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 xStormy16 ABI
 ************

 !!!!! NOTE !!!!!
 This document is a draft and is subject to change.
 !!!!! NOTE !!!!!

 This part of the file describes the conventions required to write
 ELF object files that are link-compatible with the ones produced
 by the GNU toolchains.

 Bit and Byte Ordering
 =====================

 This implementation is little-endian.   Bits are numbered starting
 from 0 being the LSB.

 In this document, 'word' means 16 bits.

 Calling Sequence
 ================

 The registers are allocated as follows:

 Register	Purpose
 -------------------------------------------------------------------
 r0, r1          Call-volatile.  May be changed during the execution
                 of a call instruction.
 r2 through r7   Argument passing;  call-clobbered.
 r8, r9		Call-volatile.  May be changed during the execution
 		of a call instruction.
 r10 through r13	Call-saved.
 r14		Program status word.
 r15		Stack pointer.


 Scalar values are returned in register r2-r7 if the value fits.
 Otherwise, a pointer is passed as a 'hidden' first argument and
 the return value is placed there.

 Arguments are passed in registers starting in r2, then on the stack.
 Arguments of size not a multiple of a word are padded to whole words.
 If an argument would otherwise be passed partially in registers, and
 partially on the stack, the whole of it is passed on the stack.  The
 last argument is pushed on the stack first.

 After a procedure's arguments are pushed on the stack,
 the return address is pushed on the stack, as if by the call
 instruction.  The return address is on the top of the stack when
 a procedure is called.

 Objects whose size is a multiple of 16 bits are aligned to a 16-bit
 boundary.

 Pointers are 16 bits, referencing addresses between 0 and 0xFFFF.

 Procedure pointers are also implemented as 16-bit pointers.

 Variable Argument Functions
 ===========================

 The C type 'va_list' is implemented as a structure, as follows:

 struct {
   char *base;
   unsigned count;
 }

 Both fields are 16 bits.  An argument of size N bytes
 (N will be even) is accessed as if by the following code:

 char *result;
 /* count = #bytes non-variable arguments */
 /* 12 = #bytes for register arguments */
 if (count + N > 12)
   {
     if (count < 12)
       count = 12;
     result = base - (count + N - 12 + 4);
   }
 else
   {
     result = base + count;
   }
 count += N;
 /* The argument is at `*result'.  */


 One implementation of this is if a variadic function first
 pushes registers 2 through 7 in sequence at entry, and
 sets 'base' to the address of the first word pushed,
 producing a stack that appears like:

 SP ->
 	[other data]
 	r7
 	r6
 	r5
 	r4
 	r3
 count->	r2
 	Return address (two words)
 	7th procedure parameter word
 	8th procedure parameter word
 	...
 	last procedure parameter word

 and initializes 'count' to be the number of bytes of non-variable
 arguments to the function.

 ELF File Format
 ===============

 ELF file header
 ---------------

 xStormy16 ELF files are distinguished by the value EM_XSTORMY16 in
 the e_machine field of the ELF file header:

 #define EM_XSTORMY16	        0xad45

 DWARF Register Number Mapping
 -----------------------------

 Registers r0 through r15 are mapped to numbers 0 through 15.

 Relocations
 -----------

 RELA relocs are used exclusively.  The relocation types defined are:

 Name			Value	Field	Calculation	Overflow
 ----------------------------------------------------------------
 R_XSTORMY16_NONE           0     none      none           none
 R_XSTORMY16_32             1      32       S + A          none
 R_XSTORMY16_16             2      16       S + A          either
 R_XSTORMY16_8              3       8       S + A          unsigned
 R_XSTORMY16_PC32           4      32       S + A - P      none
 R_XSTORMY16_PC16           5      16       S + A - P      signed
 R_XSTORMY16_PC8            6       8       S + A - P      signed
 R_XSTORMY16_REL_12         7      16:12:0  S + A - P      signed
 R_XSTORMY16_24             8      32:23:1 (S + A) >> 1    unsigned
 R_XSTORMY16_FPTR16         9      16       S + A          either
 R_XSTORMY16_LO16           10     16       S + A          none
 R_XSTORMY16_HI16           11     32:16:16 S + A          none
 R_XSTORMY16_12             12     16:12:0  S + A          signed
 R_XSTORMY16_GNU_VTINHERIT  128    n/a      n/a            n/a
 R_XSTORMY16_GNU_VTENTRY    129    n/a      n/a            n/a

 In the 'Field' column, the first number indicates whether the
 relocation refers to a byte, word or doubleword.  The second number,
 if any, indicates the size of the bit-field into which the relocation
 is to occur (and also the size for overflow checking).  The third
 number indicates the first bit of the bit-field in the word or
 doubleword, counting the LSB as bit 0.

 In the 'Calculation' column, 'S' is the value of the symbol to which
 the reloc refers, 'A' is the addend, and 'P' represents the place of
 the storage unit being relocated.

 In the 'Overflow' column, 'none' means that any overflow of the
 computation performed in the 'Calculation' column is ignored.
 'signed' means that the overflow is only reported if it happens when
 the values are treated as signed quantities.  'unsigned' is the same,
 except that the values are treated as unsigned quantities.  'either'
 means that overflow is reported for either signed or unsigned
 overflow.


 Copyright (C) 2001-2021 Free Software Foundation, Inc.

