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This is ctf-spec.info, produced by makeinfo version 7.0.2 from
ctf-spec.texi.
Copyright © 2021-2023 Free Software Foundation, Inc.
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU General Public License, Version 3 or any
later version published by the Free Software Foundation. A copy of the
license is included in the section entitled “GNU General Public
License”.
INFO-DIR-SECTION Software development
START-INFO-DIR-ENTRY
* CTF: (ctf-spec). The CTF file format.
END-INFO-DIR-ENTRY

File: ctf-spec.info, Node: Top, Next: Overview, Up: (dir)
The CTF file format
*******************
This manual describes version 3 of the CTF file format, which is
intended to model the C type system in a fashion that C programs can
consume at runtime.
* Menu:
* Overview::
* CTF archive::
* CTF dictionaries::
* Index::

File: ctf-spec.info, Node: Overview, Next: CTF archive, Prev: Top, Up: Top
Overview
********
The CTF file format compactly describes C types and the association
between function and data symbols and types: if embedded in ELF objects,
it can exploit the ELF string table to reduce duplication further.
There is no real concept of namespacing: only top-level types are
described, not types scoped to within single functions.
CTF dictionaries can be “children” of other dictionaries, in a
one-level hierarchy: child dictionaries can refer to types in the
parent, but the opposite is not sensible (since if you refer to a child
type in the parent, the actual type you cited would vary depending on
what child was attached). This parent/child definition is recorded in
the child, but only as a recommendation: users of the API have to attach
parents to children explicitly, and can choose to attach a child to any
parent they like, or to none, though doing so might lead to unpleasant
consequences like dangling references to types. *Note Type indexes and
type IDs::. Type lookups in child dicts that are not associated with a
parent at all will fail with ECTF_NOPARENT if a parent type was
needed.
The associated API to generate, merge together, and query this file
format will be described in the accompanying libctf manual once it is
written. There is no API to modify dictionaries once theyve been
written out: CTF is a write-once file format. (However, it is always
possible to dynamically create a new child dictionary on the fly and
attach it to a pre-existing, read-only parent.)
There are two major pieces to CTF: the “archive” and the
“dictionary”. Some relatives and ancestors of CTF call dictionaries
“containers”: the archive format is unique to this variant of CTF. (Much
of the source code still uses the old term.)
The archive file format is a very simple mmappable archive used to
group multiple dictionaries together into groups: it is expected to
slowly go away and be replaced by other mechanisms, but right now it is
an important part of the file format, used to group dictionaries
containing types with conflicting definitions in different TUs with the
overarching dictionary used to store all other types. (Even when
archives go away, the libctf API used to access them will remain, and
access the other mechanisms that replace it instead.)
The CTF dictionary consists of a “preamble”, which does not vary
between versions of the CTF file format, and a “header” and some number
of “sections”, which can vary between versions.
The rest of this specification describes the format of these
sections, first for the latest version of CTF, then for all earlier
versions supported by libctf: the earlier versions are defined in
terms of their differences from the next later one. We describe each
part of the format first by reproducing the C structure which defines
that part, then describing it at greater length in terms of file
offsets.
The description of the file format ends with a description of
relevant limits that apply to it. These limits can vary between file
format versions.
This document is quite young, so for now the C code in ctf.h should
be presumed correct when this document conflicts with it.

File: ctf-spec.info, Node: CTF archive, Next: CTF dictionaries, Prev: Overview, Up: Top
1 CTF archives
**************
The CTF archive format maps names to CTF dictionaries. The names may
contain any character other than \0, but for now archives containing
slashes in the names may not extract correctly. It is possible to
insert multiple members with the same name, but these are quite hard to
access reliably (you have to iterate through all the members rather than
opening by name) so this is not recommended.
CTF archives are not themselves compressed: the constituent
components, CTF dictionaries, can be compressed. (*Note CTF header::).
CTF archives usually contain a collection of related dictionaries,
one parent and many children of that parent. CTF archives can have a
member with a “default name”, .ctf (which can be represented as NULL
in the API). If present, this member is usually the parent of all the
children, but it is possible for CTF producers to emit parents with
different names if they wish (usually for backward- compatibility
purposes).
.ctf sections in ELF objects consist of a single CTF dictionary
rather than an archive of dictionaries if and only if the section
contains no types with identical names but conflicting definitions: if
two conflicting definitions exist, the deduplicator will place the type
most commonly referred to by other types in the parent and will place
the other type in a child named after the translation unit it is found
in, and will emit a CTF archive containing both dictionaries instead of
a raw dictionary. All types that refer to such conflicting types are
also placed in the per-translation-unit child.
The definition of an archive in ctf.h is as follows:
struct ctf_archive
{
uint64_t ctfa_magic;
uint64_t ctfa_model;
uint64_t ctfa_nfiles;
uint64_t ctfa_names;
uint64_t ctfa_ctfs;
};
typedef struct ctf_archive_modent
{
uint64_t name_offset;
uint64_t ctf_offset;
} ctf_archive_modent_t;
(Note one irregularity here: the ctf_archive_t is not a typedef to
struct ctf_archive, but a different typedef, private to libctf, so
that things that are not really archives can be made to appear as if
they were.)
All the above items are always in little-endian byte order,
regardless of the machine endianness.
The archive header has the following fields:
Offset Name Description
------------------------------------------------------------------------------------------
0x00 uint64_t ctfa_magic The magic number for archives, CTFA_MAGIC:
0x8b47f2a4d7623eeb.
0x08 uint64_t ctfa_model The data model for this archive: an arbitrary integer
that serves no purpose but to be handed back by the
libctf API. *Note Data models::.
0x10 uint64_t ctfa_nfiles The number of CTF dictionaries in this archive.
0x18 uint64_t ctfa_names Offset of the name table, in bytes from the start of
the archive. The name table is an array of struct
ctf_archive_modent_t[ctfa_nfiles].
0x20 uint64_t ctfa_ctfs Offset of the CTF table. Each element starts with a
uint64_t size, followed by a CTF dictionary.
The array pointed to by ctfa_names is an array of entries of
ctf_archive_modent:
Offset Name Description
---------------------------------------------------------------------------------
0x00 uint64_t name_offset Offset of this name, in bytes from the start
of the archive.
0x08 uint64_t ctf_offset Offset of this CTF dictionary, in bytes from
the start of the archive.
The ctfa_names array is sorted into ASCIIbetical order by name
(i.e. by the result of dereferencing the name_offset).
The archive file also contains a name table and a table of CTF
dictionaries: these are pointed to by the structures above. The name
table is a simple strtab which is not required to be sorted; the
dictionary array is described above in the entry for ctfa_ctfs.
The relative order of these various parts is not defined, except that
the header naturally always comes first.

