bfd/doc/mmo.texi - native_client/nacl-gdb - Git at Google

 @section mmo backend
 The mmo object format is used exclusively together with Professor
 Donald E.@: Knuth's educational 64-bit processor MMIX.  The simulator
 @command{mmix} which is available at
 @url{http://www-cs-faculty.stanford.edu/~knuth/programs/mmix.tar.gz}
 understands this format.  That package also includes a combined
 assembler and linker called @command{mmixal}.  The mmo format has
 no advantages feature-wise compared to e.g. ELF.  It is a simple
 non-relocatable object format with no support for archives or
 debugging information, except for symbol value information and
 line numbers (which is not yet implemented in BFD).  See
 @url{http://www-cs-faculty.stanford.edu/~knuth/mmix.html} for more
 information about MMIX.  The ELF format is used for intermediate
 object files in the BFD implementation.

 @c We want to xref the symbol table node.  A feature in "chew"
 @c requires that "commands" do not contain spaces in the
 @c arguments.  Hence the hyphen in "Symbol-table".
 @menu
 * File layout::
 * Symbol-table::
 * mmo section mapping::
 @end menu

 @node File layout, Symbol-table, mmo, mmo
 @subsection File layout
 The mmo file contents is not partitioned into named sections as
 with e.g.@: ELF.  Memory areas is formed by specifying the
 location of the data that follows.  Only the memory area
 @samp{0x0000@dots{}00} to @samp{0x01ff@dots{}ff} is executable, so
 it is used for code (and constants) and the area
 @samp{0x2000@dots{}00} to @samp{0x20ff@dots{}ff} is used for
 writable data.  @xref{mmo section mapping}.

 There is provision for specifying ``special data'' of 65536
 different types.  We use type 80 (decimal), arbitrarily chosen the
 same as the ELF @code{e_machine} number for MMIX, filling it with
 section information normally found in ELF objects. @xref{mmo
 section mapping}.

 Contents is entered as 32-bit words, xor:ed over previous
 contents, always zero-initialized.  A word that starts with the
 byte @samp{0x98} forms a command called a @samp{lopcode}, where
 the next byte distinguished between the thirteen lopcodes.  The
 two remaining bytes, called the @samp{Y} and @samp{Z} fields, or
 the @samp{YZ} field (a 16-bit big-endian number), are used for
 various purposes different for each lopcode.  As documented in
 @url{http://www-cs-faculty.stanford.edu/~knuth/mmixal-intro.ps.gz},
 the lopcodes are:

 @table @code
 @item lop_quote
 0x98000001.  The next word is contents, regardless of whether it
 starts with 0x98 or not.

 @item lop_loc
 0x9801YYZZ, where @samp{Z} is 1 or 2.  This is a location
 directive, setting the location for the next data to the next
 32-bit word (for @math{Z = 1}) or 64-bit word (for @math{Z = 2}),
 plus @math{Y * 2^56}.  Normally @samp{Y} is 0 for the text segment
 and 2 for the data segment.

 @item lop_skip
 0x9802YYZZ.  Increase the current location by @samp{YZ} bytes.

 @item lop_fixo
 0x9803YYZZ, where @samp{Z} is 1 or 2.  Store the current location
 as 64 bits into the location pointed to by the next 32-bit
 (@math{Z = 1}) or 64-bit (@math{Z = 2}) word, plus @math{Y *
 2^56}.

 @item lop_fixr
 0x9804YYZZ.  @samp{YZ} is stored into the current location plus
 @math{2 - 4 * YZ}.

 @item lop_fixrx
 0x980500ZZ.  @samp{Z} is 16 or 24.  A value @samp{L} derived from
 the following 32-bit word are used in a manner similar to
 @samp{YZ} in lop_fixr: it is xor:ed into the current location
 minus @math{4 * L}.  The first byte of the word is 0 or 1.  If it
 is 1, then @math{L = (@var{lowest 24 bits of word}) - 2^Z}, if 0,
 then @math{L = (@var{lowest 24 bits of word})}.

 @item lop_file
 0x9806YYZZ.  @samp{Y} is the file number, @samp{Z} is count of
 32-bit words.  Set the file number to @samp{Y} and the line
 counter to 0.  The next @math{Z * 4} bytes contain the file name,
 padded with zeros if the count is not a multiple of four.  The
 same @samp{Y} may occur multiple times, but @samp{Z} must be 0 for
 all but the first occurrence.

