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| ChangeLog | 21-Aug-2018 | 25.2K | |
| debian/ | 21-Aug-2018 | ||
| gnuefi/ | 21-Aug-2018 | ||
| inc/ | 21-Aug-2018 | ||
| lib/ | 21-Aug-2018 | ||
| Make.defaults | 21-Aug-2018 | 3.9K | |
| Make.rules | 21-Aug-2018 | 2.1K | |
| Makefile | 21-Aug-2018 | 3K | |
| README.efilib | 21-Aug-2018 | 1.5K | |
| README.elilo | 21-Aug-2018 | 639 | |
| README.gnuefi | 21-Aug-2018 | 16.8K | |
README.efilib
1 2 The files in the "lib" and "inc" subdirectories are using the EFI Application 3 Toolkit distributed by Intel at http://developer.intel.com/technology/efi 4 5 This code is covered by the following agreement: 6 7 Copyright (c) 1998-2000 Intel Corporation 8 9 Redistribution and use in source and binary forms, with or without modification, are permitted 10 provided that the following conditions are met: 11 12 Redistributions of source code must retain the above copyright notice, this list of conditions and 13 the following disclaimer. 14 15 Redistributions in binary form must reproduce the above copyright notice, this list of conditions 16 and the following disclaimer in the documentation and/or other materials provided with the 17 distribution. 18 19 THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, 20 INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND 21 FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL INTEL BE 22 LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 23 CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 24 SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 25 INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 26 CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 27 ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 28 POSSIBILITY OF SUCH DAMAGE. THE EFI SPECIFICATION AND ALL OTHER INFORMATION 29 ON THIS WEB SITE ARE PROVIDED "AS IS" WITH NO WARRANTIES, AND ARE SUBJECT 30 TO CHANGE WITHOUT NOTICE. 31
README.elilo
1 2 IMPORTANT information related to the gnu-efi package 3 ---------------------------------------------------- 4 June 2001 5 6 As of version 3.0, the gnu-efi package is now split in two different packages: 7 8 -> gnu-efi-X.y: contains the EFI library, include files and crt0. 9 10 -> elilo-X.y : contains the ELILO bootloader. 11 12 Note that X.y don't need to match for both packages. However elilo-3.x 13 requires at least gnu-efi-3.0. EFI support for x86_64 is provided in 14 gnu-efi-3.0d. 15 16 Both packages can be downloaded from: 17 18 http://www.sf.net/projects/gnu-efi 19 http://www.sf.net/projects/elilo 20
README.gnuefi
1 ------------------------------------------------- 2 Building EFI Applications Using the GNU Toolchain 3 ------------------------------------------------- 4 5 David Mosberger <davidm (a] hpl.hp.com> 6 7 23 September 1999 8 9 10 Copyright (c) 1999-2007 Hewlett-Packard Co. 11 Copyright (c) 2006-2010 Intel Co. 12 13 Last update: 04/09/2007 14 15 * Introduction 16 17 This document has two parts: the first part describes how to develop 18 EFI applications for IA-64,x86 and x86_64 using the GNU toolchain and the EFI 19 development environment contained in this directory. The second part 20 describes some of the more subtle aspects of how this development 21 environment works. 22 23 24 25 * Part 1: Developing EFI Applications 26 27 28 ** Prerequisites: 29 30 To develop x86 and x86_64 EFI applications, the following tools are needed: 31 32 - gcc-3.0 or newer (gcc 2.7.2 is NOT sufficient!) 33 As of gnu-efi-3.0b, the Redhat 8.0 toolchain is known to work, 34 but the Redhat 9.0 toolchain is not currently supported. 35 36 - A version of "objcopy" that supports EFI applications. To 37 check if your version includes EFI support, issue the 38 command: 39 40 objcopy --help 41 42 and verify that the line "supported targets" contains the 43 string "efi-app-ia32" and "efi-app-x86_64". The binutils release 44 binutils-2.17.50.0.14 supports Intel64 EFI. 45 46 - For debugging purposes, it's useful to have a version of 47 "objdump" that supports EFI applications as well. This 48 allows inspect and disassemble EFI binaries. 