File: ctf-spec.info, Node: CTF dictionaries, Next: Index, Prev: CTF archive, Up: Top
2 CTF dictionaries
******************
CTF dictionaries consist of a header, starting with a premable, and a
number of sections.
* Menu:
* CTF Preamble::
* CTF header::
* The type section::
* The symtypetab sections::
* The variable section::
* The label section::
* The string section::
* Data models::
* Limits of CTF::

File: ctf-spec.info, Node: CTF Preamble, Next: CTF header, Up: CTF dictionaries
2.1 CTF Preamble
================
The preamble is the only part of the CTF dictionary whose format cannot
vary between versions. It is never compressed. It is correspondingly
simple:
typedef struct ctf_preamble
{
unsigned short ctp_magic;
unsigned char ctp_version;
unsigned char ctp_flags;
} ctf_preamble_t;
#defines are provided under the names cth_magic, cth_version
and cth_flags to make the fields of the ctf_preamble_t appear to be
part of the ctf_header_t, so consuming programs rarely need to
consider the existence of the preamble as a separate structure.
Offset Name Description
-------------------------------------------------------------------------------
0x00 unsigned short ctp_magic The magic number for CTF
dictionaries, CTF_MAGIC: 0xdff2.
0x02 unsigned char ctp_version The version number of this CTF
dictionary.
0x03 ctp_flags Flags for this CTF file.
*Note CTF file-wide flags::.
Every element of a dictionary must be naturally aligned unless
otherwise specified. (This restriction will be lifted in later
versions.)
CTF dictionaries are stored in the native endianness of the system
that generates them: the consumer (e.g., libctf) can detect whether to
endian-flip a CTF dictionary by inspecting the ctp_magic. (If it
appears as 0xf2df, endian-flipping is needed.)
The version of the CTF dictionary can be determined by inspecting
ctp_version. The following versions are currently valid, and libctf
can read all of them:
Version Number Description
-------------------------------------------------------------------------------------------
CTF_VERSION_1 1 First version, rare. Very similar to Solaris CTF.
CTF_VERSION_1_UPGRADED_3 2 First version, upgraded to v3 or higher and
written out again. Name may change. Very rare.
CTF_VERSION_2 3 Second version, with many range limits lifted.
CTF_VERSION_3 4 Third and current version, documented here.
This section documents CTF_VERSION_3.
* Menu:
* CTF file-wide flags::

File: ctf-spec.info, Node: CTF file-wide flags, Up: CTF Preamble
2.1.1 CTF file-wide flags
-------------------------
The preamble contains bitflags in its ctp_flags field that describe
various file-wide properties. Some of the flags are valid only for
particular file-format versions, which means the flags can be used to
fix file-format bugs. Consumers that see unknown flags should
accordingly assume that the dictionary is not comprehensible, and refuse
to open them.
The following flags are currently defined. Many are bug workarounds,
valid only in CTFv3, and will not be valid in any future versions: the
same values may be reused for other flags in v4+.
Flag Versions Value Meaning
---------------------------------------------------------------------------------------
CTF_F_COMPRESS All 0x1 Compressed with zlib
CTF_F_NEWFUNCINFO 3 only 0x2 “New-format” func info section.
CTF_F_IDXSORTED 3+ 0x4 The index section is in sorted order
CTF_F_DYNSTR 3 only 0x8 The external strtab is in .dynstr and the
symtab used is .dynsym.
*Note The string section::
CTF_F_NEWFUNCINFO and CTF_F_IDXSORTED relate to the function info
and data object sections. *Note The symtypetab sections::.
Further flags (and further compression methods) wil be added in
future.

File: ctf-spec.info, Node: CTF header, Next: The type section, Prev: CTF Preamble, Up: CTF dictionaries
2.2 CTF header
==============
The CTF header is the first part of a CTF dictionary, including the
preamble. All parts of it other than the preamble (*note CTF
Preamble::) can vary between CTF file versions and are never compressed.
It contains things that apply to the dictionary as a whole, and a table
of the sections into which the rest of the dictionary is divided. The
sections tile the file: each section runs from the offset given until
the start of the next section. Only the last section cannot follow this
rule, so the header has a length for it instead.
All section offsets, here and in the rest of the CTF file, are
relative to the _end_ of the header. (This is annoyingly different to
how offsets in CTF archives are handled.)
This is the first structure to include offsets into the string table,
which are not straight references because CTF dictionaries can include
references into the ELF string table to save space, as well as into the
string table internal to the CTF dictionary. *Note The string section::
for more on these. Offset 0 is always the null string.
typedef struct ctf_header
{
ctf_preamble_t cth_preamble;
uint32_t cth_parlabel;
uint32_t cth_parname;
uint32_t cth_cuname;
uint32_t cth_lbloff;
uint32_t cth_objtoff;
uint32_t cth_funcoff;
uint32_t cth_objtidxoff;
uint32_t cth_funcidxoff;
uint32_t cth_varoff;
uint32_t cth_typeoff;
uint32_t cth_stroff;
uint32_t cth_strlen;
} ctf_header_t;
In detail:
Offset Name Description
-----------------------------------------------------------------------------------------------
0x00 ctf_preamble_t cth_preamble The preamble (conceptually embedded in the header).
*Note CTF Preamble::
0x04 uint32_t cth_parlabel The parent label, if deduplication happened against
a specific label: a strtab offset.
*Note The label section::. Currently unused and
always 0, but may be used in future when semantics
are attached to the label section.
0x08 uint32_t cth_parname The name of the parent dictionary deduplicated
against: a strtab offset. Interpretation is up to
the consumer (usually a CTF archive member name).
0 (the null string) if this is not a child
dictionary.
0x1c uint32_t cth_cuname The name of the compilation unit, for consumers
like GDB that want to know the name of CUs
associated with single CUs: a strtab offset. 0 if
this dictionary describes types from many CUs.
0x10 uint32_t cth_lbloff The offset of the label section, which tiles the
type space into named regions.
*Note The label section::.
0x14 uint32_t cth_objtoff The offset of the data object symtypetab section,
which maps ELF data symbols to types.
*Note The symtypetab sections::.
0x18 uint32_t cth_funcoff The offset of the function info symtypetab section,
which maps ELF function symbols to a return type
and arg types. *Note The symtypetab sections::.
0x1c uint32_t cth_objtidxoff The offset of the object index section, which maps
ELF object symbols to entries in the data object
section. *Note The symtypetab sections::.
0x20 uint32_t cth_funcidxoff The offset of the function info index section,
which maps ELF function symbols to entries in the
function info section.
*Note The symtypetab sections::.
0x24 uint32_t cth_varoff The offset of the variable section, which maps
string names to types.
*Note The variable section::.
0x28 uint32_t cth_typeoff The offset of the type section, the core of CTF,
which describes types using variable-length array
elements. *Note The type section::.
0x2c uint32_t cth_stroff The offset of the string section.
*Note The string section::.
0x30 uint32_t cth_strlen The length of the string section (not an offset!).
The CTF file ends at this point.
Everything from this point on (until the end of the file at
cth_stroff + cth_strlen) is compressed with zlib if CTF_F_COMPRESS
is set in the preambles ctp_flags.