 @item lop_line
 0x9807YYZZ.  @samp{YZ} is the line number.  Together with
 lop_file, it forms the source location for the next 32-bit word.
 Note that for each non-lopcode 32-bit word, line numbers are
 assumed incremented by one.

 @item lop_spec
 0x9808YYZZ.  @samp{YZ} is the type number.  Data until the next
 lopcode other than lop_quote forms special data of type @samp{YZ}.
 @xref{mmo section mapping}.

 Other types than 80, (or type 80 with a content that does not
 parse) is stored in sections named @code{.MMIX.spec_data.@var{n}}
 where @var{n} is the @samp{YZ}-type.  The flags for such a
 sections say not to allocate or load the data.  The vma is 0.
 Contents of multiple occurrences of special data @var{n} is
 concatenated to the data of the previous lop_spec @var{n}s.  The
 location in data or code at which the lop_spec occurred is lost.

 @item lop_pre
 0x980901ZZ.  The first lopcode in a file.  The @samp{Z} field forms the
 length of header information in 32-bit words, where the first word
 tells the time in seconds since @samp{00:00:00 GMT Jan 1 1970}.

 @item lop_post
 0x980a00ZZ.  @math{Z > 32}.  This lopcode follows after all
 content-generating lopcodes in a program.  The @samp{Z} field
 denotes the value of @samp{rG} at the beginning of the program.
 The following @math{256 - Z} big-endian 64-bit words are loaded
 into global registers @samp{$G} @dots{} @samp{$255}.

 @item lop_stab
 0x980b0000.  The next-to-last lopcode in a program.  Must follow
 immediately after the lop_post lopcode and its data.  After this
 lopcode follows all symbols in a compressed format
 (@pxref{Symbol-table}).

 @item lop_end
 0x980cYYZZ.  The last lopcode in a program.  It must follow the
 lop_stab lopcode and its data.  The @samp{YZ} field contains the
 number of 32-bit words of symbol table information after the
 preceding lop_stab lopcode.
 @end table

 Note that the lopcode "fixups"; @code{lop_fixr}, @code{lop_fixrx} and
 @code{lop_fixo} are not generated by BFD, but are handled.  They are
 generated by @code{mmixal}.

 This trivial one-label, one-instruction file:

 @example
  :Main TRAP 1,2,3
 @end example

 can be represented this way in mmo:

 @example
  0x98090101 - lop_pre, one 32-bit word with timestamp.
  <timestamp>
  0x98010002 - lop_loc, text segment, using a 64-bit address.
               Note that mmixal does not emit this for the file above.
  0x00000000 - Address, high 32 bits.
  0x00000000 - Address, low 32 bits.
  0x98060002 - lop_file, 2 32-bit words for file-name.
  0x74657374 - "test"
  0x2e730000 - ".s\0\0"
  0x98070001 - lop_line, line 1.
  0x00010203 - TRAP 1,2,3
  0x980a00ff - lop_post, setting $255 to 0.
  0x00000000
  0x00000000
  0x980b0000 - lop_stab for ":Main" = 0, serial 1.
  0x203a4040   @xref{Symbol-table}.
  0x10404020
  0x4d206120
  0x69016e00
  0x81000000
  0x980c0005 - lop_end; symbol table contained five 32-bit words.
 @end example
 @node Symbol-table, mmo section mapping, File layout, mmo
 @subsection Symbol table format
 From mmixal.w (or really, the generated mmixal.tex) in
 @url{http://www-cs-faculty.stanford.edu/~knuth/programs/mmix.tar.gz}):
 ``Symbols are stored and retrieved by means of a @samp{ternary
 search trie}, following ideas of Bentley and Sedgewick. (See
 ACM--SIAM Symp.@: on Discrete Algorithms @samp{8} (1997), 360--369;
 R.@:Sedgewick, @samp{Algorithms in C} (Reading, Mass.@:
 Addison--Wesley, 1998), @samp{15.4}.)  Each trie node stores a
 character, and there are branches to subtries for the cases where
 a given character is less than, equal to, or greater than the
 character in the trie.  There also is a pointer to a symbol table
 entry if a symbol ends at the current node.''