49 50 To develop IA-64 EFI applications, the following tools are needed: 51 52 - A version of gcc newer than July 30th 1999 (older versions 53 had problems with generating position independent code). 54 As of gnu-efi-3.0b, gcc-3.1 is known to work well. 55 56 - A version of "objcopy" that supports EFI applications. To 57 check if your version includes EFI support, issue the 58 command: 59 60 objcopy --help 61 62 and verify that the line "supported targets" contains the 63 string "efi-app-ia64". 64 65 - For debugging purposes, it's useful to have a version of 66 "objdump" that supports EFI applications as well. This 67 allows inspect and disassemble EFI binaries. 68 69 70 ** Directory Structure 71 72 This EFI development environment contains the following 73 subdirectories: 74 75 inc: This directory contains the EFI-related include files. The 76 files are taken from Intel's EFI source distribution, except 77 that various fixes were applied to make it compile with the 78 GNU toolchain. 79 80 lib: This directory contains the source code for Intel's EFI library. 81 Again, the files are taken from Intel's EFI source 82 distribution, with changes to make them compile with the GNU 83 toolchain. 84 85 gnuefi: This directory contains the glue necessary to convert ELF64 86 binaries to EFI binaries. Various runtime code bits, such as 87 a self-relocator are included as well. This code has been 88 contributed by the Hewlett-Packard Company and is distributed 89 under the GNU GPL. 90 91 apps: This directory contains a few simple EFI test apps. 92 93 ** Setup 94 95 It is necessary to edit the Makefile in the directory containing this 96 README file before EFI applications can be built. Specifically, you 97 should verify that macros CC, AS, LD, AR, RANLIB, and OBJCOPY point to 98 the appropriate compiler, assembler, linker, ar, and ranlib binaries, 99 respectively. 100 101 If you're working in a cross-development environment, be sure to set 102 macro ARCH to the desired target architecture ("ia32" for x86, "x86_64" for 103 x86_64 and "ia64" for IA-64). For convenience, this can also be done from 104 the make command line (e.g., "make ARCH=ia64"). 105 106 107 ** Building 108 109 To build the sample EFI applications provided in subdirectory "apps", 110 simply invoke "make" in the toplevel directory (the directory 111 containing this README file). This should build lib/libefi.a and 112 gnuefi/libgnuefi.a first and then all the EFI applications such as a 113 apps/t6.efi. 114 115 116 ** Running 117 118 Just copy the EFI application (e.g., apps/t6.efi) to the EFI 119 filesystem, boot EFI, and then select "Invoke EFI application" to run 120 the application you want to test. Alternatively, you can invoke the 121 Intel-provided "nshell" application and then invoke your test binary 122 via the command line interface that "nshell" provides. 123 124 125 ** Writing Your Own EFI Application 126 127 Suppose you have your own EFI application in a file called 128 "apps/myefiapp.c". To get this application built by the GNU EFI build 129 environment, simply add "myefiapp.efi" to macro TARGETS in 130 apps/Makefile. Once this is done, invoke "make" in the top level 131 directory. This should result in EFI application apps/myefiapp.efi, 132 ready for execution. 133 134 The GNU EFI build environment allows to write EFI applications as 135 described in Intel's EFI documentation, except for two differences: 136 137 - The EFI application's entry point is always called "efi_main". The 138 declaration of this routine is: 139 140 EFI_STATUS efi_main (EFI_HANDLE image, EFI_SYSTEM_TABLE *systab); 141 142 - UNICODE string literals must be written as W2U(L"Sample String") 143 instead of just L"Sample String". The W2U() macro is defined in 144 <efilib.h>. This header file also declares the function W2UCpy() 145 which allows to convert a wide string into a UNICODE string and 146 store the result in a programmer-supplied buffer. 147 148 - Calls to EFI services should be made via uefi_call_wrapper(). This 149 ensures appropriate parameter passing for the architecture. 