File: ctf-spec.info, Node: The type section, Next: The symtypetab sections, Prev: CTF header, Up: CTF dictionaries
2.3 The type section
====================
This section is the most important section in CTF, describing all the
top-level types in the program. It consists of an array of type
structures, each of which describes a type of some “kind”: each kind of
type has some amount of variable-length data associated with it (some
kinds have none). The amount of variable-length data associated with a
given type can be determined by inspecting the type, so the reading code
can walk through the types in sequence at opening time.
Each type structure is one of a set of overlapping structures in a
discriminated union of sorts: the variable-length data for each type
immediately follows the types type structure. Heres the largest of
the overlapping structures, which is only needed for huge types and so
is very rarely seen:
typedef struct ctf_type
{
uint32_t ctt_name;
uint32_t ctt_info;
__extension__
union
{
uint32_t ctt_size;
uint32_t ctt_type;
};
uint32_t ctt_lsizehi;
uint32_t ctt_lsizelo;
} ctf_type_t;
Heres the much more common smaller form:
typedef struct ctf_stype
{
uint32_t ctt_name;
uint32_t ctt_info;
__extension__
union
{
uint32_t ctt_size;
uint32_t ctt_type;
};
} ctf_type_t;
If ctt_size is the #define CTF_LSIZE_SENT, 0xffffffff, this type
is described by a ctf_type_t: otherwise, a ctf_stype_t.
Heres what the fields mean:
Offset Name Description
-----------------------------------------------------------------------------------------------------
0x00 uint32_t ctt_name Strtab offset of the type name, if any (0 if none).
0x04 uint32_t ctt_info The “info word”, containing information on the kind
of this type, its variable-length data and whether
it is visible to name lookup. See
*Note The info word::.
0x08 uint32_t ctt_size The size of this type, if this type is of a kind for
which a size needs to be recorded (constant-size
types dont need one). If this is CTF_LSIZE_SENT,
this type is a huge type described by ctf_type_t.
0x08 uint32_t ctt_type The type this type refers to, if this type is of a
kind which refers to other types (like a pointer).
All such types are fixed-size, and no types that are
variable-size refer to other types, so ctt_size
and ctt_type overlap. All type kinds that use
ctt_type are described by ctf_stype_t, not
ctf_type_t. *Note Type indexes and type IDs::.
0x0c (ctf_type_t uint32_t ctt_lsizehi The high 32 bits of the size of a very large type.
only) The CTF_TYPE_LSIZE macro can be used to get a
64-bit size out of this field and the next one.
CTF_SIZE_TO_LSIZE_HI splits the ctt_lsizehi out
of it again.
0x10 (ctf_type_t uint32_t ctt_lsizelo The low 32 bits of the size of a very large type.
only) CTF_SIZE_TO_LSIZE_LO splits the ctt_lsizelo out
of a 64-bit size.
Two aspects of this need further explanation: the info word, and what
exactly a type ID is and how you determine it. (Information on the
various type-kind- dependent things, like whether ctt_size or
ctt_type is used, is described in the section devoted to each kind.)
* Menu:
* The info word::
* Type indexes and type IDs::
* Type kinds::
* Integer types::
* Floating-point types::
* Slices::
* Pointers typedefs and cvr-quals::
* Arrays::
* Function pointers::
* Enums::
* Structs and unions::
* Forward declarations::

File: ctf-spec.info, Node: The info word, Next: Type indexes and type IDs, Up: The type section
2.3.1 The info word, ctt_info
-----------------------------
The info word is a bitfield split into three parts. From MSB to LSB:
Bit offset Name Description
------------------------------------------------------------------------------------------
2631 kind Type kind: *note Type kinds::.
25 isroot 1 if this type is visible to name lookup
024 vlen Length of variable-length data for this type (some kinds only).
The variable-length data directly follows the ctf_type_t or
ctf_stype_t. This is a kind-dependent array length value,
not a length in bytes. Some kinds have no variable-length
data, or fixed-size variable-length data, and do not use this
value.
The most mysterious of these is undoubtedly isroot. This indicates
whether types with names (nonzero ctt_name) are visible to name
lookup: if zero, this type is considered a “non-root type” and you cant
look it up by name at all. Multiple types with the same name in the
same C namespace (struct, union, enum, other) can exist in a single
dictionary, but only one of them may have a nonzero value for isroot.
libctf validates this at open time and refuses to open dictionaries
that violate this constraint.
Historically, this feature was introduced for the encoding of
bitfields (*note Integer types::): for instance, int bitfields will all
be named int with different widths or offsets, but only the full-width
one at offset zero is wanted when you look up the type named int.
With the introduction of slices (*note Slices::) as a more general
bitfield encoding mechanism, this is less important, but we still use
non-root types to handle conflicts if the linker API is used to fuse
multiple translation units into one dictionary and those translation
units contain types with the same name and conflicting definitions. (We
do not discuss this further here, because the linker never does this:
only specialized type mergers do, like that used for the Linux kernel.
The libctf documentation will describe this in more detail.)
The CTF_TYPE_INFO macro can be used to compose an info word from a
kind, isroot, and vlen; CTF_V2_INFO_KIND, CTF_V2_INFO_ISROOT
and CTF_V2_INFO_VLEN pick it apart again.

File: ctf-spec.info, Node: Type indexes and type IDs, Next: Type kinds, Prev: The info word, Up: The type section
2.3.2 Type indexes and type IDs
-------------------------------
Types are referred to within the CTF file via “type IDs”. A type ID is
a number from 0 to 2^32, from a space divided in half. Types 2^31-1 and
below are in the “parent range”: these IDs are used for dictionaries
that have not had any other dictionary ctf_imported into it as a
parent. Both completely standalone dictionaries and parent dictionaries
with children hanging off them have types in this range. Types 2^31 and
above are in the “child range”: only types in child dictionaries are in
this range.
These IDs appear in ctf_type_t.ctt_type (*note The type section::),
but the types themselves have no visible ID: quite intentionally,
because adding an ID uses space, and every ID is different so they dont
compress well. The IDs are implicit: at open time, the consumer walks
through the entire type section and counts the types in the type
section. The type section is an array of variable-length elements, so
each entry could be considered as having an index, starting from 1. We
count these indexes and associate each with its corresponding
ctf_type_t or ctf_stype_t.
Lookups of types with IDs in the parent space look in the parent
dictionary if this dictionary has one associated with it; lookups of
types with IDs in the child space error out if the dictionary does not
have a parent, and otherwise convert the ID into an index by shaving off
the top bit and look up the index in the child.
These properties mean that the same dictionary can be used as a
parent of child dictionaries and can also be used directly with no
children at all, but a dictionary created as a child dictionary must
always be associated with a parent — usually, the same parent — because
its references to its own types have the high bit turned on and this is
only flipped off again if this is a child dictionary. (This is not a
problem, because if you _dont_ associate the child with a parent, any
references within it to its parent types will fail, and there are almost
certain to be many such references, or why is it a child at all?)
This does mean that consumers should keep a close eye on the
distinction between type IDs and type indexes: if you mix them up,
everything will appear to work as long as youre only using parent
dictionaries or standalone dictionaries, but as soon as you start using
children, everything will fail horribly.
Type index zero, and type ID zero, are used to indicate that this
type cannot be represented in CTF as currently constituted: they are
emitted by the compiler, but all type chains that terminate in the
unknown type are erased at link time (structure fields that use them
just vanish, etc). So you will probably never see a use of type zero
outside the symtypetab sections, where they serve as sentinels of sorts,
to indicate symbols with no associated type.
The macros CTF_V2_TYPE_TO_INDEX and CTF_V2_INDEX_TO_TYPE may help
in translation between types and indexes: CTF_V2_TYPE_ISPARENT and
CTF_V2_TYPE_ISCHILD can be used to tell whether a given ID is in the
parent or child range.
It is quite possible and indeed common for type IDs to point forward
in the dictionary, as well as backward.