 So it's a tree encoded as a stream of bytes.  The stream of bytes
 acts on a single virtual global symbol, adding and removing
 characters and signalling complete symbol points.  Here, we read
 the stream and create symbols at the completion points.

 First, there's a control byte @code{m}.  If any of the listed bits
 in @code{m} is nonzero, we execute what stands at the right, in
 the listed order:

 @example
  (MMO3_LEFT)
  0x40 - Traverse left trie.
         (Read a new command byte and recurse.)

  (MMO3_SYMBITS)
  0x2f - Read the next byte as a character and store it in the
         current character position; increment character position.
         Test the bits of @code{m}:

         (MMO3_WCHAR)
         0x80 - The character is 16-bit (so read another byte,
                merge into current character.

         (MMO3_TYPEBITS)
         0xf  - We have a complete symbol; parse the type, value
                and serial number and do what should be done
                with a symbol.  The type and length information
                is in j = (m & 0xf).

                (MMO3_REGQUAL_BITS)
                j == 0xf: A register variable.  The following
                          byte tells which register.
                j <= 8:   An absolute symbol.  Read j bytes as the
                          big-endian number the symbol equals.
                          A j = 2 with two zero bytes denotes an
                          unknown symbol.
                j > 8:    As with j <= 8, but add (0x20 << 56)
                          to the value in the following j - 8
                          bytes.

                Then comes the serial number, as a variant of
                uleb128, but better named ubeb128:
                Read bytes and shift the previous value left 7
                (multiply by 128).  Add in the new byte, repeat
                until a byte has bit 7 set.  The serial number
                is the computed value minus 128.

         (MMO3_MIDDLE)
         0x20 - Traverse middle trie.  (Read a new command byte
                and recurse.)  Decrement character position.

  (MMO3_RIGHT)
  0x10 - Traverse right trie.  (Read a new command byte and
         recurse.)
 @end example

 Let's look again at the @code{lop_stab} for the trivial file
 (@pxref{File layout}).

 @example
  0x980b0000 - lop_stab for ":Main" = 0, serial 1.
  0x203a4040
  0x10404020
  0x4d206120
  0x69016e00
  0x81000000
 @end example

 This forms the trivial trie (note that the path between ``:'' and
 ``M'' is redundant):

 @example
  203a     ":"
  40       /
  40      /
  10      \
  40      /
  40     /
  204d  "M"
  2061  "a"
  2069  "i"
  016e  "n" is the last character in a full symbol, and
        with a value represented in one byte.
  00    The value is 0.
  81    The serial number is 1.
 @end example

 @node mmo section mapping, , Symbol-table, mmo
 @subsection mmo section mapping
 The implementation in BFD uses special data type 80 (decimal) to
 encapsulate and describe named sections, containing e.g.@: debug
 information.  If needed, any datum in the encapsulation will be
 quoted using lop_quote.  First comes a 32-bit word holding the
 number of 32-bit words containing the zero-terminated zero-padded
 segment name.  After the name there's a 32-bit word holding flags
 describing the section type.  Then comes a 64-bit big-endian word
 with the section length (in bytes), then another with the section
 start address.  Depending on the type of section, the contents
 might follow, zero-padded to 32-bit boundary.  For a loadable
 section (such as data or code), the contents might follow at some
 later point, not necessarily immediately, as a lop_loc with the
 same start address as in the section description, followed by the
 contents.  This in effect forms a descriptor that must be emitted
 before the actual contents.  Sections described this way must not
 overlap.

 For areas that don't have such descriptors, synthetic sections are
 formed by BFD.  Consecutive contents in the two memory areas
 @samp{0x0000@dots{}00} to @samp{0x01ff@dots{}ff} and
 @samp{0x2000@dots{}00} to @samp{0x20ff@dots{}ff} are entered in
 sections named @code{.text} and @code{.data} respectively.  If an area
 is not otherwise described, but would together with a neighboring
 lower area be less than @samp{0x40000000} bytes long, it is joined
 with the lower area and the gap is zero-filled.  For other cases,
 a new section is formed, named @code{.MMIX.sec.@var{n}}.  Here,
 @var{n} is a number, a running count through the mmo file,
 starting at 0.