 Copying and distribution of this file, with or without modification,
 are permitted in any medium without royalty provided the copyright
 notice and this notice are preserved.
	xStormy16 ABI
	************

	!!!!! NOTE !!!!!
	This document is a draft and is subject to change.
	!!!!! NOTE !!!!!

	This part of the file describes the conventions required to write
	ELF object files that are link-compatible with the ones produced
	by the GNU toolchains.

	Bit and Byte Ordering
	=====================

	This implementation is little-endian. Bits are numbered starting
	from 0 being the LSB.

	In this document, 'word' means 16 bits.

	Calling Sequence
	================

	The registers are allocated as follows:

	Register Purpose
	-------------------------------------------------------------------
	r0, r1 Call-volatile. May be changed during the execution
	of a call instruction.
	r2 through r7 Argument passing; call-clobbered.
	r8, r9 Call-volatile. May be changed during the execution
	of a call instruction.
	r10 through r13 Call-saved.
	r14 Program status word.
	r15 Stack pointer.


	Scalar values are returned in register r2-r7 if the value fits.
	Otherwise, a pointer is passed as a 'hidden' first argument and
	the return value is placed there.

	Arguments are passed in registers starting in r2, then on the stack.
	Arguments of size not a multiple of a word are padded to whole words.
	If an argument would otherwise be passed partially in registers, and
	partially on the stack, the whole of it is passed on the stack. The
	last argument is pushed on the stack first.

	After a procedure's arguments are pushed on the stack,
	the return address is pushed on the stack, as if by the call
	instruction. The return address is on the top of the stack when
	a procedure is called.

	Objects whose size is a multiple of 16 bits are aligned to a 16-bit
	boundary.

	Pointers are 16 bits, referencing addresses between 0 and 0xFFFF.

	Procedure pointers are also implemented as 16-bit pointers.

	Variable Argument Functions
	===========================

	The C type 'va_list' is implemented as a structure, as follows:

	struct {
	char *base;
	unsigned count;
	}

	Both fields are 16 bits. An argument of size N bytes
	(N will be even) is accessed as if by the following code:

	char *result;
	/* count = #bytes non-variable arguments */
	/* 12 = #bytes for register arguments */
	if (count + N > 12)
	{
	if (count < 12)
	count = 12;
	result = base - (count + N - 12 + 4);
	}
	else
	{
	result = base + count;
	}
	count += N;
	/* The argument is at `result'. /


	One implementation of this is if a variadic function first
	pushes registers 2 through 7 in sequence at entry, and
	sets 'base' to the address of the first word pushed,
	producing a stack that appears like:

	SP ->
	[other data]
	r7
	r6
	r5
	r4
	r3
	count-> r2
	Return address (two words)
	7th procedure parameter word
	8th procedure parameter word
	...
	last procedure parameter word

	and initializes 'count' to be the number of bytes of non-variable
	arguments to the function.

	ELF File Format
	===============

	ELF file header
	---------------

	xStormy16 ELF files are distinguished by the value EM_XSTORMY16 in
	the e_machine field of the ELF file header:

	#define EM_XSTORMY16 0xad45

	DWARF Register Number Mapping
	-----------------------------

	Registers r0 through r15 are mapped to numbers 0 through 15.

	Relocations
	-----------

	RELA relocs are used exclusively. The relocation types defined are:

	Name Value Field Calculation Overflow
	----------------------------------------------------------------
	R_XSTORMY16_NONE 0 none none none
	R_XSTORMY16_32 1 32 S + A none
	R_XSTORMY16_16 2 16 S + A either
	R_XSTORMY16_8 3 8 S + A unsigned
	R_XSTORMY16_PC32 4 32 S + A - P none
	R_XSTORMY16_PC16 5 16 S + A - P signed
	R_XSTORMY16_PC8 6 8 S + A - P signed
	R_XSTORMY16_REL_12 7 16:12:0 S + A - P signed
	R_XSTORMY16_24 8 32:23:1 (S + A) >> 1 unsigned
	R_XSTORMY16_FPTR16 9 16 S + A either
	R_XSTORMY16_LO16 10 16 S + A none
	R_XSTORMY16_HI16 11 32:16:16 S + A none
	R_XSTORMY16_12 12 16:12:0 S + A signed
	R_XSTORMY16_GNU_VTINHERIT 128 n/a n/a n/a
	R_XSTORMY16_GNU_VTENTRY 129 n/a n/a n/a

	In the 'Field' column, the first number indicates whether the
	relocation refers to a byte, word or doubleword. The second number,
	if any, indicates the size of the bit-field into which the relocation
	is to occur (and also the size for overflow checking). The third
	number indicates the first bit of the bit-field in the word or
	doubleword, counting the LSB as bit 0.

	In the 'Calculation' column, 'S' is the value of the symbol to which
	the reloc refers, 'A' is the addend, and 'P' represents the place of
	the storage unit being relocated.

	In the 'Overflow' column, 'none' means that any overflow of the
	computation performed in the 'Calculation' column is ignored.
	'signed' means that the overflow is only reported if it happens when
	the values are treated as signed quantities. 'unsigned' is the same,
	except that the values are treated as unsigned quantities. 'either'
	means that overflow is reported for either signed or unsigned
	overflow.


	Copyright (C) 2001-2021 Free Software Foundation, Inc.

	Copying and distribution of this file, with or without modification,
	are permitted in any medium without royalty provided the copyright
	notice and this notice are preserved.