File: ctf-spec.info, Node: Type kinds, Next: Integer types, Prev: Type indexes and type IDs, Up: The type section
2.3.3 Type kinds
----------------
Every type in CTF is of some “kind”. Each kind is some variety of C
type: all structures are a single kind, as are all unions, all pointers,
all arrays, all integers regardless of their bitfield width, etc. The
kind of a type is given in the kind field of the ctt_info word
(*note The info word::).
The space of type kinds is only a quarter full so far, so there is
plenty of room for expansion. It is likely that in future versions of
the file format, types with smaller kinds will be more efficiently
encoded than types with larger kinds, so their numerical value will
actually start to matter in future. (So these IDs will probably change
their numerical values in a later release of this format, to move more
frequently-used kinds like structures and cv-quals towards the top of
the space, and move rarely-used kinds like integers downwards. Yes,
integers are rare: how many kinds of int are there in a program?
Theyre just very frequently _referenced_.)
Heres the set of kinds so far. Each kind has a #define associated
with it, also given here.
Kind Macro Purpose
----------------------------------------------------------------------------------------
0 CTF_K_UNKNOWN Indicates a type that cannot be represented in CTF, or that
is being skipped. It is very similar to type ID 0, except
that you can have _multiple_, distinct types of kind
CTF_K_UNKNOWN.
1 CTF_K_INTEGER An integer type. *Note Integer types::.
2 CTF_K_FLOAT A floating-point type. *Note Floating-point types::.
3 CTF_K_POINTER A pointer. *Note Pointers typedefs and cvr-quals::.
4 CTF_K_ARRAY An array. *Note Arrays::.
5 CTF_K_FUNCTION A function pointer. *Note Function pointers::.
6 CTF_K_STRUCT A structure. *Note Structs and unions::.
7 CTF_K_UNION A union. *Note Structs and unions::.
8 CTF_K_ENUM An enumerated type. *Note Enums::.
9 CTF_K_FORWARD A forward. *Note Forward declarations::.
10 CTF_K_TYPEDEF A typedef. *Note Pointers typedefs and cvr-quals::.
11 CTF_K_VOLATILE A volatile-qualified type.
*Note Pointers typedefs and cvr-quals::.
12 CTF_K_CONST A const-qualified type.
*Note Pointers typedefs and cvr-quals::.
13 CTF_K_RESTRICT A restrict-qualified type.
*Note Pointers typedefs and cvr-quals::.
14 CTF_K_SLICE A slice, a change of the bit-width or offset of some other
type. *Note Slices::.
Now we cover all type kinds in turn. Some are more complicated than
others.

File: ctf-spec.info, Node: Integer types, Next: Floating-point types, Prev: Type kinds, Up: The type section
2.3.4 Integer types
-------------------
Integral types are all represented as types of kind CTF_K_INTEGER.
These types fill out ctt_size in the ctf_stype_t with the size in
bytes of the integral type in question. They are always represented by
ctf_stype_t, never ctf_type_t. Their variable-length data is one
uint32_t in length: vlen in the info word should be disregarded and
is always zero.
The variable-length data for integers has multiple items packed into
it much like the info word does.
Bit offset Name Description
-----------------------------------------------------------------------------------
2431 Encoding The desired display representation of this integer. You
can extract this field with the CTF_INT_ENCODING
macro. See below.
1623 Offset The offset of this integral type in bits from the start
of its enclosing structure field, adjusted for
endianness: *note Structs and unions::. You can extract
this field with the CTF_INT_OFFSET macro.
015 Bit-width The width of this integral type in bits. You can
extract this field with the CTF_INT_BITS macro.
If you choose, bitfields can be represented using the things above as
a sort of integral type with the isroot bit flipped off and the offset
and bits values set in the vlen word: you can populate it with the
CTF_INT_DATA macro. (But it may be more convenient to represent them
using slices of a full-width integer: *note Slices::.)
Integers that are bitfields usually have a ctt_size rounded up to
the nearest power of two in bytes, for natural alignment (e.g. a 17-bit
integer would have a ctt_size of 4). However, not all types are
naturally aligned on all architectures: packed structures may in theory
use integral bitfields with different ctt_size, though this is rarely
observed.
The “encoding” for integers is a bit-field comprised of the values
below, which consumers can use to decide how to display values of this
type:
Offset Name Description
--------------------------------------------------------------------------------------------------------
0x01 CTF_INT_SIGNED If set, this is a signed int: if false, unsigned.
0x02 CTF_INT_CHAR If set, this is a char type. It is platform-dependent whether unadorned
char is signed or not: the CTF_CHAR macro produces an integral type
suitable for the definition of char on this platform.
0x04 CTF_INT_BOOL If set, this is a boolean type. (It is theoretically possible to turn
this and CTF_INT_CHAR on at the same time, but it is not clear what
this would mean.)
0x08 CTF_INT_VARARGS If set, this is a varargs-promoted value in a K&R function definition.
This is not currently produced or consumed by anything that we know of:
it is set aside for future use.
The GCC “Complex int” and fixed-point extensions are not yet
supported: references to such types will be emitted as type 0.

File: ctf-spec.info, Node: Floating-point types, Next: Slices, Prev: Integer types, Up: The type section
2.3.5 Floating-point types
--------------------------
Floating-point types are all represented as types of kind CTF_K_FLOAT.
Like integers, These types fill out ctt_size in the ctf_stype_t with
the size in bytes of the floating-point type in question. They are
always represented by ctf_stype_t, never ctf_type_t.
This part of CTF shows many rough edges in the more obscure corners
of floating-point handling, and is likely to change in format v4.
The variable-length data for floats has multiple items packed into it
just like integers do:
Bit offset Name Description
-------------------------------------------------------------------------------------------
2431 Encoding The desired display representation of this float. You can
extract this field with the CTF_FP_ENCODING macro. See below.
1623 Offset The offset of this floating-point type in bits from the start of
its enclosing structure field, adjusted for endianness:
*note Structs and unions::. You can extract this field with the
CTF_FP_OFFSET macro.
015 Bit-width The width of this floating-point type in bits. You can extract
this field with the CTF_FP_BITS macro.
The purpose of the floating-point offset and bit-width is somewhat
opaque, since there are no such things as floating-point bitfields in C:
the bit-width should be filled out with the full width of the type in
bits, and the offset should always be zero. It is likely that these
fields will go away in the future. As with integers, you can use
CTF_FP_DATA to assemble one of these vlen items from its component
parts.
The “encoding” for floats is not a bitfield but a simple value
indicating the display representation. Many of these are unused, relate
to Solaris-specific compiler extensions, and will be recycled in future:
some are unused and will become used in future.
Offset Name Description
----------------------------------------------------------------------------------------------
1 CTF_FP_SINGLE This is a single-precision IEEE 754 float.
2 CTF_FP_DOUBLE This is a double-precision IEEE 754 double.
3 CTF_FP_CPLX This is a Complex float.
4 CTF_FP_DCPLX This is a Complex double.
5 CTF_FP_LDCPLX This is a Complex long double.
6 CTF_FP_LDOUBLE This is a long double.
7 CTF_FP_INTRVL This is a float interval type, a Solaris-specific extension.
Unused: will be recycled.
8 CTF_FP_DINTRVL This is a double interval type, a Solaris-specific
extension. Unused: will be recycled.
9 CTF_FP_LDINTRVL This is a long double interval type, a Solaris-specific
extension. Unused: will be recycled.
10 CTF_FP_IMAGRY This is a the imaginary part of a Complex float. Not
currently generated. May change.
11 CTF_FP_DIMAGRY This is a the imaginary part of a Complex double. Not
currently generated. May change.
12 CTF_FP_LDIMAGRY This is a the imaginary part of a Complex long double. Not
currently generated. May change.
The use of the complex floating-point encodings is obscure: it is
possible that CTF_FP_CPLX is meant to be used for only the real part
of complex types, and CTF_FP_IMAGRY et al for the imaginary part but
for now, we are emitting CTF_FP_CPLX to cover the entire type, with no
way to get at its constituent parts. There appear to be no uses of
these encodings anywhere, so they are quite likely to change
incompatibly in future.