 A loadable section specified as:

 @example
  .section secname,"ax"
  TETRA 1,2,3,4,-1,-2009
  BYTE 80
 @end example

 and linked to address @samp{0x4}, is represented by the sequence:

 @example
  0x98080050 - lop_spec 80
  0x00000002 - two 32-bit words for the section name
  0x7365636e - "secn"
  0x616d6500 - "ame\0"
  0x00000033 - flags CODE, READONLY, LOAD, ALLOC
  0x00000000 - high 32 bits of section length
  0x0000001c - section length is 28 bytes; 6 * 4 + 1 + alignment to 32 bits
  0x00000000 - high 32 bits of section address
  0x00000004 - section address is 4
  0x98010002 - 64 bits with address of following data
  0x00000000 - high 32 bits of address
  0x00000004 - low 32 bits: data starts at address 4
  0x00000001 - 1
  0x00000002 - 2
  0x00000003 - 3
  0x00000004 - 4
  0xffffffff - -1
  0xfffff827 - -2009
  0x50000000 - 80 as a byte, padded with zeros.
 @end example

 Note that the lop_spec wrapping does not include the section
 contents.  Compare this to a non-loaded section specified as:

 @example
  .section thirdsec
  TETRA 200001,100002
  BYTE 38,40
 @end example

 This, when linked to address @samp{0x200000000000001c}, is
 represented by:

 @example
  0x98080050 - lop_spec 80
  0x00000002 - two 32-bit words for the section name
  0x7365636e - "thir"
  0x616d6500 - "dsec"
  0x00000010 - flag READONLY
  0x00000000 - high 32 bits of section length
  0x0000000c - section length is 12 bytes; 2 * 4 + 2 + alignment to 32 bits
  0x20000000 - high 32 bits of address
  0x0000001c - low 32 bits of address 0x200000000000001c
  0x00030d41 - 200001
  0x000186a2 - 100002
  0x26280000 - 38, 40 as bytes, padded with zeros
 @end example

 For the latter example, the section contents must not be
 loaded in memory, and is therefore specified as part of the
 special data.  The address is usually unimportant but might
 provide information for e.g.@: the DWARF 2 debugging format.
	@section mmo backend
	The mmo object format is used exclusively together with Professor
	Donald E.@: Knuth's educational 64-bit processor MMIX. The simulator
	@command{mmix} which is available at
	@url{http://www-cs-faculty.stanford.edu/~knuth/programs/mmix.tar.gz}
	understands this format. That package also includes a combined
	assembler and linker called @command{mmixal}. The mmo format has
	no advantages feature-wise compared to e.g. ELF. It is a simple
	non-relocatable object format with no support for archives or
	debugging information, except for symbol value information and
	line numbers (which is not yet implemented in BFD). See
	@url{http://www-cs-faculty.stanford.edu/~knuth/mmix.html} for more
	information about MMIX. The ELF format is used for intermediate
	object files in the BFD implementation.

	@c We want to xref the symbol table node. A feature in "chew"
	@c requires that "commands" do not contain spaces in the
	@c arguments. Hence the hyphen in "Symbol-table".
	@menu
	* File layout::
	* Symbol-table::
	* mmo section mapping::
	@end menu

	@node File layout, Symbol-table, mmo, mmo
	@subsection File layout
	The mmo file contents is not partitioned into named sections as
	with e.g.@: ELF. Memory areas is formed by specifying the
	location of the data that follows. Only the memory area
	@samp{0x0000@dots{}00} to @samp{0x01ff@dots{}ff} is executable, so
	it is used for code (and constants) and the area
	@samp{0x2000@dots{}00} to @samp{0x20ff@dots{}ff} is used for
	writable data. @xref{mmo section mapping}.

	There is provision for specifying ``special data'' of 65536
	different types. We use type 80 (decimal), arbitrarily chosen the
	same as the ELF @code{e_machine} number for MMIX, filling it with
	section information normally found in ELF objects. @xref{mmo
	section mapping}.

