doc/README.arm-unaligned-accesses - github/trini/u-boot - Gitiles

 If you are reading this because of a data abort: the following MIGHT
 be relevant to your abort, if it was caused by an alignment violation.
 In order to determine this, use the PC from the abort dump along with
 an objdump -s -S of the u-boot ELF binary to locate the function where
 the abort happened; then compare this function with the examples below.
 If they match, then you've been hit with a compiler generated unaligned
 access, and you should rewrite your code or add -mno-unaligned-access
 to the command line of the offending file.

 Note that the PC shown in the abort message is relocated. In order to
 be able to match it to an address in the ELF binary dump, you will need
 to know the relocation offset. If your target defines CONFIG_CMD_BDI
 and if you can get to the prompt and enter commands before the abort
 happens, then command "bdinfo" will give you the offset. Otherwise you
 will need to try a build with DEBUG set, which will display the offset,
 or use a debugger and set a breakpoint at relocate_code() to see the
 offset (passed as an argument).

 *

 Since U-Boot runs on a variety of hardware, some only able to perform
 unaligned accesses with a strong penalty, some unable to perform them
 at all, the policy regarding unaligned accesses is to not perform any,
 unless absolutely necessary because of hardware or standards.

 Also, on hardware which permits it, the core is configured to throw
 data abort exceptions on unaligned accesses in order to catch these
 unallowed accesses as early as possible.

 Until version 4.7, the gcc default for performing unaligned accesses
 (-mno-unaligned-access) is to emulate unaligned accesses using aligned
 loads and stores plus shifts and masks. Emulated unaligned accesses
 will not be caught by hardware. These accesses may be costly and may
 be actually unnecessary. In order to catch these accesses and remove
 or optimize them, option -munaligned-access is explicitly set for all
 versions of gcc which support it.

 From gcc 4.7 onward starting at armv7 architectures, the default for
 performing unaligned accesses is to use unaligned native loads and
 stores (-munaligned-access), because the cost of unaligned accesses
 has dropped on armv7 and beyond. This should not affect U-Boot's
 policy of controlling unaligned accesses, however the compiler may
 generate uncontrolled unaligned accesses on its own in at least one
 known case: when declaring a local initialized char array, e.g.

 function foo()
 {
 	char buffer[] = "initial value";
 /* or */
 	char buffer[] = { 'i', 'n', 'i', 't', 0 };
 	...
 }

 Under -munaligned-accesses with optimizations on, this declaration
 causes the compiler to generate native loads from the literal string
 and native stores to the buffer, and the literal string alignment
 cannot be controlled. If it is misaligned, then the core will throw
 a data abort exception.

 Quite probably the same might happen for 16-bit array initializations
 where the constant is aligned on a boundary which is a multiple of 2
 but not of 4:

 function foo()
 {
 	u16 buffer[] = { 1, 2, 3 };
 	...
 }

 The long term solution to this issue is to add an option to gcc to
 allow controlling the general alignment of data, including constant
 initialization values.

 However this will only apply to the version of gcc which will have such
 an option. For other versions, there are four workarounds:

 a) Enforce as a rule that array initializations as described above
    are forbidden. This is generally not acceptable as they are valid,
    and usual, C constructs. The only case where they could be rejected
    is when they actually equate to a const char* declaration, i.e. the
    array is initialized and never modified in the function's scope.

 b) Drop the requirement on unaligned accesses at least for ARMv7,
    i.e. do not throw a data abort exception upon unaligned accesses.
    But that will allow adding badly aligned code to U-Boot, only for
    it to fail when re-used with a stricter target, possibly once the
    bad code is already in mainline.

 c) Relax the -munaligned-access rule globally. This will prevent native
    unaligned accesses of course, but that will also hide any bug caused
    by a bad unaligned access, making it much harder to diagnose it. It
    is actually what already happens when building ARM targets with a
    pre-4.7 gcc, and it may actually already hide some bugs yet unseen
    until the target gets compiled with -munaligned-access.

 d) Relax the -munaligned-access rule only for for files susceptible to
    the local initialized array issue and for armv7 architectures and
    beyond. This minimizes the quantity of code which can hide unwanted
    misaligned accesses.

 The option retained is d).

 Considering that actual occurrences of the issue are rare (as of this
 writing, 5 files out of 7840 in U-Boot, or .3%, contain an initialized
 local char array which cannot actually be replaced with a const char*),
 contributors should not be required to systematically try and detect
 the issue in their patches.

 Detecting files susceptible to the issue can be automated through a
 filter installed as a hook in .git which recognizes local char array
 initializations. Automation should err on the false positive side, for
 instance flagging non-local arrays as if they were local if they cannot
 be told apart.

 In any case, detection shall not prevent committing the patch, but
 shall pre-populate the commit message with a note to the effect that
 this patch contains an initialized local char or 16-bit array and thus
 should be protected from the gcc 4.7 issue.