File: ctf-spec.info, Node: Slices, Next: Pointers typedefs and cvr-quals, Prev: Floating-point types, Up: The type section
2.3.6 Slices
------------
Slices, with kind CTF_K_SLICE, are an unusual CTF construct: they do
not directly correspond to any C type, but are a way to model other
types in a more convenient fashion for CTF generators.
A slice is like a pointer or other reference type in that they are
always represented by ctf_stype_t: but unlike pointers and other
reference types, they populate the ctt_size field just like integral
types do, and come with an attached encoding and transform the encoding
of the underlying type. The underlying type is described in the
variable-length data, similarly to structure and union fields: see
below. Requests for the type size should also chase down to the
referenced type.
Slices are always nameless: ctt_name is always zero for them.
(The libctf API behaviour is unusual as well, and justifies the
existence of slices: ctf_type_kind never returns CTF_K_SLICE but
always the underlying type kind, so that consumers never need to know
about slices: they can tell if an apparent integer is actually a slice
if they need to by calling ctf_type_reference, which will uniquely
return the underlying integral type rather than erroring out with
ECTF_NOTREF if this is actually a slice. So slices act just like an
integer with an encoding, but more closely mirror DWARF and other
debugging information formats by allowing CTF file creators to represent
a bitfield as a slice of an underlying integral type.)
The vlen in the info word for a slice should be ignored and is always
zero. The variable-length data for a slice is a single ctf_slice_t:
typedef struct ctf_slice
{
uint32_t cts_type;
unsigned short cts_offset;
unsigned short cts_bits;
} ctf_slice_t;
Offset Name Description
----------------------------------------------------------------------------------------
0x0 uint32_t cts_type The type this slice is a slice of. Must be an
integral type (or a floating-point type, but
this nonsensical option will go away in v4.)
0x4 unsigned short cts_offset The offset of this integral type in bits from
the start of its enclosing structure field,
adjusted for endianness:
*note Structs and unions::. Identical
semantics to the CTF_INT_OFFSET field:
*note Integer types::. This field is much too
long, because the maximum possible offset of
an integral type would easily fit in a char:
this field is bigger just for the sake of
alignment. This will change in v4.
0x6 unsigned short cts_bits The bit-width of this integral type.
Identical semantics to the CTF_INT_BITS
field: *note Integer types::. As above, this
field is really too large and will shrink in
v4.

File: ctf-spec.info, Node: Pointers typedefs and cvr-quals, Next: Arrays, Prev: Slices, Up: The type section
2.3.7 Pointers, typedefs, and cvr-quals
---------------------------------------
Pointers, typedefs, and const, volatile and restrict qualifiers
are represented identically except for their type kind (though they may
be treated differently by consuming libraries like libctf, since
pointers affect assignment-compatibility in ways cvr-quals do not, and
they may have different alignment requirements, etc).
All of these are represented by ctf_stype_t, have no variable data
at all, and populate ctt_type with the type ID of the type they point
to. These types can stack: a CTF_K_RESTRICT can point to a
CTF_K_CONST which can point to a CTF_K_POINTER etc.
They are all unnamed: ctt_name is 0.
The size of CTF_K_POINTER is derived from the data model (*note
Data models::), i.e. in practice, from the target machine ABI, and is
not explicitly represented. The size of other kinds in this set should
be determined by chasing ctf_types as necessary until a
non-typedef/const/volatile/restrict is found, and using that.

File: ctf-spec.info, Node: Arrays, Next: Function pointers, Prev: Pointers typedefs and cvr-quals, Up: The type section
2.3.8 Arrays
------------
Arrays are encoded as types of kind CTF_K_ARRAY in a ctf_stype_t.
Both size and kind for arrays are zero. The variable-length data is a
ctf_array_t: vlen in the info word should be disregarded and is
always zero.
typedef struct ctf_array
{
uint32_t cta_contents;
uint32_t cta_index;
uint32_t cta_nelems;
} ctf_array_t;
Offset Name Description
----------------------------------------------------------------------------------------
0x0 uint32_t cta_contents The type of the array elements: a type ID.
0x4 uint32_t cta_index The type of the array index: a type ID of an
integral type. If this is a variable-length
array, the index type ID will be 0 (but the
actual index type of this array is probably
int). Probably redundant and may be
dropped in v4.
0x8 uint32_t cta_nelems The number of array elements. 0 for VLAs,
and also for the historical variety of VLA
which has explicit zero dimensions (which
will have a nonzero cta_index.)
The size of an array can be computed by simple multiplication of the
size of the cta_contents type by the cta_nelems.

File: ctf-spec.info, Node: Function pointers, Next: Enums, Prev: Arrays, Up: The type section
2.3.9 Function pointers
-----------------------
Function pointers are explicitly represented in the CTF type section by
a type of kind CTF_K_FUNCTION, always encoded with a ctf_stype_t.
The ctt_type is the function return type ID. The vlen in the info
word is the number of arguments, each of which is a type ID, a
uint32_t: if the last argument is 0, this is a varargs function and
the number of arguments is one less than indicated by the vlen.
If the number of arguments is odd, a single uint32_t of padding is
inserted to maintain alignment.

File: ctf-spec.info, Node: Enums, Next: Structs and unions, Prev: Function pointers, Up: The type section
2.3.10 Enums
------------
Enumerated types are represented as types of kind CTF_K_ENUM in a
ctf_stype_t. The ctt_size is always the size of an int from the
data model (enum bitfields are implemented via slices). The vlen is a
count of enumerations, each of which is represented by a ctf_enum_t in
the vlen:
typedef struct ctf_enum
{
uint32_t cte_name;
int32_t cte_value;
} ctf_enum_t;
Offset Name Description
------------------------------------------------------------------------
0x0 uint32_t cte_name Strtab offset of the enumeration name.
Must not be 0.
0x4 int32_t cte_value The enumeration value.
Enumeration values larger than 2^32 are not yet supported and are
omitted from the enumeration. (v4 will lift this restriction by
encoding the value differently.)
Forward declarations of enums are not implemented with this kind:
*note Forward declarations::.
Enumerated type names, as usual in C, go into their own namespace,
and do not conflict with non-enums, structs, or unions with the same
name.

