	placed in ROM. The index file is platform specific and its format is:

	::

	lib function [patch]

	lib -- Name of the library the function belongs to
	function -- Name of the function to be placed in library at ROM
	[patch] -- Option to patch the function

	It is also possible to insert reserved spaces in the list by using the keyword
	"reserved" rather than the "lib" and "function" names as shown below:

	::

	reserved

	The reserved spaces can be used to add more functions in the future without
	affecting the order and location of functions already existing in the jump
	table. Also, for additional flexibility and modularity, the index file can
	include other index files.

	For an index file example, refer to ``lib/romlib/jmptbl.i``.

	Wrapper functions
	~~~~~~~~~~~~~~~~~

	.. image:: ../resources/diagrams/romlib_wrapper.png
	:width: 600

	When invoking a function of the "library at ROM", the calling sequence is as
	follows:

	BL image --> wrapper function --> jump table entry --> library at ROM

	The index file is used to create a jump table which is placed in ROM. Then, the
	wrappers refer to the jump table to call the "library at ROM" functions. The
	wrappers essentially contain a branch instruction to the jump table entry
	corresponding to the original function. Finally, the original function in the BL
	image(s) is replaced with the wrapper function.

	The "library at ROM" contains a necessary init function that initialises the
	global variables defined by the functions inside "library at ROM".

	Script
	~~~~~~

	There is a ``romlib_generate.py`` Python script that generates the necessary
	files for the "library at ROM" to work. It implements multiple functions:

	1. ``romlib_generate.py gentbl [args]`` - Generates the jump table by parsing
	the index file.

	2. ``romlib_generator.py genvar [args]`` - Generates the jump table global
	variable (not the jump table itself) with the absolute address in ROM.
	This global variable is, basically, a pointer to the jump table.

	3. ``romlib_generator.py genwrappers [args]`` - Generates a wrapper function for
	each entry in the index file except for the ones that contain the keyword
	``patch``. The generated wrapper file is called ``<fn_name>.s``.

	4. ``romlib_generator.py pre [args]`` - Preprocesses the index file which means
	it resolves all the include commands in the file recursively. It can also
	generate a dependency file of the included index files which can be directly
	used in makefiles.

	Each ``romlib_generate.py`` function has its own manual which is accessible by
	runing ``romlib_generator.py [function] --help``.

	``romlib_generate.py`` requires Python 3 environment.


	Patching of functions in library at ROM
	~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

	The ``romlib_generator.py genwrappers`` does not generate wrappers for the
	entries in the index file that contain the keyword ``patch``. Thus, it allows
	calling the function from the actual library by breaking the link to the
	"library at ROM" version of this function.

	The calling sequence for a patched function is as follows:

	BL image --> function

	Memory impact
	~~~~~~~~~~~~~

	Using library at ROM will modify the memory layout of the BL images:

	- The ROM library needs a page aligned RAM section to hold the RW data. This
	section is defined by the ROMLIB_RW_BASE and ROMLIB_RW_END macros.
	On Arm platforms a section of 1 page (0x1000) is allocated at the top of SRAM.
	This will have for effect to shift down all the BL images by 1 page.

	- Depending on the functions moved to the ROM library, the size of the BL images
	will be reduced.
	For example: moving MbedTLS function into the ROM library reduces BL1 and
	BL2, but not BL31.

	- This change in BL images size can be taken into consideration to optimize the
	memory layout when defining the BLx_BASE macros.

	Build library at ROM
	~~~~~~~~~~~~~~~~~~~~~

	The environment variable ``CROSS_COMPILE`` must be set appropriately. Refer to
	:ref:`Performing an Initial Build` for more information about setting this
	variable.

	In the below example the usage of ROMLIB together with mbed TLS is demonstrated
	to showcase the benefits of library at ROM - it's not mandatory.

	.. code:: shell

	make PLAT=fvp \
	MBEDTLS_DIR=</path/to/mbedtls/> \
	TRUSTED_BOARD_BOOT=1 GENERATE_COT=1 \
	ARM_ROTPK_LOCATION=devel_rsa \
	ROT_KEY=plat/arm/board/common/rotpk/arm_rotprivk_rsa.pem \
	BL33=</path/to/bl33.bin> \
	USE_ROMLIB=1 \
	all fip

	--------------

	Copyright (c) 2019, Arm Limited. All rights reserved.