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1 227 jeremybenn
@section mmo backend
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The mmo object format is used exclusively together with Professor
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Donald E.@: Knuth's educational 64-bit processor MMIX.  The simulator
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@command{mmix} which is available at
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@url{http://www-cs-faculty.stanford.edu/~knuth/programs/mmix.tar.gz}
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understands this format.  That package also includes a combined
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assembler and linker called @command{mmixal}.  The mmo format has
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no advantages feature-wise compared to e.g. ELF.  It is a simple
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non-relocatable object format with no support for archives or
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debugging information, except for symbol value information and
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line numbers (which is not yet implemented in BFD).  See
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@url{http://www-cs-faculty.stanford.edu/~knuth/mmix.html} for more
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information about MMIX.  The ELF format is used for intermediate
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object files in the BFD implementation.
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@c We want to xref the symbol table node.  A feature in "chew"
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@c requires that "commands" do not contain spaces in the
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@c arguments.  Hence the hyphen in "Symbol-table".
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@menu
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* File layout::
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* Symbol-table::
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* mmo section mapping::
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@end menu
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@node File layout, Symbol-table, mmo, mmo
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@subsection File layout
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The mmo file contents is not partitioned into named sections as
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with e.g.@: ELF.  Memory areas is formed by specifying the
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location of the data that follows.  Only the memory area
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@samp{0x0000@dots{}00} to @samp{0x01ff@dots{}ff} is executable, so
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it is used for code (and constants) and the area
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@samp{0x2000@dots{}00} to @samp{0x20ff@dots{}ff} is used for
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writable data.  @xref{mmo section mapping}.
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There is provision for specifying ``special data'' of 65536
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different types.  We use type 80 (decimal), arbitrarily chosen the
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same as the ELF @code{e_machine} number for MMIX, filling it with
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section information normally found in ELF objects. @xref{mmo
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section mapping}.
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Contents is entered as 32-bit words, xor:ed over previous
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contents, always zero-initialized.  A word that starts with the
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byte @samp{0x98} forms a command called a @samp{lopcode}, where
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the next byte distinguished between the thirteen lopcodes.  The
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two remaining bytes, called the @samp{Y} and @samp{Z} fields, or
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the @samp{YZ} field (a 16-bit big-endian number), are used for
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various purposes different for each lopcode.  As documented in
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@url{http://www-cs-faculty.stanford.edu/~knuth/mmixal-intro.ps.gz},
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the lopcodes are:
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@table @code
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@item lop_quote
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0x98000001.  The next word is contents, regardless of whether it
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starts with 0x98 or not.
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@item lop_loc
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0x9801YYZZ, where @samp{Z} is 1 or 2.  This is a location
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directive, setting the location for the next data to the next
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32-bit word (for @math{Z = 1}) or 64-bit word (for @math{Z = 2}),
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plus @math{Y * 2^56}.  Normally @samp{Y} is 0 for the text segment
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and 2 for the data segment.
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@item lop_skip
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0x9802YYZZ.  Increase the current location by @samp{YZ} bytes.
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@item lop_fixo
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0x9803YYZZ, where @samp{Z} is 1 or 2.  Store the current location
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as 64 bits into the location pointed to by the next 32-bit
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(@math{Z = 1}) or 64-bit (@math{Z = 2}) word, plus @math{Y *
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2^56}.
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@item lop_fixr
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0x9804YYZZ.  @samp{YZ} is stored into the current location plus
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@math{2 - 4 * YZ}.
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@item lop_fixrx
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0x980500ZZ.  @samp{Z} is 16 or 24.  A value @samp{L} derived from
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the following 32-bit word are used in a manner similar to
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@samp{YZ} in lop_fixr: it is xor:ed into the current location
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minus @math{4 * L}.  The first byte of the word is 0 or 1.  If it
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is 1, then @math{L = (@var{lowest 24 bits of word}) - 2^Z}, if 0,
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then @math{L = (@var{lowest 24 bits of word})}.
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@item lop_file
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0x9806YYZZ.  @samp{Y} is the file number, @samp{Z} is count of
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32-bit words.  Set the file number to @samp{Y} and the line
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counter to 0.  The next @math{Z * 4} bytes contain the file name,
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padded with zeros if the count is not a multiple of four.  The
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same @samp{Y} may occur multiple times, but @samp{Z} must be 0 for
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all but the first occurrence.
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@item lop_line
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0x9807YYZZ.  @samp{YZ} is the line number.  Together with
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lop_file, it forms the source location for the next 32-bit word.
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Note that for each non-lopcode 32-bit word, line numbers are
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assumed incremented by one.
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@item lop_spec
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0x9808YYZZ.  @samp{YZ} is the type number.  Data until the next
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lopcode other than lop_quote forms special data of type @samp{YZ}.
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@xref{mmo section mapping}.
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Other types than 80, (or type 80 with a content that does not
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parse) is stored in sections named @code{.MMIX.spec_data.@var{n}}
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where @var{n} is the @samp{YZ}-type.  The flags for such a
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sections say not to allocate or load the data.  The vma is 0.
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Contents of multiple occurrences of special data @var{n} is
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concatenated to the data of the previous lop_spec @var{n}s.  The
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location in data or code at which the lop_spec occurred is lost.
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111
@item lop_pre
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0x980901ZZ.  The first lopcode in a file.  The @samp{Z} field forms the
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length of header information in 32-bit words, where the first word
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tells the time in seconds since @samp{00:00:00 GMT Jan 1 1970}.
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@item lop_post
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0x980a00ZZ.  @math{Z > 32}.  This lopcode follows after all
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content-generating lopcodes in a program.  The @samp{Z} field
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denotes the value of @samp{rG} at the beginning of the program.
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The following @math{256 - Z} big-endian 64-bit words are loaded
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into global registers @samp{$G} @dots{} @samp{$255}.
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@item lop_stab
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0x980b0000.  The next-to-last lopcode in a program.  Must follow
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immediately after the lop_post lopcode and its data.  After this
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lopcode follows all symbols in a compressed format
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(@pxref{Symbol-table}).
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@item lop_end
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0x980cYYZZ.  The last lopcode in a program.  It must follow the
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lop_stab lopcode and its data.  The @samp{YZ} field contains the
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number of 32-bit words of symbol table information after the
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preceding lop_stab lopcode.
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@end table
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Note that the lopcode "fixups"; @code{lop_fixr}, @code{lop_fixrx} and
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@code{lop_fixo} are not generated by BFD, but are handled.  They are
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generated by @code{mmixal}.
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This trivial one-label, one-instruction file:
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142
@example
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 :Main TRAP 1,2,3
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@end example
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can be represented this way in mmo:
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@example
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 0x98090101 - lop_pre, one 32-bit word with timestamp.
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 <timestamp>
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 0x98010002 - lop_loc, text segment, using a 64-bit address.
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              Note that mmixal does not emit this for the file above.
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 0x00000000 - Address, high 32 bits.
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 0x00000000 - Address, low 32 bits.