150 151 152 * Part 2: Inner Workings 153 154 WARNING: This part contains all the gory detail of how the GNU EFI 155 toolchain works. Normal users do not have to worry about such 156 details. Reading this part incurs a definite risk of inducing severe 157 headaches or other maladies. 158 159 The basic idea behind the GNU EFI build environment is to use the GNU 160 toolchain to build a normal ELF binary that, at the end, is converted 161 to an EFI binary. EFI binaries are really just PE32+ binaries. PE 162 stands for "Portable Executable" and is the object file format 163 Microsoft is using on its Windows platforms. PE is basically the COFF 164 object file format with an MS-DOS2.0 compatible header slapped on in 165 front of it. The "32" in PE32+ stands for 32 bits, meaning that PE32 166 is a 32-bit object file format. The plus in "PE32+" indicates that 167 this format has been hacked to allow loading a 4GB binary anywhere in 168 a 64-bit address space (unlike ELF64, however, this is not a full 169 64-bit object file format because the entire binary cannot span more 170 than 4GB of address space). EFI binaries are plain PE32+ binaries 171 except that the "subsystem id" differs from normal Windows binaries. 172 There are two flavors of EFI binaries: "applications" and "drivers" 173 and each has there own subsystem id and are identical otherwise. At 174 present, the GNU EFI build environment supports the building of EFI 175 applications only, though it would be trivial to generate drivers, as 176 the only difference is the subsystem id. For more details on PE32+, 177 see the spec at 178 179 http://msdn.microsoft.com/library/specs/msdn_pecoff.htm. 180 181 In theory, converting a suitable ELF64 binary to PE32+ is easy and 182 could be accomplished with the "objcopy" utility by specifying option 183 --target=efi-app-ia32 (x86) or --target=efi-app-ia64 (IA-64). But 184 life never is that easy, so here some complicating factors: 185 186 (1) COFF sections are very different from ELF sections. 187 188 ELF binaries distinguish between program headers and sections. 189 The program headers describe the memory segments that need to 190 be loaded/initialized, whereas the sections describe what 191 constitutes those segments. In COFF (and therefore PE32+) no 192 such distinction is made. Thus, COFF sections need to be page 193 aligned and have a size that is a multiple of the page size 194 (4KB for EFI), whereas ELF allows sections at arbitrary 195 addresses and with arbitrary sizes. 196 197 (2) EFI binaries should be relocatable. 198 199 Since EFI binaries are executed in physical mode, EFI cannot 200 guarantee that a given binary can be loaded at its preferred 201 address. EFI does _try_ to load a binary at it's preferred 202 address, but if it can't do so, it will load it at another 203 address and then relocate the binary using the contents of the 204 .reloc section. 205 206 (3) On IA-64, the EFI entry point needs to point to a function 207 descriptor, not to the code address of the entry point. 208 209 (4) The EFI specification assumes that wide characters use UNICODE 210 encoding. 211 212 ANSI C does not specify the size or encoding that a wide 213 character uses. These choices are "implementation defined". 214 On most UNIX systems, the GNU toolchain uses a wchar_t that is 215 4 bytes in size. The encoding used for such characters is 216 (mostly) UCS4. 217 218 In the following sections, we address how the GNU EFI build 219 environment addresses each of these issues. 220 221 222 ** (1) Accommodating COFF Sections 223 224 In order to satisfy the COFF constraint of page-sized and page-aligned 225 sections, the GNU EFI build environment uses the special linker script 226 in gnuefi/elf_$(ARCH)_efi.lds where $(ARCH) is the target architecture 227 ("ia32" for x86, "x86_64" for x86_64 and "ia64" for IA-64). 228 This script is set up to create only eight COFF section, each page aligned 229 and page sized.These eight sections are used to group together the much 230 greater number of sections that are typically present in ELF object files. 231 Specifically: 232 233 .hash 234 Collects the ELF .hash info (this section _must_ be the first 235 section in order to build a shared object file; the section is 236 not actually loaded or used at runtime). 