530d68ba19
Signed-off-by: Peter Jones <pjones@redhat.com> Signed-off-by: Nigel Croxon <nigel.croxon@hp.com>
400 lines
17 KiB
Plaintext
400 lines
17 KiB
Plaintext
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Building EFI Applications Using the GNU Toolchain
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-------------------------------------------------
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David Mosberger <davidm@hpl.hp.com>
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23 September 1999
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Copyright (c) 1999-2007 Hewlett-Packard Co.
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Copyright (c) 2006-2010 Intel Co.
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Last update: 04/09/2007
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* Introduction
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This document has two parts: the first part describes how to develop
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EFI applications for IA-64,x86 and x86_64 using the GNU toolchain and the EFI
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development environment contained in this directory. The second part
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describes some of the more subtle aspects of how this development
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environment works.
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* Part 1: Developing EFI Applications
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** Prerequisites:
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To develop x86 and x86_64 EFI applications, the following tools are needed:
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- gcc-3.0 or newer (gcc 2.7.2 is NOT sufficient!)
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As of gnu-efi-3.0b, the Redhat 8.0 toolchain is known to work,
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but the Redhat 9.0 toolchain is not currently supported.
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- A version of "objcopy" that supports EFI applications. To
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check if your version includes EFI support, issue the
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command:
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objcopy --help
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Verify that the line "supported targets" contains the string
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"efi-app-ia32" and "efi-app-x86_64" and that the "-j" option
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accepts wildcards. The binutils release binutils-2.24
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supports Intel64 EFI and accepts wildcard section names.
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- For debugging purposes, it's useful to have a version of
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"objdump" that supports EFI applications as well. This
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allows inspect and disassemble EFI binaries.
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To develop IA-64 EFI applications, the following tools are needed:
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- A version of gcc newer than July 30th 1999 (older versions
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had problems with generating position independent code).
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As of gnu-efi-3.0b, gcc-3.1 is known to work well.
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- A version of "objcopy" that supports EFI applications. To
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check if your version includes EFI support, issue the
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command:
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objcopy --help
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Verify that the line "supported targets" contains the string
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"efi-app-ia64" and that the "-j" option accepts wildcards.
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- For debugging purposes, it's useful to have a version of
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"objdump" that supports EFI applications as well. This
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allows inspect and disassemble EFI binaries.
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** Directory Structure
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This EFI development environment contains the following
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subdirectories:
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inc: This directory contains the EFI-related include files. The
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files are taken from Intel's EFI source distribution, except
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that various fixes were applied to make it compile with the
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GNU toolchain.
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lib: This directory contains the source code for Intel's EFI library.
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Again, the files are taken from Intel's EFI source
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distribution, with changes to make them compile with the GNU
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toolchain.
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gnuefi: This directory contains the glue necessary to convert ELF64
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binaries to EFI binaries. Various runtime code bits, such as
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a self-relocator are included as well. This code has been
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contributed by the Hewlett-Packard Company and is distributed
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under the GNU GPL.
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apps: This directory contains a few simple EFI test apps.
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** Setup
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It is necessary to edit the Makefile in the directory containing this
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README file before EFI applications can be built. Specifically, you
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should verify that macros CC, AS, LD, AR, RANLIB, and OBJCOPY point to
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the appropriate compiler, assembler, linker, ar, and ranlib binaries,
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respectively.
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If you're working in a cross-development environment, be sure to set
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macro ARCH to the desired target architecture ("ia32" for x86, "x86_64" for
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x86_64 and "ia64" for IA-64). For convenience, this can also be done from
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the make command line (e.g., "make ARCH=ia64").
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** Building
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To build the sample EFI applications provided in subdirectory "apps",
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simply invoke "make" in the toplevel directory (the directory
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containing this README file). This should build lib/libefi.a and
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gnuefi/libgnuefi.a first and then all the EFI applications such as a
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apps/t6.efi.