 Upon a positive detection, either $(PLATFORM_NO_UNALIGNED) should be
 added to CFLAGS for the affected file(s), or if the array is a pseudo
 const char*, it should be replaced by an actual one.
	If you are reading this because of a data abort: the following MIGHT
	be relevant to your abort, if it was caused by an alignment violation.
	In order to determine this, use the PC from the abort dump along with
	an objdump -s -S of the u-boot ELF binary to locate the function where
	the abort happened; then compare this function with the examples below.
	If they match, then you've been hit with a compiler generated unaligned
	access, and you should rewrite your code or add -mno-unaligned-access
	to the command line of the offending file.

	Note that the PC shown in the abort message is relocated. In order to
	be able to match it to an address in the ELF binary dump, you will need
	to know the relocation offset. If your target defines CONFIG_CMD_BDI
	and if you can get to the prompt and enter commands before the abort
	happens, then command "bdinfo" will give you the offset. Otherwise you
	will need to try a build with DEBUG set, which will display the offset,
	or use a debugger and set a breakpoint at relocate_code() to see the
	offset (passed as an argument).

	*

	Since U-Boot runs on a variety of hardware, some only able to perform
	unaligned accesses with a strong penalty, some unable to perform them
	at all, the policy regarding unaligned accesses is to not perform any,
	unless absolutely necessary because of hardware or standards.

	Also, on hardware which permits it, the core is configured to throw
	data abort exceptions on unaligned accesses in order to catch these
	unallowed accesses as early as possible.

	Until version 4.7, the gcc default for performing unaligned accesses
	(-mno-unaligned-access) is to emulate unaligned accesses using aligned
	loads and stores plus shifts and masks. Emulated unaligned accesses
	will not be caught by hardware. These accesses may be costly and may
	be actually unnecessary. In order to catch these accesses and remove
	or optimize them, option -munaligned-access is explicitly set for all
	versions of gcc which support it.

	From gcc 4.7 onward starting at armv7 architectures, the default for
	performing unaligned accesses is to use unaligned native loads and
	stores (-munaligned-access), because the cost of unaligned accesses
	has dropped on armv7 and beyond. This should not affect U-Boot's
	policy of controlling unaligned accesses, however the compiler may
	generate uncontrolled unaligned accesses on its own in at least one
	known case: when declaring a local initialized char array, e.g.

	function foo()
	{
	char buffer[] = "initial value";
	/* or */
	char buffer[] = { 'i', 'n', 'i', 't', 0 };
	...
	}

	Under -munaligned-accesses with optimizations on, this declaration
	causes the compiler to generate native loads from the literal string
	and native stores to the buffer, and the literal string alignment
	cannot be controlled. If it is misaligned, then the core will throw
	a data abort exception.

	Quite probably the same might happen for 16-bit array initializations
	where the constant is aligned on a boundary which is a multiple of 2
	but not of 4:

	function foo()
	{
	u16 buffer[] = { 1, 2, 3 };
	...
	}

	The long term solution to this issue is to add an option to gcc to
	allow controlling the general alignment of data, including constant
	initialization values.

	However this will only apply to the version of gcc which will have such
	an option. For other versions, there are four workarounds:

	a) Enforce as a rule that array initializations as described above
	are forbidden. This is generally not acceptable as they are valid,
	and usual, C constructs. The only case where they could be rejected
	is when they actually equate to a const char* declaration, i.e. the
	array is initialized and never modified in the function's scope.

	b) Drop the requirement on unaligned accesses at least for ARMv7,
	i.e. do not throw a data abort exception upon unaligned accesses.
	But that will allow adding badly aligned code to U-Boot, only for
	it to fail when re-used with a stricter target, possibly once the
	bad code is already in mainline.

	c) Relax the -munaligned-access rule globally. This will prevent native
	unaligned accesses of course, but that will also hide any bug caused
	by a bad unaligned access, making it much harder to diagnose it. It
	is actually what already happens when building ARM targets with a
	pre-4.7 gcc, and it may actually already hide some bugs yet unseen
	until the target gets compiled with -munaligned-access.

	d) Relax the -munaligned-access rule only for for files susceptible to
	the local initialized array issue and for armv7 architectures and
	beyond. This minimizes the quantity of code which can hide unwanted
	misaligned accesses.

	The option retained is d).

	Considering that actual occurrences of the issue are rare (as of this
	writing, 5 files out of 7840 in U-Boot, or .3%, contain an initialized
	local char array which cannot actually be replaced with a const char*),
	contributors should not be required to systematically try and detect
	the issue in their patches.

	Detecting files susceptible to the issue can be automated through a
	filter installed as a hook in .git which recognizes local char array
	initializations. Automation should err on the false positive side, for
	instance flagging non-local arrays as if they were local if they cannot
	be told apart.

	In any case, detection shall not prevent committing the patch, but
	shall pre-populate the commit message with a note to the effect that
	this patch contains an initialized local char or 16-bit array and thus
	should be protected from the gcc 4.7 issue.

	Upon a positive detection, either $(PLATFORM_NO_UNALIGNED) should be
	added to CFLAGS for the affected file(s), or if the array is a pseudo
	const char*, it should be replaced by an actual one.