File: ctf-spec.info, Node: Structs and unions, Next: Forward declarations, Prev: Enums, Up: The type section
2.3.11 Structs and unions
-------------------------
Structures and unions are represnted as types of kind CTF_K_STRUCT and
CTF_K_UNION: their representation is otherwise identical, and it is
perfectly allowed for “structs” to contain overlapping fields etc, so we
will treat them together for the rest of this section.
They fill out ctt_size, and use ctf_type_t in preference to
ctf_stype_t if the structure size is greater than CTF_MAX_SIZE
(0xfffffffe).
The vlen for structures and unions is a count of structure fields,
but the type used to represent a structure field (and thus the size of
the variable-length array element representing the type) depends on the
size of the structure: truly huge structures, greater than
CTF_LSTRUCT_THRESH bytes in length, use a different type.
(CTF_LSTRUCT_THRESH is 536870912, so such structures are vanishingly
rare: in v4, this representation will change somewhat for greater
compactness. Its inherited from v1, where the limits were much lower.)
Most structures can get away with using ctf_member_t:
typedef struct ctf_member_v2
{
uint32_t ctm_name;
uint32_t ctm_offset;
uint32_t ctm_type;
} ctf_member_t;
Huge structures that are represented by ctf_type_t rather than
ctf_stype_t have to use ctf_lmember_t, which splits the offset as
ctf_type_t splits the size:
typedef struct ctf_lmember_v2
{
uint32_t ctlm_name;
uint32_t ctlm_offsethi;
uint32_t ctlm_type;
uint32_t ctlm_offsetlo;
} ctf_lmember_t;
Heres what the fields of ctf_member mean:
Offset Name Description
---------------------------------------------------------------------------------------------------------
0x00 uint32_t ctm_name Strtab offset of the field name.
0x04 uint32_t ctm_offset The offset of this field _in bits_. (Usually, for bitfields, this is
machine-word-aligned and the individual field has an offset in bits,
but the format allows for the offset to be encoded in bits here.)
0x08 uint32_t ctm_type The type ID of the type of the field.
Heres what the fields of the very similar ctf_lmember mean:
Offset Name Description
------------------------------------------------------------------------------------------------------------
0x00 uint32_t ctlm_name Strtab offset of the field name.
0x04 uint32_t ctlm_offsethi The high 32 bits of the offset of this field in bits.
0x08 uint32_t ctlm_type The type ID of the type of the field.
0x0c uint32_t ctlm_offsetlo The low 32 bits of the offset of this field in bits.
Macros CTF_LMEM_OFFSET, CTF_OFFSET_TO_LMEMHI and
CTF_OFFSET_TO_LMEMLO serve to extract and install the values of the
ctlm_offset fields, much as with the split size fields in
ctf_type_t.
Unnamed structure and union fields are simply implemented by
collapsing the unnamed fields members into the containing structure or
union: this does mean that a structure containing an unnamed union can
end up being a “structure” with multiple members at the same offset. (A
future format revision may collapse CTF_K_STRUCT and CTF_K_UNION
into the same kind and decide among them based on whether their members
do in fact overlap.)
Structure and union type names, as usual in C, go into their own
namespace, just as enum type names do.
Forward declarations of structures and unions are not implemented
with this kind: *note Forward declarations::.

File: ctf-spec.info, Node: Forward declarations, Prev: Structs and unions, Up: The type section
2.3.12 Forward declarations
---------------------------
When the compiler encounters a forward declaration of a struct, union,
or enum, it emits a type of kind CTF_K_FORWARD. If it later
encounters a non- forward declaration of the same thing, it marks the
forward as non-root-visible: before link time, therefore,
non-root-visible forwards indicate that a non-forward is coming.
After link time, forwards are fused with their corresponding
non-forwards by the deduplicator where possible. They are kept if there
is no non-forward definition (maybe its not visible from any TU at all)
or if multiple conflicting structures with the same name might match
it. Otherwise, all other forwards are converted to structures, unions,
or enums as appropriate, even across TUs if only one structure could
correspond to the forward (after all, all types across all TUs land in
the same dictionary unless they conflict, so promoting forwards to their
concrete type seems most helpful).
A forward has a rather strange representation: it is encoded with a
ctf_stype_t but the ctt_type is populated not with a type (if its a
forward, we dont have an underlying type yet: if we did, wed have
promoted it and this wouldnt be a forward any more) but with the kind
of the forward. This means that we can distinguish forwards to structs,
enums and unions reliably and ensure they land in the appropriate
namespace even before the actual struct, union or enum is found.

File: ctf-spec.info, Node: The symtypetab sections, Next: The variable section, Prev: The type section, Up: CTF dictionaries
2.4 The symtypetab sections
===========================
These are two very simple sections with identical formats, used by
consumers to map from ELF function and data symbols directly to their
types. So they are usually populated only in CTF sections that are
embedded in ELF objects.
Their format is very simple: an array of type IDs. Which symbol each
type ID corresponds to depends on whether the optional _index section_
associated with this symtypetab section has any content.
If the index section is nonempty, it is an array of uint32_t string
table offsets, each giving the name of the symbol whose type is at the
same offset in the corresponding non-index section: users can look up
symbols in such a table by name. The index section and corresponding
symtypetab section is usually ASCIIbetically sorted (indicated by the
CTF_F_IDXSORTED flag in the header): if its sorted, it can be
bsearched for a symbol name rather than having to use a slower linear
search.
If the data object index section is empty, the entries in the data
object and function info sections are associated 1:1 with ELF symbols of
type STT_OBJECT (for data object) or STT_FUNC (for function info)
with a nonzero value: the linker shuffles the symtypetab sections to
correspond with the order of the symbols in the ELF file. Symbols with
no name, undefined symbols and symbols named “_START_” and “_END_
are skipped and never appear in either section. Symbols that have no
corresponding type are represented by type ID 0. The section may have
fewer entries than the symbol table, in which case no later entries have
associated types. This format is more compact than an indexed form if
most entries have types (since there is no need to record any symbol
names), but if the producer and consumer disagree even slightly about
which symbols are omitted, the types of all further symbols will be
wrong!
The compiler always emits indexed symtypetab tables, because there is
no symbol table yet. The linker will always have to read them all in
and always works through them from start to end, so there is no benefit
having the compiler sort them either. The linker (actually, libctfs
linking machinery) will automatically sort unsorted indexed sections,
and convert indexed sections that contain a lot of pads into the more
compact, unindexed form.
If child dicts are in use, only symbols that use types actually
mentioned in the child appear in the childs symtypetab: symbols that
use only types in the parent appear in the parents symtypetab instead.
So the childs symtypetab will almost always be very sparse, and thus
will usually use the indexed form even in fully linked objects. (It is,
of course, impossible for symbols to exist that use types from multiple
child dicts at once, since its impossible to declare a function in C
that uses types that are only visible in two different, disjoint
translation units.)

File: ctf-spec.info, Node: The variable section, Next: The label section, Prev: The symtypetab sections, Up: CTF dictionaries
2.5 The variable section
========================
The variable section is a simple array mapping names (strtab entries) to
type IDs, intended to provide a replacement for the data object section
in dynamic situations in which there is no static ELF strtab but the
consumer instead hands back names. The section is sorted into
ASCIIbetical order by name for rapid lookup, like the CTF archive name
table.
The section is an array of these structures:
typedef struct ctf_varent
{
uint32_t ctv_name;
uint32_t ctv_type;
} ctf_varent_t;
Offset Name Description
-----------------------------------------------------------
0x00 uint32_t ctv_name Strtab offset of the name
0x04 uint32_t ctv_type Type ID of this type
There is no analogue of the function info section yet: v4 will
probably drop this section in favour of a way to put both indexed (thus,
named) and nonindexed symbols into the symtypetab sections at the same
time.

File: ctf-spec.info, Node: The label section, Next: The string section, Prev: The variable section, Up: CTF dictionaries
2.6 The label section
=====================
The label section is a currently-unused facility allowing the tiling of
the type space with names taken from the strtab. The section is an
array of these structures:
typedef struct ctf_lblent
{
uint32_t ctl_label;
uint32_t ctl_type;
} ctf_lblent_t;
Offset Name Description
-------------------------------------------------------------
0x00 uint32_t ctl_label Strtab offset of the label
0x04 uint32_t ctl_type Type ID of the last type
covered by this label
Semantics will be attached to labels soon, probably in v4 (the plan
is to use them to allow multiple disjoint namespaces in a single CTF
file, removing many uses of CTF archives, in particular in the .ctf
section in ELF objects).