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 0x98060002 - lop_file, 2 32-bit words for file-name.
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 0x74657374 - "test"
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 0x2e730000 - ".s\0\0"
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 0x98070001 - lop_line, line 1.
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 0x00010203 - TRAP 1,2,3
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 0x980a00ff - lop_post, setting $255 to 0.
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 0x00000000
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 0x00000000
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 0x980b0000 - lop_stab for ":Main" = 0, serial 1.
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 0x203a4040   @xref{Symbol-table}.
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 0x10404020
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 0x4d206120
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 0x69016e00
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 0x81000000
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 0x980c0005 - lop_end; symbol table contained five 32-bit words.
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@end example
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@node Symbol-table, mmo section mapping, File layout, mmo
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@subsection Symbol table format
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From mmixal.w (or really, the generated mmixal.tex) in
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@url{http://www-cs-faculty.stanford.edu/~knuth/programs/mmix.tar.gz}):
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``Symbols are stored and retrieved by means of a @samp{ternary
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search trie}, following ideas of Bentley and Sedgewick. (See
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ACM--SIAM Symp.@: on Discrete Algorithms @samp{8} (1997), 360--369;
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R.@:Sedgewick, @samp{Algorithms in C} (Reading, Mass.@:
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Addison--Wesley, 1998), @samp{15.4}.)  Each trie node stores a
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character, and there are branches to subtries for the cases where
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a given character is less than, equal to, or greater than the
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character in the trie.  There also is a pointer to a symbol table
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entry if a symbol ends at the current node.''
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So it's a tree encoded as a stream of bytes.  The stream of bytes
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acts on a single virtual global symbol, adding and removing
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characters and signalling complete symbol points.  Here, we read
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the stream and create symbols at the completion points.
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First, there's a control byte @code{m}.  If any of the listed bits
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in @code{m} is nonzero, we execute what stands at the right, in
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the listed order:
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@example
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 (MMO3_LEFT)
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 0x40 - Traverse left trie.
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        (Read a new command byte and recurse.)
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 (MMO3_SYMBITS)
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 0x2f - Read the next byte as a character and store it in the
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        current character position; increment character position.
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        Test the bits of @code{m}:
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        (MMO3_WCHAR)
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        0x80 - The character is 16-bit (so read another byte,
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               merge into current character.
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        (MMO3_TYPEBITS)
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        0xf  - We have a complete symbol; parse the type, value
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               and serial number and do what should be done
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               with a symbol.  The type and length information
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               is in j = (m & 0xf).
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               (MMO3_REGQUAL_BITS)
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               j == 0xf: A register variable.  The following
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                         byte tells which register.
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               j <= 8:   An absolute symbol.  Read j bytes as the
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                         big-endian number the symbol equals.
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                         A j = 2 with two zero bytes denotes an
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                         unknown symbol.
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               j > 8:    As with j <= 8, but add (0x20 << 56)
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                         to the value in the following j - 8
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                         bytes.
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               Then comes the serial number, as a variant of
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               uleb128, but better named ubeb128:
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               Read bytes and shift the previous value left 7
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               (multiply by 128).  Add in the new byte, repeat
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               until a byte has bit 7 set.  The serial number
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               is the computed value minus 128.
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        (MMO3_MIDDLE)
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        0x20 - Traverse middle trie.  (Read a new command byte
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               and recurse.)  Decrement character position.
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 (MMO3_RIGHT)
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 0x10 - Traverse right trie.  (Read a new command byte and
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        recurse.)
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@end example
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Let's look again at the @code{lop_stab} for the trivial file
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(@pxref{File layout}).
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@example
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 0x980b0000 - lop_stab for ":Main" = 0, serial 1.
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 0x203a4040
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 0x10404020
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 0x4d206120
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 0x69016e00
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 0x81000000
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@end example
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This forms the trivial trie (note that the path between ``:'' and
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``M'' is redundant):
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@example
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 203a     ":"
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 40       /
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 40      /
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 10      \
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 40      /
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 40     /
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 204d  "M"
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 2061  "a"
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 2069  "i"
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 016e  "n" is the last character in a full symbol, and
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       with a value represented in one byte.
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 00    The value is 0.
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 81    The serial number is 1.
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@end example
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@node mmo section mapping, , Symbol-table, mmo
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@subsection mmo section mapping
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The implementation in BFD uses special data type 80 (decimal) to
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encapsulate and describe named sections, containing e.g.@: debug
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information.  If needed, any datum in the encapsulation will be
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quoted using lop_quote.  First comes a 32-bit word holding the
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number of 32-bit words containing the zero-terminated zero-padded
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segment name.  After the name there's a 32-bit word holding flags
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describing the section type.  Then comes a 64-bit big-endian word
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with the section length (in bytes), then another with the section
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start address.  Depending on the type of section, the contents
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might follow, zero-padded to 32-bit boundary.  For a loadable
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section (such as data or code), the contents might follow at some
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later point, not necessarily immediately, as a lop_loc with the
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same start address as in the section description, followed by the
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contents.  This in effect forms a descriptor that must be emitted
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before the actual contents.  Sections described this way must not
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overlap.
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For areas that don't have such descriptors, synthetic sections are
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formed by BFD.  Consecutive contents in the two memory areas
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@samp{0x0000@dots{}00} to @samp{0x01ff@dots{}ff} and
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@samp{0x2000@dots{}00} to @samp{0x20ff@dots{}ff} are entered in
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sections named @code{.text} and @code{.data} respectively.  If an area
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is not otherwise described, but would together with a neighboring
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lower area be less than @samp{0x40000000} bytes long, it is joined
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with the lower area and the gap is zero-filled.  For other cases,
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a new section is formed, named @code{.MMIX.sec.@var{n}}.  Here,
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@var{n} is a number, a running count through the mmo file,
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starting at 0.
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303
A loadable section specified as:
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305
@example
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 .section secname,"ax"
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 TETRA 1,2,3,4,-1,-2009
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 BYTE 80
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@end example
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311
and linked to address @samp{0x4}, is represented by the sequence:
312
 