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** Running
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Just copy the EFI application (e.g., apps/t6.efi) to the EFI
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filesystem, boot EFI, and then select "Invoke EFI application" to run
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the application you want to test. Alternatively, you can invoke the
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Intel-provided "nshell" application and then invoke your test binary
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via the command line interface that "nshell" provides.
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** Writing Your Own EFI Application
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Suppose you have your own EFI application in a file called
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"apps/myefiapp.c". To get this application built by the GNU EFI build
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environment, simply add "myefiapp.efi" to macro TARGETS in
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apps/Makefile. Once this is done, invoke "make" in the top level
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directory. This should result in EFI application apps/myefiapp.efi,
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ready for execution.
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The GNU EFI build environment allows to write EFI applications as
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described in Intel's EFI documentation, except for two differences:
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- The EFI application's entry point is always called "efi_main". The
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declaration of this routine is:
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EFI_STATUS efi_main (EFI_HANDLE image, EFI_SYSTEM_TABLE *systab);
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- UNICODE string literals must be written as W2U(L"Sample String")
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instead of just L"Sample String". The W2U() macro is defined in
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<efilib.h>. This header file also declares the function W2UCpy()
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which allows to convert a wide string into a UNICODE string and
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store the result in a programmer-supplied buffer.
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- Calls to EFI services should be made via uefi_call_wrapper(). This
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ensures appropriate parameter passing for the architecture.
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* Part 2: Inner Workings
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WARNING: This part contains all the gory detail of how the GNU EFI
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toolchain works. Normal users do not have to worry about such
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details. Reading this part incurs a definite risk of inducing severe
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headaches or other maladies.
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The basic idea behind the GNU EFI build environment is to use the GNU
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toolchain to build a normal ELF binary that, at the end, is converted
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to an EFI binary. EFI binaries are really just PE32+ binaries. PE
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stands for "Portable Executable" and is the object file format
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Microsoft is using on its Windows platforms. PE is basically the COFF
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object file format with an MS-DOS2.0 compatible header slapped on in
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front of it. The "32" in PE32+ stands for 32 bits, meaning that PE32
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is a 32-bit object file format. The plus in "PE32+" indicates that
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this format has been hacked to allow loading a 4GB binary anywhere in
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a 64-bit address space (unlike ELF64, however, this is not a full
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64-bit object file format because the entire binary cannot span more
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than 4GB of address space). EFI binaries are plain PE32+ binaries
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except that the "subsystem id" differs from normal Windows binaries.
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There are two flavors of EFI binaries: "applications" and "drivers"
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and each has there own subsystem id and are identical otherwise. At
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present, the GNU EFI build environment supports the building of EFI
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applications only, though it would be trivial to generate drivers, as
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the only difference is the subsystem id. For more details on PE32+,
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see the spec at
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http://msdn.microsoft.com/library/specs/msdn_pecoff.htm.
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In theory, converting a suitable ELF64 binary to PE32+ is easy and
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could be accomplished with the "objcopy" utility by specifying option
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--target=efi-app-ia32 (x86) or --target=efi-app-ia64 (IA-64). But
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life never is that easy, so here some complicating factors:
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(1) COFF sections are very different from ELF sections.
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ELF binaries distinguish between program headers and sections.
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The program headers describe the memory segments that need to
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be loaded/initialized, whereas the sections describe what
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constitutes those segments. In COFF (and therefore PE32+) no
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such distinction is made. Thus, COFF sections need to be page
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aligned and have a size that is a multiple of the page size
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(4KB for EFI), whereas ELF allows sections at arbitrary
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addresses and with arbitrary sizes.
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(2) EFI binaries should be relocatable.
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Since EFI binaries are executed in physical mode, EFI cannot
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guarantee that a given binary can be loaded at its preferred
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address. EFI does _try_ to load a binary at it's preferred
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address, but if it can't do so, it will load it at another
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address and then relocate the binary using the contents of the
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.reloc section.
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(3) On IA-64, the EFI entry point needs to point to a function
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descriptor, not to the code address of the entry point.
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(4) The EFI specification assumes that wide characters use UNICODE
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encoding.