File: ctf-spec.info, Node: The string section, Next: Data models, Prev: The label section, Up: CTF dictionaries
2.7 The string section
======================
This section is a simple ELF-format strtab, starting with a zero byte
(thus ensuring that the string with offset 0 is the null string, as
assumed elsewhere in this spec). The strtab is usually ASCIIbetically
sorted to somewhat improve compression efficiency.
Where the strtab is unusual is the _references_ to it. CTF has two
string tables, the internal strtab and an external strtab associated
with the CTF dictionary at open time: usually, this is the ELF dynamic
strtab (.dynstr) of a CTF dictionary embedded in an ELF file. We
distinguish between these strtabs by the most significant bit, bit 31,
of the 32-bit strtab references: if it is 0, the offset is in the
internal strtab: if 1, the offset is in the external strtab.
There is a bug workaround in this area: in format v3 (the first
version to have working support for external strtabs), the external
strtab is .strtab unless the CTF_F_DYNSTR flag is set on the
dictionary (*note CTF file-wide flags::). Format v4 will introduce a
header field that explicitly names the external strtab, making this flag
unnecessary.

File: ctf-spec.info, Node: Data models, Next: Limits of CTF, Prev: The string section, Up: CTF dictionaries
2.8 Data models
===============
The data model is a simple integer which indicates the ABI in use on
this platform. Right now, it is very simple, distinguishing only
between 32- and 64-bit types: a model of 1 indicates ILP32, 2 indicats
LP64. The mapping from ABI integer to type sizes is hardwired into
libctf: currently, we use this to hardwire the size of pointers,
function pointers, and enumerated types,
This is a very kludgy corner of CTF and will probably be replaced
with explicit header fields to record this sort of thing in future.

File: ctf-spec.info, Node: Limits of CTF, Prev: Data models, Up: CTF dictionaries
2.9 Limits of CTF
=================
The following limits are imposed by various aspects of CTF version 3:
CTF_MAX_TYPE
Maximum type identifier (maximum number of types accessible with
parent and child containers in use): 0xfffffffe
CTF_MAX_PTYPE
Maximum type identifier in a parent dictioanry: maximum number of
types in any one dictionary: 0x7fffffff
CTF_MAX_NAME
Maximum offset into a string table: 0x7fffffff
CTF_MAX_VLEN
Maximum number of members in a struct, union, or enum: maximum
number of function args: 0xffffff
CTF_MAX_SIZE
Maximum size of a ctf_stype_t in bytes before we fall back to
ctf_type_t: 0xfffffffe bytes
Other maxima without associated macros:
• Maximum value of an enumerated type: 2^32
• Maximum size of an array element: 2^32
These maxima are generally considered to be too low, because C
programs can and do exceed them: they will be lifted in format v4.

