POSIX-UEFI

We hate that horrible and ugly UEFI API, we want POSIX!

This is a very small build environment that helps you to develop for UEFI under Linux (and other POSIX systems). It was greatly inspired by gnu-efi (big big kudos to those guys), but it is a lot smaller, easier to integrate (works with Clang and GNU gcc both) and easier to use because it provides a POSIX like API.

You have two options on how to integrate it into your project:

Distributing as Static Library

In the uefi directory, run

$ make

This will create build/uefi with all the necessary files in it. These are:

• crt0.o, the run-time that bootstraps POSIX-UEFI
• link.ld, the linker script you must use with POSIX-UEFI (same as with gnu-efi)
• libuefi.a, the library itself
• uefi.h, the all-in-one C / C++ header

You can use this and link your application with it, but you won't be able to recompile it, plus you're on your own with the linking and converting.

Strictly speaking you'll only need crt0.o and link.ld, that will get you started and will call your application's "main()", but to get libc functions like memcmp, strcpy, malloc or fopen, you'll have to link with libuefi.a.

Distributing as Source

This is the preferred way, as it also provides a Makefile to set up your toolchain properly.

1. simply copy the uefi directory into your source tree (or set up a git submodule). A dozen files, about 128K in total.
2. create an extremely simple Makefile like the one below
3. compile your code for UEFI by running make

TARGET = helloworld.efi

include uefi/Makefile

An example helloworld.c goes like this:

#include <uefi.h>

int main(int argc, wchar_t **argv)
{
    printf(L"Hello World!\n");
    return 0;
}

By default it uses the host native's GNU gcc + ld, creates a shared object and converts that into .efi file. If USE_LLVM is given, then LLVM CLang + lld used, and native PE is generated, no conversion involved.

Available Makefile Options

Variable	Description
TARGET	the target application (required)
SRCS	list of source files you want to compile (defaults to *.c *.S)
CFLAGS	compiler flags you want to use (empty by default, like "-Wall -pedantic -std=c99")
LDFLAGS	linker flags you want to use (I don't think you'll ever need this, just in case)
LIBS	additional libraries you want to link with (like "-lm", only static .a libraries allowed)
USE_LLVM	set this if you want LLVM Clang + Lld instead of GNU gcc + ld
ARCH	the target architecture

Here's a more advanced Makefile example:

ARCH = x86_64
TARGET = helloworld.efi
SRCS = $(wildcard *.c)
CFLAGS = -pedantic -Wall -Wextra -Werror --std=c11 -O2
LDFLAGS =
LIBS = -lm

USE_LLVM = 1
include uefi/Makefile

The build environment configurator was created in a way that it can handle any number of architectures, however there's only x86_64 crt0 implemented for now. There's an experimental aarch64 crt0, which only compiles with the LLVM toolchain, GNU ld has some issues with it, saying "unsupported relocation" for ImageBase.

Notable Differences to POSIX libc

This library is nowhere near as complete as glibc or musl for example. It only provides the very basic libc functions for you, because simplicity was one of its main goals. It is the best to say this is just wrapper around the UEFI API, rather than a POSIX compatible libc.

All strings in the UEFI environment are stored with 16 bits wide characters. The library provides wchar_t type for that, so for example your main() is NOT like main(int argc, char **argv), but main(int argc, wchar_t **argv) instead. All the other string related libc functions (like strlen() for example) use this wide character type too. For this reason, you must specify your string literals with L"" and characters with L''. Functions that supposed to handle characters in int type (like getchar, putchar), do not truncate to unsigned char, rather to wchar_t.

File types in dirent are limited to directories and files only (DT_DIR, DT_REG), but for stat in addition to S_IFDIR and S_IFREG, S_IFIFO also returned (for console streams: stdin, stdout, stderr).

Note that getenv and setenv aren't POSIX standard, because UEFI environment variables are binary blobs.

That's about it, everything else is the same.

List of Provided POSIX Functions

dirent.h

Function	Description
opendir	as usual, but accepts wide char strings
readdir	as usual
rewinddir	as usual
closedir	as usual

Because UEFI has no concept of device files nor of symlinks, dirent fields are limited and only DT_DIR and DT_REG supported.

stdlib.h

Function	Description
atoi	as usual, but accepts wide char strings and understands "0x" prefix
atol	as usual, but accepts wide char strings and understands "0x" prefix
strtol	as usual, but accepts wide char strings
malloc	as usual
calloc	as usual
realloc	as usual (needs testing)
free	as usual
abort	as usual
exit	as usual
mbtowc	as usual (UTF-8 char to wchar_t)
wctomb	as usual (wchar_t to UTF-8 char)
mbstowcs	as usual (UTF-8 string to wchar_t string)
wcstombs	as usual (wchar_t string to UTF-8 string)
srand	as usual
rand	as usual, but uses EFI_RNG_PROTOCOL if possible
getenv	pretty UEFI specific
setenv	pretty UEFI specific

uint8_t *getenv(wchar_t *name, uintn_t *len);

Query the value of environment variable name. On success, len is set, and a malloc'd buffer returned. It is the caller's responsibility to free the buffer later. On error returns NULL.

int setenv(wchar_t *name, uintn_t len, uint8_t *data);

Sets an environment variable by name with data of length len. On success returns 1, otherwise 0 on error.