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ANSI C does not specify the size or encoding that a wide
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character uses. These choices are "implementation defined".
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On most UNIX systems, the GNU toolchain uses a wchar_t that is
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4 bytes in size. The encoding used for such characters is
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(mostly) UCS4.
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In the following sections, we address how the GNU EFI build
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environment addresses each of these issues.
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** (1) Accommodating COFF Sections
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In order to satisfy the COFF constraint of page-sized and page-aligned
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sections, the GNU EFI build environment uses the special linker script
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in gnuefi/elf_$(ARCH)_efi.lds where $(ARCH) is the target architecture
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("ia32" for x86, "x86_64" for x86_64 and "ia64" for IA-64).
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This script is set up to create only eight COFF section, each page aligned
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and page sized.These eight sections are used to group together the much
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greater number of sections that are typically present in ELF object files.
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Specifically:
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.hash
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Collects the ELF .hash info (this section _must_ be the first
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section in order to build a shared object file; the section is
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not actually loaded or used at runtime).
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.text
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Collects all sections containing executable code.
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.data
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Collects read-only and read-write data, literal string data,
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global offset tables, the uninitialized data segment (bss) and
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various other sections containing data.
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The reason read-only data is placed here instead of the in
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.text is to make it possible to disassemble the .text section
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without getting garbage due to read-only data. Besides, since
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EFI binaries execute in physical mode, differences in page
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protection do not matter.
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The reason the uninitialized data is placed in this section is
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that the EFI loader appears to be unable to handle sections
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that are allocated but not loaded from the binary.
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.dynamic, .dynsym, .rela, .rel, .reloc
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These sections contains the dynamic information necessary to
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self-relocate the binary (see below).
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A couple of more points worth noting about the linker script:
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o On IA-64, the global pointer symbol (__gp) needs to be placed such
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that the _entire_ EFI binary can be addressed using the signed
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22-bit offset that the "addl" instruction affords. Specifically,
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this means that __gp should be placed at ImageBase + 0x200000.
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Strictly speaking, only a couple of symbols need to be addressable
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in this fashion, so with some care it should be possible to build
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binaries much larger than 4MB. To get a list of symbols that need
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to be addressable in this fashion, grep the assembly files in
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directory gnuefi for the string "@gprel".
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o The link address (ImageBase) of the binary is (arbitrarily) set to
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zero. This could be set to something larger to increase the chance
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of EFI being able to load the binary without requiring relocation.
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However, a start address of 0 makes debugging a wee bit easier
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(great for those of us who can add, but not subtract... ;-).
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o The relocation related sections (.dynamic, .rel, .rela, .reloc)
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cannot be placed inside .data because some tools in the GNU
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toolchain rely on the existence of these sections.
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o Some sections in the ELF binary intentionally get dropped when
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building the EFI binary. Particularly noteworthy are the dynamic
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relocation sections for the .plabel and .reloc sections. It would
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be _wrong_ to include these sections in the EFI binary because it
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would result in .reloc and .plabel being relocated twice (once by
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the EFI loader and once by the self-relocator; see below for a
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description of the latter). Specifically, only the sections
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mentioned with the -j option in the final "objcopy" command are
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retained in the EFI binary (see Make.rules).
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** (2) Building Relocatable Binaries
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ELF binaries are normally linked for a fixed load address and are thus
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not relocatable. The only kind of ELF object that is relocatable are
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shared objects ("shared libraries"). However, even those objects are
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usually not completely position independent and therefore require
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runtime relocation by the dynamic loader. For example, IA-64 binaries
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normally require relocation of the global offset table.
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The approach to building relocatable binaries in the GNU EFI build
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environment is to:
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(a) build an ELF shared object
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(b) link it together with a self-relocator that takes care of
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applying the dynamic relocations that may be present in the
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ELF shared object
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(c) convert the resulting image to an EFI binary
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The self-relocator is of course architecture dependent. The x86
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version can be found in gnuefi/reloc_ia32.c, the x86_64 version
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can be found in gnuefi/reloc_x86_64.c and the IA-64 version can be
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found in gnuefi/reloc_ia64.S.
