doc/README.standalone - manifest_repos/bootloader - Git at Google

 Design Notes on Exporting U-Boot Functions to Standalone Applications:
 ======================================================================

 1. The functions are exported by U-Boot via a jump table. The jump
    table is allocated and initialized in the jumptable_init() routine
    (common/exports.c). Other routines may also modify the jump table,
    however. The jump table can be accessed as the 'jt' field of the
    'global_data' structure. The struct members for the jump table are
    defined in the <include/exports.h> header. E.g., to substitute the
    malloc() and free() functions that will be available to standalone
    applications, one should do the following:

 	DECLARE_GLOBAL_DATA_PTR;

 	gd->jt->malloc	= my_malloc;
 	gd->jt->free = my_free;

    Note that the pointers to the functions are real function pointers
    so the compiler can perform type checks on these assignments.

 2. The pointer to the jump table is passed to the application in a
    machine-dependent way. PowerPC, ARM, MIPS, Blackfin and Nios II
    architectures use a dedicated register to hold the pointer to the
    'global_data' structure: r2 on PowerPC, r9 on ARM, k0 on MIPS,
    P3 on Blackfin and gp on Nios II. The x86 architecture does not
    use such a register; instead, the pointer to the 'global_data'
    structure is passed as 'argv[-1]' pointer.

    The application can access the 'global_data' structure in the same
    way as U-Boot does:

 	DECLARE_GLOBAL_DATA_PTR;

 	printf("U-Boot relocation offset: %x\n", gd->reloc_off);

 3. The application should call the app_startup() function before any
    call to the exported functions. Also, implementor of the
    application may want to check the version of the ABI provided by
    U-Boot. To facilitate this, a get_version() function is exported
    that returns the ABI version of the running U-Boot. I.e., a
    typical application startup may look like this:

 	int my_app (int argc, char * const argv[])
 	{
 		app_startup (argv);
 		if (get_version () != XF_VERSION)
 			return 1;
 	}

 4. The default load and start addresses of the applications are as
    follows:

 			Load address	Start address
 	x86		0x00040000	0x00040000
 	PowerPC		0x00040000	0x00040004
 	ARM		0x0c100000	0x0c100000
 	MIPS		0x80200000	0x80200000
 	Blackfin	0x00001000	0x00001000
 	NDS32		0x00300000	0x00300000
 	Nios II		0x02000000	0x02000000

    For example, the "hello world" application may be loaded and
    executed on a PowerPC board with the following commands:

    => tftp 0x40000 hello_world.bin
    => go 0x40004

 5. To export some additional function long foobar(int i,char c), the following steps
    should be undertaken:

    - Append the following line at the end of the include/_exports.h
      file:

 	EXPORT_FUNC(foobar, long, foobar, int, char)

 	Parameters to EXPORT_FUNC:
 	 - the first parameter is the function that is exported (default implementation)
 	 - the second parameter is the return value type
 	 - the third  parameter is the name of the member in struct jt_funcs
 	   this is also the name that the standalone application will used.
 	   the rest of the parameters are the function arguments

    - Add the prototype for this function to the include/exports.h
      file:

 	long foobar(int i, char c);

 	Initialization with the default implementation is done in jumptable_init()

 	You can override the default implementation using:

 	gd->jt->foobar = another_foobar;

 	The signature of another_foobar must then match the declaration of foobar.

    - Increase the XF_VERSION value by one in the include/exports.h
      file

    - If you want to export a function which depends on a CONFIG_XXX
 	use 2 lines like this:
 	#ifdef CONFIG_FOOBAR
 		EXPORT_FUNC(foobar, long, foobar, int, char)
 	#else
 		EXPORT_FUNC(dummy, void, foobar, void)
 	#endif


 6. The code for exporting the U-Boot functions to applications is
    mostly machine-independent. The only places written in assembly
    language are stub functions that perform the jump through the jump
    table. That said, to port this code to a new architecture, the
    only thing to be provided is the code in the examples/stubs.c
    file. If this architecture, however, uses some uncommon method of
    passing the 'global_data' pointer (like x86 does), one should add
    the respective code to the app_startup() function in that file.