237 238 .text 239 Collects all sections containing executable code. 240 241 .data 242 Collects read-only and read-write data, literal string data, 243 global offset tables, the uninitialized data segment (bss) and 244 various other sections containing data. 245 246 The reason read-only data is placed here instead of the in 247 .text is to make it possible to disassemble the .text section 248 without getting garbage due to read-only data. Besides, since 249 EFI binaries execute in physical mode, differences in page 250 protection do not matter. 251 252 The reason the uninitialized data is placed in this section is 253 that the EFI loader appears to be unable to handle sections 254 that are allocated but not loaded from the binary. 255 256 .dynamic, .dynsym, .rela, .rel, .reloc 257 These sections contains the dynamic information necessary to 258 self-relocate the binary (see below). 259 260 A couple of more points worth noting about the linker script: 261 262 o On IA-64, the global pointer symbol (__gp) needs to be placed such 263 that the _entire_ EFI binary can be addressed using the signed 264 22-bit offset that the "addl" instruction affords. Specifically, 265 this means that __gp should be placed at ImageBase + 0x200000. 266 Strictly speaking, only a couple of symbols need to be addressable 267 in this fashion, so with some care it should be possible to build 268 binaries much larger than 4MB. To get a list of symbols that need 269 to be addressable in this fashion, grep the assembly files in 270 directory gnuefi for the string "@gprel". 271 272 o The link address (ImageBase) of the binary is (arbitrarily) set to 273 zero. This could be set to something larger to increase the chance 274 of EFI being able to load the binary without requiring relocation. 275 However, a start address of 0 makes debugging a wee bit easier 276 (great for those of us who can add, but not subtract... ;-). 277 278 o The relocation related sections (.dynamic, .rel, .rela, .reloc) 279 cannot be placed inside .data because some tools in the GNU 280 toolchain rely on the existence of these sections. 281 282 o Some sections in the ELF binary intentionally get dropped when 283 building the EFI binary. Particularly noteworthy are the dynamic 284 relocation sections for the .plabel and .reloc sections. It would 285 be _wrong_ to include these sections in the EFI binary because it 286 would result in .reloc and .plabel being relocated twice (once by 287 the EFI loader and once by the self-relocator; see below for a 288 description of the latter). Specifically, only the sections 289 mentioned with the -j option in the final "objcopy" command are 290 retained in the EFI binary (see apps/Makefile). 291 292 293 ** (2) Building Relocatable Binaries 294 295 ELF binaries are normally linked for a fixed load address and are thus 296 not relocatable. The only kind of ELF object that is relocatable are 297 shared objects ("shared libraries"). However, even those objects are 298 usually not completely position independent and therefore require 299 runtime relocation by the dynamic loader. For example, IA-64 binaries 300 normally require relocation of the global offset table. 301 302 The approach to building relocatable binaries in the GNU EFI build 303 environment is to: 304 305 (a) build an ELF shared object 306 307 (b) link it together with a self-relocator that takes care of 308 applying the dynamic relocations that may be present in the 309 ELF shared object 310 311 (c) convert the resulting image to an EFI binary 312 313 The self-relocator is of course architecture dependent. The x86 314 version can be found in gnuefi/reloc_ia32.c, the x86_64 version 315 can be found in gnuefi/reloc_x86_64.c and the IA-64 version can be 316 found in gnuefi/reloc_ia64.S. 317 318 The self-relocator operates as follows: the startup code invokes it 319 right after EFI has handed off control to the EFI binary at symbol 320 "_start". Upon activation, the self-relocator searches the .dynamic 321 section (whose starting address is given by symbol _DYNAMIC) for the 322 dynamic relocation information, which can be