313
@example
314
 0x98080050 - lop_spec 80
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 0x00000002 - two 32-bit words for the section name
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 0x7365636e - "secn"
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 0x616d6500 - "ame\0"
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 0x00000033 - flags CODE, READONLY, LOAD, ALLOC
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 0x00000000 - high 32 bits of section length
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 0x0000001c - section length is 28 bytes; 6 * 4 + 1 + alignment to 32 bits
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 0x00000000 - high 32 bits of section address
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 0x00000004 - section address is 4
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 0x98010002 - 64 bits with address of following data
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 0x00000000 - high 32 bits of address
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 0x00000004 - low 32 bits: data starts at address 4
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 0x00000001 - 1
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 0x00000002 - 2
328
 0x00000003 - 3
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 0x00000004 - 4
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 0xffffffff - -1
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 0xfffff827 - -2009
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 0x50000000 - 80 as a byte, padded with zeros.
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@end example
334
 
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Note that the lop_spec wrapping does not include the section
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contents.  Compare this to a non-loaded section specified as:
337
 
338
@example
339
 .section thirdsec
340
 TETRA 200001,100002
341
 BYTE 38,40
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@end example
343
 
344
This, when linked to address @samp{0x200000000000001c}, is
345
represented by:
346
 
347
@example
348
 0x98080050 - lop_spec 80
349
 0x00000002 - two 32-bit words for the section name
350
 0x7365636e - "thir"
351
 0x616d6500 - "dsec"
352
 0x00000010 - flag READONLY
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 0x00000000 - high 32 bits of section length
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 0x0000000c - section length is 12 bytes; 2 * 4 + 2 + alignment to 32 bits
355
 0x20000000 - high 32 bits of address
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 0x0000001c - low 32 bits of address 0x200000000000001c
357
 0x00030d41 - 200001
358
 0x000186a2 - 100002
359
 0x26280000 - 38, 40 as bytes, padded with zeros
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@end example
361
 
362
For the latter example, the section contents must not be
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loaded in memory, and is therefore specified as part of the
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special data.  The address is usually unimportant but might
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provide information for e.g.@: the DWARF 2 debugging format.

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