	Contents is entered as 32-bit words, xor:ed over previous
	contents, always zero-initialized. A word that starts with the
	byte @samp{0x98} forms a command called a @samp{lopcode}, where
	the next byte distinguished between the thirteen lopcodes. The
	two remaining bytes, called the @samp{Y} and @samp{Z} fields, or
	the @samp{YZ} field (a 16-bit big-endian number), are used for
	various purposes different for each lopcode. As documented in
	@url{http://www-cs-faculty.stanford.edu/~knuth/mmixal-intro.ps.gz},
	the lopcodes are:

	@table @code
	@item lop_quote
	0x98000001. The next word is contents, regardless of whether it
	starts with 0x98 or not.

	@item lop_loc
	0x9801YYZZ, where @samp{Z} is 1 or 2. This is a location
	directive, setting the location for the next data to the next
	32-bit word (for @math{Z = 1}) or 64-bit word (for @math{Z = 2}),
	plus @math{Y * 2^56}. Normally @samp{Y} is 0 for the text segment
	and 2 for the data segment.

	@item lop_skip
	0x9802YYZZ. Increase the current location by @samp{YZ} bytes.

	@item lop_fixo
	0x9803YYZZ, where @samp{Z} is 1 or 2. Store the current location
	as 64 bits into the location pointed to by the next 32-bit
	(@math{Z = 1}) or 64-bit (@math{Z = 2}) word, plus @math{Y *
	2^56}.

	@item lop_fixr
	0x9804YYZZ. @samp{YZ} is stored into the current location plus
	@math{2 - 4 * YZ}.

	@item lop_fixrx
	0x980500ZZ. @samp{Z} is 16 or 24. A value @samp{L} derived from
	the following 32-bit word are used in a manner similar to
	@samp{YZ} in lop_fixr: it is xor:ed into the current location
	minus @math{4 * L}. The first byte of the word is 0 or 1. If it
	is 1, then @math{L = (@var{lowest 24 bits of word}) - 2^Z}, if 0,
	then @math{L = (@var{lowest 24 bits of word})}.

	@item lop_file
	0x9806YYZZ. @samp{Y} is the file number, @samp{Z} is count of
	32-bit words. Set the file number to @samp{Y} and the line
	counter to 0. The next @math{Z * 4} bytes contain the file name,
	padded with zeros if the count is not a multiple of four. The
	same @samp{Y} may occur multiple times, but @samp{Z} must be 0 for
	all but the first occurrence.

	@item lop_line
	0x9807YYZZ. @samp{YZ} is the line number. Together with
	lop_file, it forms the source location for the next 32-bit word.
	Note that for each non-lopcode 32-bit word, line numbers are
	assumed incremented by one.

	@item lop_spec
	0x9808YYZZ. @samp{YZ} is the type number. Data until the next
	lopcode other than lop_quote forms special data of type @samp{YZ}.
	@xref{mmo section mapping}.

	Other types than 80, (or type 80 with a content that does not
	parse) is stored in sections named @code{.MMIX.spec_data.@var{n}}
	where @var{n} is the @samp{YZ}-type. The flags for such a
	sections say not to allocate or load the data. The vma is 0.
	Contents of multiple occurrences of special data @var{n} is
	concatenated to the data of the previous lop_spec @var{n}s. The
	location in data or code at which the lop_spec occurred is lost.

	@item lop_pre
	0x980901ZZ. The first lopcode in a file. The @samp{Z} field forms the
	length of header information in 32-bit words, where the first word
	tells the time in seconds since @samp{00:00:00 GMT Jan 1 1970}.

	@item lop_post
	0x980a00ZZ. @math{Z > 32}. This lopcode follows after all
	content-generating lopcodes in a program. The @samp{Z} field
	denotes the value of @samp{rG} at the beginning of the program.
	The following @math{256 - Z} big-endian 64-bit words are loaded
	into global registers @samp{$G} @dots{} @samp{$255}.

	@item lop_stab
	0x980b0000. The next-to-last lopcode in a program. Must follow
	immediately after the lop_post lopcode and its data. After this
	lopcode follows all symbols in a compressed format
	(@pxref{Symbol-table}).