    Note that these functions may only use call-clobbered registers;
    those registers that are used to pass the function's arguments,
    the stack contents and the return address should be left intact.
	Design Notes on Exporting U-Boot Functions to Standalone Applications:
	======================================================================

	1. The functions are exported by U-Boot via a jump table. The jump
	table is allocated and initialized in the jumptable_init() routine
	(common/exports.c). Other routines may also modify the jump table,
	however. The jump table can be accessed as the 'jt' field of the
	'global_data' structure. The struct members for the jump table are
	defined in the <include/exports.h> header. E.g., to substitute the
	malloc() and free() functions that will be available to standalone
	applications, one should do the following:

	DECLARE_GLOBAL_DATA_PTR;

	gd->jt->malloc = my_malloc;
	gd->jt->free = my_free;

	Note that the pointers to the functions are real function pointers
	so the compiler can perform type checks on these assignments.

	2. The pointer to the jump table is passed to the application in a
	machine-dependent way. PowerPC, ARM, MIPS, Blackfin and Nios II
	architectures use a dedicated register to hold the pointer to the
	'global_data' structure: r2 on PowerPC, r9 on ARM, k0 on MIPS,
	P3 on Blackfin and gp on Nios II. The x86 architecture does not
	use such a register; instead, the pointer to the 'global_data'
	structure is passed as 'argv[-1]' pointer.

	The application can access the 'global_data' structure in the same
	way as U-Boot does:

	DECLARE_GLOBAL_DATA_PTR;

	printf("U-Boot relocation offset: %x\n", gd->reloc_off);

	3. The application should call the app_startup() function before any
	call to the exported functions. Also, implementor of the
	application may want to check the version of the ABI provided by
	U-Boot. To facilitate this, a get_version() function is exported
	that returns the ABI version of the running U-Boot. I.e., a
	typical application startup may look like this:

	int my_app (int argc, char * const argv[])
	{
	app_startup (argv);
	if (get_version () != XF_VERSION)
	return 1;
	}

	4. The default load and start addresses of the applications are as
	follows:

	Load address Start address
	x86 0x00040000 0x00040000
	PowerPC 0x00040000 0x00040004
	ARM 0x0c100000 0x0c100000
	MIPS 0x80200000 0x80200000
	Blackfin 0x00001000 0x00001000
	NDS32 0x00300000 0x00300000
	Nios II 0x02000000 0x02000000

	For example, the "hello world" application may be loaded and
	executed on a PowerPC board with the following commands:

	=> tftp 0x40000 hello_world.bin
	=> go 0x40004

	5. To export some additional function long foobar(int i,char c), the following steps
	should be undertaken:

	- Append the following line at the end of the include/_exports.h
	file:

	EXPORT_FUNC(foobar, long, foobar, int, char)

	Parameters to EXPORT_FUNC:
	- the first parameter is the function that is exported (default implementation)
	- the second parameter is the return value type
	- the third parameter is the name of the member in struct jt_funcs
	this is also the name that the standalone application will used.
	the rest of the parameters are the function arguments

	- Add the prototype for this function to the include/exports.h
	file:

	long foobar(int i, char c);

	Initialization with the default implementation is done in jumptable_init()

	You can override the default implementation using:

	gd->jt->foobar = another_foobar;

	The signature of another_foobar must then match the declaration of foobar.

	- Increase the XF_VERSION value by one in the include/exports.h
	file

	- If you want to export a function which depends on a CONFIG_XXX
	use 2 lines like this:
	#ifdef CONFIG_FOOBAR
	EXPORT_FUNC(foobar, long, foobar, int, char)
	#else
	EXPORT_FUNC(dummy, void, foobar, void)
	#endif


	6. The code for exporting the U-Boot functions to applications is
	mostly machine-independent. The only places written in assembly
	language are stub functions that perform the jump through the jump
	table. That said, to port this code to a new architecture, the
	only thing to be provided is the code in the examples/stubs.c
	file. If this architecture, however, uses some uncommon method of
	passing the 'global_data' pointer (like x86 does), one should add
	the respective code to the app_startup() function in that file.

	Note that these functions may only use call-clobbered registers;
	those registers that are used to pass the function's arguments,
	the stack contents and the return address should be left intact.