found in the DT_REL, 323 DT_RELSZ, and DT_RELENT entries of the dynamic table (DT_RELA, 324 DT_RELASZ, and DT_RELAENT in the case of rela relocations, as is the 325 case for IA-64). The dynamic relocation information points to the ELF 326 relocation table. Once this table is found, the self-relocator walks 327 through it, applying each relocation one by one. Since the EFI 328 binaries are fully resolved shared objects, only a subset of all 329 possible relocations need to be supported. Specifically, on x86 only 330 the R_386_RELATIVE relocation is needed. On IA-64, the relocations 331 R_IA64_DIR64LSB, R_IA64_REL64LSB, and R_IA64_FPTR64LSB are needed. 332 Note that the R_IA64_FPTR64LSB relocation requires access to the 333 dynamic symbol table. This is why the .dynsym section is included in 334 the EFI binary. Another complication is that this relocation requires 335 memory to hold the function descriptors (aka "procedure labels" or 336 "plabels"). Each function descriptor uses 16 bytes of memory. The 337 IA-64 self-relocator currently reserves a static memory area that can 338 hold 100 of these descriptors. If the self-relocator runs out of 339 space, it causes the EFI binary to fail with error code 5 340 (EFI_BUFFER_TOO_SMALL). When this happens, the manifest constant 341 MAX_FUNCTION_DESCRIPTORS in gnuefi/reloc_ia64.S should be increased 342 and the application recompiled. An easy way to count the number of 343 function descriptors required by an EFI application is to run the 344 command: 345 346 objdump --dynamic-reloc example.so | fgrep FPTR64 | wc -l 347 348 assuming "example" is the name of the desired EFI application. 349 350 351 ** (3) Creating the Function Descriptor for the IA-64 EFI Binaries 352 353 As mentioned above, the IA-64 PE32+ format assumes that the entry 354 point of the binary is a function descriptor. A function descriptors 355 consists of two double words: the first one is the code entry point 356 and the second is the global pointer that should be loaded before 357 calling the entry point. Since the ELF toolchain doesn't know how to 358 generate a function descriptor for the entry point, the startup code 359 in gnuefi/crt0-efi-ia64.S crafts one manually by with the code: 360 361 .section .plabel, "a" 362 _start_plabel: 363 data8 _start 364 data8 __gp 365 366 this places the procedure label for entry point _start in a section 367 called ".plabel". Now, the only problem is that _start and __gp need 368 to be relocated _before_ EFI hands control over to the EFI binary. 369 Fortunately, PE32+ defines a section called ".reloc" that can achieve 370 this. Thus, in addition to manually crafting the function descriptor, 371 the startup code also crafts a ".reloc" section that has will cause 372 the EFI loader to relocate the function descriptor before handing over 373 control to the EFI binary (again, see the PECOFF spec mentioned above 374 for details). 375 376 A final question may be why .plabel and .reloc need to go in their own 377 COFF sections. The answer is simply: we need to be able to discard 378 the relocation entries that are generated for these sections. By 379 placing them in these sections, the relocations end up in sections 380 ".rela.plabel" and ".rela.reloc" which makes it easy to filter them 381 out in the filter script. Also, the ".reloc" section needs to be in 382 its own section so that the objcopy program can recognize it and can 383 create the correct directory entries in the PE32+ binary. 384 385 386 ** (4) Convenient and Portable Generation of UNICODE String Literals 387 388 As of gnu-efi-3.0, we make use (and somewhat abuse) the gcc option 389 that forces wide characters (WCHAR_T) to use short integers (2 bytes) 390 instead of integers (4 bytes). This way we match the Unicode character 391 size. By abuse, we mean that we rely on the fact that the regular ASCII 392 characters are encoded the same way between (short) wide characters 393 and Unicode and basically only use the first byte. This allows us 394 to just use them interchangeably. 395 396 The gcc option to force short wide characters is : -fshort-wchar 397 398 * * * The End * * * 399