	@item lop_end
	0x980cYYZZ. The last lopcode in a program. It must follow the
	lop_stab lopcode and its data. The @samp{YZ} field contains the
	number of 32-bit words of symbol table information after the
	preceding lop_stab lopcode.
	@end table

	Note that the lopcode "fixups"; @code{lop_fixr}, @code{lop_fixrx} and
	@code{lop_fixo} are not generated by BFD, but are handled. They are
	generated by @code{mmixal}.

	This trivial one-label, one-instruction file:

	@example
	:Main TRAP 1,2,3
	@end example

	can be represented this way in mmo:

	@example
	0x98090101 - lop_pre, one 32-bit word with timestamp.
	<timestamp>
	0x98010002 - lop_loc, text segment, using a 64-bit address.
	Note that mmixal does not emit this for the file above.
	0x00000000 - Address, high 32 bits.
	0x00000000 - Address, low 32 bits.
	0x98060002 - lop_file, 2 32-bit words for file-name.
	0x74657374 - "test"
	0x2e730000 - ".s\0\0"
	0x98070001 - lop_line, line 1.
	0x00010203 - TRAP 1,2,3
	0x980a00ff - lop_post, setting $255 to 0.
	0x00000000
	0x00000000
	0x980b0000 - lop_stab for ":Main" = 0, serial 1.
	0x203a4040 @xref{Symbol-table}.
	0x10404020
	0x4d206120
	0x69016e00
	0x81000000
	0x980c0005 - lop_end; symbol table contained five 32-bit words.
	@end example
	@node Symbol-table, mmo section mapping, File layout, mmo
	@subsection Symbol table format
	From mmixal.w (or really, the generated mmixal.tex) in
	@url{http://www-cs-faculty.stanford.edu/~knuth/programs/mmix.tar.gz}):
	``Symbols are stored and retrieved by means of a @samp{ternary
	search trie}, following ideas of Bentley and Sedgewick. (See
	ACM--SIAM Symp.@: on Discrete Algorithms @samp{8} (1997), 360--369;
	R.@:Sedgewick, @samp{Algorithms in C} (Reading, Mass.@:
	Addison--Wesley, 1998), @samp{15.4}.) Each trie node stores a
	character, and there are branches to subtries for the cases where
	a given character is less than, equal to, or greater than the
	character in the trie. There also is a pointer to a symbol table
	entry if a symbol ends at the current node.''

	So it's a tree encoded as a stream of bytes. The stream of bytes
	acts on a single virtual global symbol, adding and removing
	characters and signalling complete symbol points. Here, we read
	the stream and create symbols at the completion points.

	First, there's a control byte @code{m}. If any of the listed bits
	in @code{m} is nonzero, we execute what stands at the right, in
	the listed order:

	@example
	(MMO3_LEFT)
	0x40 - Traverse left trie.
	(Read a new command byte and recurse.)

	(MMO3_SYMBITS)
	0x2f - Read the next byte as a character and store it in the
	current character position; increment character position.
	Test the bits of @code{m}:

	(MMO3_WCHAR)
	0x80 - The character is 16-bit (so read another byte,
	merge into current character.

	(MMO3_TYPEBITS)
	0xf - We have a complete symbol; parse the type, value
	and serial number and do what should be done
	with a symbol. The type and length information
	is in j = (m & 0xf).

	(MMO3_REGQUAL_BITS)
	j == 0xf: A register variable. The following
	byte tells which register.
	j <= 8: An absolute symbol. Read j bytes as the
	big-endian number the symbol equals.
	A j = 2 with two zero bytes denotes an
	unknown symbol.
	j > 8: As with j <= 8, but add (0x20 << 56)
	to the value in the following j - 8
	bytes.

	Then comes the serial number, as a variant of
	uleb128, but better named ubeb128:
	Read bytes and shift the previous value left 7
	(multiply by 128). Add in the new byte, repeat
	until a byte has bit 7 set. The serial number
	is the computed value minus 128.

	(MMO3_MIDDLE)
	0x20 - Traverse middle trie. (Read a new command byte
	and recurse.) Decrement character position.

	(MMO3_RIGHT)
	0x10 - Traverse right trie. (Read a new command byte and
	recurse.)
	@end example

	Let's look again at the @code{lop_stab} for the trivial file
	(@pxref{File layout}).