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The self-relocator operates as follows: the startup code invokes it
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right after EFI has handed off control to the EFI binary at symbol
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"_start". Upon activation, the self-relocator searches the .dynamic
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section (whose starting address is given by symbol _DYNAMIC) for the
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dynamic relocation information, which can be found in the DT_REL,
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DT_RELSZ, and DT_RELENT entries of the dynamic table (DT_RELA,
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DT_RELASZ, and DT_RELAENT in the case of rela relocations, as is the
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case for IA-64). The dynamic relocation information points to the ELF
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relocation table. Once this table is found, the self-relocator walks
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through it, applying each relocation one by one. Since the EFI
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binaries are fully resolved shared objects, only a subset of all
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possible relocations need to be supported. Specifically, on x86 only
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the R_386_RELATIVE relocation is needed. On IA-64, the relocations
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R_IA64_DIR64LSB, R_IA64_REL64LSB, and R_IA64_FPTR64LSB are needed.
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Note that the R_IA64_FPTR64LSB relocation requires access to the
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dynamic symbol table. This is why the .dynsym section is included in
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the EFI binary. Another complication is that this relocation requires
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memory to hold the function descriptors (aka "procedure labels" or
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"plabels"). Each function descriptor uses 16 bytes of memory. The
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IA-64 self-relocator currently reserves a static memory area that can
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hold 100 of these descriptors. If the self-relocator runs out of
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space, it causes the EFI binary to fail with error code 5
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(EFI_BUFFER_TOO_SMALL). When this happens, the manifest constant
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MAX_FUNCTION_DESCRIPTORS in gnuefi/reloc_ia64.S should be increased
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and the application recompiled. An easy way to count the number of
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function descriptors required by an EFI application is to run the
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command:
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objdump --dynamic-reloc example.so | fgrep FPTR64 | wc -l
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assuming "example" is the name of the desired EFI application.
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** (3) Creating the Function Descriptor for the IA-64 EFI Binaries
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As mentioned above, the IA-64 PE32+ format assumes that the entry
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point of the binary is a function descriptor. A function descriptors
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consists of two double words: the first one is the code entry point
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and the second is the global pointer that should be loaded before
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calling the entry point. Since the ELF toolchain doesn't know how to
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generate a function descriptor for the entry point, the startup code
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in gnuefi/crt0-efi-ia64.S crafts one manually by with the code:
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.section .plabel, "a"
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_start_plabel:
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data8 _start
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data8 __gp
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this places the procedure label for entry point _start in a section
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called ".plabel". Now, the only problem is that _start and __gp need
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to be relocated _before_ EFI hands control over to the EFI binary.
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Fortunately, PE32+ defines a section called ".reloc" that can achieve
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this. Thus, in addition to manually crafting the function descriptor,
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the startup code also crafts a ".reloc" section that has will cause
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the EFI loader to relocate the function descriptor before handing over
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control to the EFI binary (again, see the PECOFF spec mentioned above
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for details).
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A final question may be why .plabel and .reloc need to go in their own
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COFF sections. The answer is simply: we need to be able to discard
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the relocation entries that are generated for these sections. By
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placing them in these sections, the relocations end up in sections
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".rela.plabel" and ".rela.reloc" which makes it easy to filter them
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out in the filter script. Also, the ".reloc" section needs to be in
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its own section so that the objcopy program can recognize it and can
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create the correct directory entries in the PE32+ binary.
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** (4) Convenient and Portable Generation of UNICODE String Literals
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As of gnu-efi-3.0, we make use (and somewhat abuse) the gcc option
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that forces wide characters (WCHAR_T) to use short integers (2 bytes)
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instead of integers (4 bytes). This way we match the Unicode character
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size. By abuse, we mean that we rely on the fact that the regular ASCII
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characters are encoded the same way between (short) wide characters
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and Unicode and basically only use the first byte. This allows us
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to just use them interchangeably.
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The gcc option to force short wide characters is : -fshort-wchar
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* * * The End * * *
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