stdio.h

Function	Description
fopen	as usual, but accepts wide char strings, also for mode
fclose	as usual
fflush	as usual
fread	as usual, only real files accepted (no stdin)
fwrite	as usual, only real files accepted (no stdout nor stderr)
fseek	as usual, only real files accepted (no stdin, stdout, stderr)
ftell	as usual, only real files accepted (no stdin, stdout, stderr)
feof	as usual, only real files accepted (no stdin, stdout, stderr)
fprintf	as usual, but accepts wide char strings, max BUFSIZ, files, stdout, stderr
printf	as usual, but accepts wide char strings, max BUFSIZ, stdout only
sprintf	as usual, but accepts wide char strings, max BUFSIZ
vfprintf	as usual, but accepts wide char strings, max BUFSIZ, files, stdout, stderr
vprintf	as usual, but accepts wide char strings, max BUFSIZ
vsprintf	as usual, but accepts wide char strings, max BUFSIZ
snprintf	as usual, but accepts wide char strings
vsnprintf	as usual, but accepts wide char strings
getchar	as usual, waits for a key, blocking, stdin only (no redirects)
getchar_ifany	non-blocking, returns 0 if there was no key press, UNICODE otherwise
putchar	as usual, stdout only (no redirects)
exit_bs	leave this entire UEFI bullshit behind (exit Boot Services)

int exit_bs()

Exit Boot Services. Returns 0 on success.

File open modes: L"r" read, L"w" write, L"a" append. Because of UEFI peculiarities, L"wd" creates directory.

String formating is limited; only supports padding via number prefixes, %d, %x, %X, %c, %s, %q and %p. Because it operates on wchar_t, it also supports the non-standard %C (printing an UTF-8 character, needs char*), %S (printing an UTF-8 string), %Q (printing an escaped UTF-8 string). These functions don't allocate memory, but in return the total length of the output string cannot be longer than BUFSIZ (8k if you haven't defined otherwise), except for the variants which have a maxlen argument. For convenience, %D requires efi_physical_address_t as argument, and it dumps memory, 16 bytes or one line at once. With the padding modifier you can dump more lines, for example %5D gives you 5 lines (80 dumped bytes).

Special "device files" you can open:

Name	Description
/dev/stdin	returns ST->ConIn
/dev/stdout	returns ST->ConOut, fprintf
/dev/stderr	returns ST->StdErr, fprintf
/dev/serial(baud)	returns Serial IO protocol, fread, fwrite, fprintf
/dev/disk(n)	returns Block IO protocol, fread, fwrite

With disk devices, fread and fwrite arguments look like this: fread(ptr, buffer size, lba number, stream).

string.h

Function	Description
memcpy	as usual, works on bytes
memmove	as usual, works on bytes
memset	as usual, works on bytes
memcmp	as usual, works on bytes
memchr	as usual, works on bytes
memrchr	as usual, works on bytes
memmem	as usual, works on bytes
memrmem	as usual, works on bytes
strcpy	works on wide char strings
strncpy	works on wide char strings
strcat	works on wide char strings
strncat	works on wide char strings
strcmp	works on wide char strings
strncmp	works on wide char strings
strdup	works on wide char strings
strchr	works on wide char strings
strrchr	works on wide char strings
strstr	works on wide char strings
strtok	works on wide char strings
strtok_r	works on wide char strings
strlen	works on wide char strings

sys/stat.h

Function	Description
stat	as usual, but accepts wide char strings
fstat	UEFI doesn't have fd, so it uses FILE*
mkdir	as usual, but accepts wide char strings, and mode unused

Because UEFI has no concept of device major and minor number nor of inodes, struct stat's fields are limited.

time.h

Function	Description
localtime	argument unused, always returns current time in struct tm
mktime	as usual
time	as usual

unistd.h

Function	Description
usleep	the usual
sleep	the usual
unlink	as usual, but accepts wide char strings
rmdir	as usual, but accepts wide char strings

Accessing UEFI Services

It is very likely that you want to call UEFI specific functions directly. For that, POSIX-UEFI specifies some globals in uefi.h:

Global Variable	Description
*BS	efi_boot_services_t, pointer to the Boot Time Services
*RT	efi_runtime_t, pointer to the Runtime Services
*ST	efi_system_table_t, pointer to the UEFI System Table
IM	efi_handle_t of your Loaded Image

The EFI structures, enums, typedefs and defines are all converted to ANSI C standard POSIX style, for example BOOLEAN -> boolean_t, UINTN -> uintn_t, EFI_MEMORY_DESCRIPTOR -> efi_memory_descriptor_t, and of course EFI_BOOT_SERVICES -> efi_boot_services_t.

Calling UEFI functions is as simple as with EDK II, just do the call, no need for "uefi_call_wrapper":

    ST->ConOut->OutputString(ST->ConOut, L"Hello World!\r\n");

There are two additional, non-POSIX calls in the library. One is exit_bs() to exit Boot Services, and the other is a non-blocking version getchar_ifany().

Unlike gnu-efi, POSIX-UEFI does not pollute your application's namespace with unused GUID variables. It only provides header definitions, so you must create each GUID instance if and when you need them.

Example:

efi_guid_t gopGuid = EFI_GRAPHICS_OUTPUT_PROTOCOL_GUID;
efi_gop_t *gop = NULL;

status = BS->LocateProtocol(&gopGuid, NULL, (void**)&gop);

Also unlike gnu-efi, POSIX-UEFI does not provide standard EFI headers. It expects that you have installed those under /usr/include/efi from EDK II or gnu-efi, and POSIX-UEFI makes it possible to use those system wide headers without naming conflicts. POSIX-UEFI itself ships the very minimum set of typedefs and structs (with POSIX-ized names).

#include <efi.h>
#include <uefi.h> /* this will work as expected! Both POSIX-UEFI and EDK II / gnu-efi typedefs available */

The advantage of this is that you can use the simplicity of the POSIX-UEFI library and build environment, while getting access to the most up-to-date protocol and interface definitions at the same time.

License

POSIX_UEFI is licensed under the terms of the MIT license.

Cheers,

bzt