	@example
	0x980b0000 - lop_stab for ":Main" = 0, serial 1.
	0x203a4040
	0x10404020
	0x4d206120
	0x69016e00
	0x81000000
	@end example

	This forms the trivial trie (note that the path between ``:'' and
	``M'' is redundant):

	@example
	203a ":"
	40 /
	40 /
	10 \
	40 /
	40 /
	204d "M"
	2061 "a"
	2069 "i"
	016e "n" is the last character in a full symbol, and
	with a value represented in one byte.
	00 The value is 0.
	81 The serial number is 1.
	@end example

	@node mmo section mapping, , Symbol-table, mmo
	@subsection mmo section mapping
	The implementation in BFD uses special data type 80 (decimal) to
	encapsulate and describe named sections, containing e.g.@: debug
	information. If needed, any datum in the encapsulation will be
	quoted using lop_quote. First comes a 32-bit word holding the
	number of 32-bit words containing the zero-terminated zero-padded
	segment name. After the name there's a 32-bit word holding flags
	describing the section type. Then comes a 64-bit big-endian word
	with the section length (in bytes), then another with the section
	start address. Depending on the type of section, the contents
	might follow, zero-padded to 32-bit boundary. For a loadable
	section (such as data or code), the contents might follow at some
	later point, not necessarily immediately, as a lop_loc with the
	same start address as in the section description, followed by the
	contents. This in effect forms a descriptor that must be emitted
	before the actual contents. Sections described this way must not
	overlap.

	For areas that don't have such descriptors, synthetic sections are
	formed by BFD. Consecutive contents in the two memory areas
	@samp{0x0000@dots{}00} to @samp{0x01ff@dots{}ff} and
	@samp{0x2000@dots{}00} to @samp{0x20ff@dots{}ff} are entered in
	sections named @code{.text} and @code{.data} respectively. If an area
	is not otherwise described, but would together with a neighboring
	lower area be less than @samp{0x40000000} bytes long, it is joined
	with the lower area and the gap is zero-filled. For other cases,
	a new section is formed, named @code{.MMIX.sec.@var{n}}. Here,
	@var{n} is a number, a running count through the mmo file,
	starting at 0.

	A loadable section specified as:

	@example
	.section secname,"ax"
	TETRA 1,2,3,4,-1,-2009
	BYTE 80
	@end example

	and linked to address @samp{0x4}, is represented by the sequence:

	@example
	0x98080050 - lop_spec 80
	0x00000002 - two 32-bit words for the section name
	0x7365636e - "secn"
	0x616d6500 - "ame\0"
	0x00000033 - flags CODE, READONLY, LOAD, ALLOC
	0x00000000 - high 32 bits of section length
	0x0000001c - section length is 28 bytes; 6 * 4 + 1 + alignment to 32 bits
	0x00000000 - high 32 bits of section address
	0x00000004 - section address is 4
	0x98010002 - 64 bits with address of following data
	0x00000000 - high 32 bits of address
	0x00000004 - low 32 bits: data starts at address 4
	0x00000001 - 1
	0x00000002 - 2
	0x00000003 - 3
	0x00000004 - 4
	0xffffffff - -1
	0xfffff827 - -2009
	0x50000000 - 80 as a byte, padded with zeros.
	@end example

	Note that the lop_spec wrapping does not include the section
	contents. Compare this to a non-loaded section specified as:

	@example
	.section thirdsec
	TETRA 200001,100002
	BYTE 38,40
	@end example

	This, when linked to address @samp{0x200000000000001c}, is
	represented by:

	@example
	0x98080050 - lop_spec 80
	0x00000002 - two 32-bit words for the section name
	0x7365636e - "thir"
	0x616d6500 - "dsec"
	0x00000010 - flag READONLY
	0x00000000 - high 32 bits of section length
	0x0000000c - section length is 12 bytes; 2 * 4 + 2 + alignment to 32 bits
	0x20000000 - high 32 bits of address
	0x0000001c - low 32 bits of address 0x200000000000001c
	0x00030d41 - 200001
	0x000186a2 - 100002
	0x26280000 - 38, 40 as bytes, padded with zeros
	@end example

	For the latter example, the section contents must not be
	loaded in memory, and is therefore specified as part of the
	special data. The address is usually unimportant but might
	provide information for e.g.@: the DWARF 2 debugging format.