File: ctf-spec.info, Node: Index, Prev: CTF dictionaries, Up: Top
Index
*****
[index]
* Menu:
* alignment: CTF Preamble. (line 33)
* archive, CTF archive: CTF archive. (line 6)
* Arrays: Arrays. (line 6)
* bool: Integer types. (line 6)
* Bug workarounds, CTF_F_DYNSTR: The symtypetab sections.
(line 6)
* Bug workarounds, CTF_F_DYNSTR <1>: The string section. (line 19)
* char: Integer types. (line 6)
* Child range: Type indexes and type IDs.
(line 6)
* Complex, double: Floating-point types. (line 6)
* Complex, float: Floating-point types. (line 6)
* Complex, signed double: Floating-point types. (line 6)
* Complex, signed float: Floating-point types. (line 6)
* Complex, unsigned double: Floating-point types. (line 6)
* Complex, unsigned float: Floating-point types. (line 6)
* const: Pointers typedefs and cvr-quals.
(line 6)
* cta_contents: Arrays. (line 20)
* cta_index: Arrays. (line 22)
* cta_nelems: Arrays. (line 29)
* cte_name: Enums. (line 21)
* cte_value: Enums. (line 24)
* CTF header: CTF header. (line 6)
* CTF versions, versions: CTF Preamble. (line 46)
* ctfa_ctfs: CTF archive. (line 76)
* ctfa_magic: CTF archive. (line 63)
* CTFA_MAGIC: CTF archive. (line 64)
* ctfa_model: CTF archive. (line 66)
* ctfa_names: CTF archive. (line 72)
* ctfa_nfiles: CTF archive. (line 71)
* ctf_archive_modent_t: CTF archive. (line 83)
* ctf_archive_modent_t, ctf_offset: CTF archive. (line 88)
* ctf_archive_modent_t, name_offset: CTF archive. (line 86)
* ctf_array_t: Arrays. (line 18)
* ctf_array_t, cta_contents: Arrays. (line 20)
* ctf_array_t, cta_index: Arrays. (line 22)
* ctf_array_t, cta_nelems: Arrays. (line 29)
* CTF_CHAR: Integer types. (line 53)
* ctf_enum_t: Enums. (line 18)
* ctf_enum_t, cte_name: Enums. (line 21)
* ctf_enum_t, cte_value: Enums. (line 24)
* CTF_FP_BITS: Floating-point types. (line 28)
* CTF_FP_CPLX: Floating-point types. (line 47)
* CTF_FP_DCPLX: Floating-point types. (line 48)
* CTF_FP_DIMAGRY: Floating-point types. (line 60)
* CTF_FP_DINTRVL: Floating-point types. (line 54)
* CTF_FP_DOUBLE: Floating-point types. (line 46)
* CTF_FP_ENCODING: Floating-point types. (line 21)
* CTF_FP_IMAGRY: Floating-point types. (line 58)
* CTF_FP_INTRVL: Floating-point types. (line 52)
* CTF_FP_LDCPLX: Floating-point types. (line 49)
* CTF_FP_LDIMAGRY: Floating-point types. (line 62)
* CTF_FP_LDINTRVL: Floating-point types. (line 56)
* CTF_FP_LDOUBLE: Floating-point types. (line 50)
* CTF_FP_OFFSET: Floating-point types. (line 25)
* CTF_FP_SINGLE: Floating-point types. (line 45)
* CTF_F_COMPRESS: CTF file-wide flags. (line 17)
* CTF_F_DYNSTR: CTF file-wide flags. (line 21)
* CTF_F_DYNSTR <1>: The symtypetab sections.
(line 6)
* CTF_F_DYNSTR <2>: The string section. (line 19)
* CTF_F_IDXSORTED: CTF file-wide flags. (line 20)
* CTF_F_IDXSORTED <1>: The symtypetab sections.
(line 6)
* CTF_F_NEWFUNCINFO: CTF file-wide flags. (line 19)
* ctf_header_t: CTF header. (line 44)
* ctf_header_t, cth_cuname: CTF header. (line 61)
* ctf_header_t, cth_flags: CTF Preamble. (line 30)
* ctf_header_t, cth_funcidxoff: CTF header. (line 82)
* ctf_header_t, cth_funcoff: CTF header. (line 74)
* ctf_header_t, cth_lbloff: CTF header. (line 66)
* ctf_header_t, cth_magic: CTF Preamble. (line 24)
* ctf_header_t, cth_objtidxoff: CTF header. (line 78)
* ctf_header_t, cth_objtoff: CTF header. (line 70)
* ctf_header_t, cth_parlabel: CTF header. (line 49)
* ctf_header_t, cth_parname: CTF header. (line 55)
* ctf_header_t, cth_preamble: CTF header. (line 47)
* ctf_header_t, cth_strlen: CTF header. (line 98)
* ctf_header_t, cth_stroff: CTF header. (line 95)
* ctf_header_t, cth_typeoff: CTF header. (line 91)
* ctf_header_t, cth_varoff: CTF header. (line 87)
* ctf_header_t, cth_version: CTF Preamble. (line 28)
* ctf_id_t: Type indexes and type IDs.
(line 6)
* CTF_INT_BITS: Integer types. (line 28)
* CTF_INT_BOOL: Integer types. (line 57)
* CTF_INT_CHAR: Integer types. (line 53)
* CTF_INT_DATA: Integer types. (line 34)
* CTF_INT_DATA <1>: Floating-point types. (line 36)
* CTF_INT_ENCODING: Integer types. (line 20)
* CTF_INT_OFFSET: Integer types. (line 25)
* CTF_INT_SIGNED: Integer types. (line 49)
* CTF_K_CONST: Pointers typedefs and cvr-quals.
(line 6)
* CTF_K_ENUM: Enums. (line 6)
* CTF_K_FLOAT: Floating-point types. (line 6)
* CTF_K_FORWARD: Forward declarations. (line 6)
* CTF_K_INTEGER: Integer types. (line 6)
* CTF_K_POINTER: Pointers typedefs and cvr-quals.
(line 6)
* CTF_K_RESTRICT: Pointers typedefs and cvr-quals.
(line 6)
* CTF_K_SLICE: Slices. (line 6)
* CTF_K_STRUCT: Structs and unions. (line 6)
* CTF_K_TYPEDEF: Pointers typedefs and cvr-quals.
(line 6)
* CTF_K_UNION: Structs and unions. (line 6)
* CTF_K_UNKNOWN: Type kinds. (line 31)
* CTF_K_VOLATILE: Pointers typedefs and cvr-quals.
(line 6)
* ctf_lblent_t: The label section. (line 16)
* ctf_lblent_t, ctl_label: The label section. (line 19)
* ctf_lblent_t, ctl_type: The label section. (line 20)
* ctf_lmember_t: Structs and unions. (line 59)
* ctf_lmember_t, ctlm_name: Structs and unions. (line 61)
* ctf_lmember_t, ctlm_offsethi: Structs and unions. (line 64)
* ctf_lmember_t, ctlm_offsetlo: Structs and unions. (line 68)
* CTF_LSIZE_SENT: The type section. (line 49)
* CTF_LSTRUCT_THRESH: Structs and unions. (line 23)
* CTF_MAGIC: CTF Preamble. (line 25)
* CTF_MAX_LSIZE: Structs and unions. (line 13)
* ctf_member_t: Structs and unions. (line 47)
* ctf_member_t, ctlm_type: Structs and unions. (line 65)
* ctf_member_t, ctm_name: Structs and unions. (line 49)
* ctf_member_t, ctm_offset: Structs and unions. (line 52)
* ctf_member_t, ctm_type: Structs and unions. (line 55)
* ctf_offset: CTF archive. (line 88)
* ctf_preamble_t: CTF Preamble. (line 22)
* ctf_preamble_t, ctp_flags: CTF Preamble. (line 30)
* ctf_preamble_t, ctp_magic: CTF Preamble. (line 24)
* ctf_preamble_t, ctp_version: CTF Preamble. (line 28)
* CTF_SIZE_TO_LSIZE_HI: The type section. (line 79)
* CTF_SIZE_TO_LSIZE_LO: The type section. (line 83)
* ctf_slice_t: Slices. (line 42)
* ctf_slice_t, cts_bits: Slices. (line 59)
* ctf_slice_t, cts_offset: Slices. (line 49)
* ctf_slice_t, cts_type: Slices. (line 44)
* ctf_stype_t: The type section. (line 53)
* ctf_stype_t, ctt_info: The type section. (line 57)
* ctf_stype_t, ctt_size: The type section. (line 62)
* ctf_stype_t, ctt_type: The type section. (line 67)
* CTF_TYPE_INFO: The info word. (line 45)
* CTF_TYPE_LSIZE: The type section. (line 79)
* ctf_type_t: The type section. (line 53)
* ctf_type_t, ctt_info: The type section. (line 57)
* ctf_type_t, ctt_lsizehi: The type section. (line 76)
* ctf_type_t, ctt_lsizelo: The type section. (line 82)
* ctf_type_t, ctt_size: The type section. (line 62)
* CTF_V2_INDEX_TO_TYPE: Type indexes and type IDs.
(line 58)
* CTF_V2_INFO_ISROOT: The info word. (line 45)
* CTF_V2_INFO_KIND: The info word. (line 45)
* CTF_V2_INFO_VLEN: The info word. (line 45)
* CTF_V2_TYPE_ISCHILD: Type indexes and type IDs.
(line 58)
* CTF_V2_TYPE_ISPARENT: Type indexes and type IDs.
(line 58)
* CTF_V2_TYPE_TO_INDEX: Type indexes and type IDs.
(line 58)
* ctf_varent_t: The variable section. (line 21)
* ctf_varent_t, ctv_name: The variable section. (line 24)
* ctf_varent_t, ctv_type: The variable section. (line 26)
* CTF_VERSION_3: CTF Preamble. (line 46)
* cth_cuname: CTF header. (line 61)
* cth_flags: CTF Preamble. (line 30)
* cth_funcidxoff: CTF header. (line 82)
* cth_funcoff: CTF header. (line 74)
* cth_lbloff: CTF header. (line 66)
* cth_magic: CTF Preamble. (line 24)
* cth_objtidxoff: CTF header. (line 78)
* cth_objtoff: CTF header. (line 70)
* cth_parlabel: CTF header. (line 49)
* cth_parname: CTF header. (line 55)
* cth_preamble: CTF header. (line 47)
* cth_strlen: CTF header. (line 98)
* cth_stroff: CTF header. (line 95)
* cth_typeoff: CTF header. (line 91)
* cth_varoff: CTF header. (line 87)
* cth_version: CTF Preamble. (line 28)
* ctlm_name: Structs and unions. (line 61)
* ctlm_offsethi: Structs and unions. (line 64)
* ctlm_offsetlo: Structs and unions. (line 68)
* ctl_label: The label section. (line 19)
* ctl_type: The label section. (line 20)
* ctm_name: Structs and unions. (line 49)
* ctm_offset: Structs and unions. (line 52)
* ctm_type: Structs and unions. (line 55)
* ctm_type <1>: Structs and unions. (line 65)
* ctp_flags: CTF Preamble. (line 30)
* ctp_flags <1>: CTF Preamble. (line 58)
* ctp_magic: CTF Preamble. (line 24)
* ctp_version: CTF Preamble. (line 28)
* cts_bits: Slices. (line 59)
* cts_offset: Slices. (line 49)
* cts_type: Slices. (line 44)
* ctt_info: The type section. (line 57)
* ctt_lsizehi: The type section. (line 76)
* ctt_lsizelo: The type section. (line 82)
* ctt_name: The type section. (line 55)
* ctt_size: The type section. (line 62)
* ctt_type: The type section. (line 67)
* ctv_name: The variable section. (line 24)
* ctv_type: The variable section. (line 26)
* cvr-quals: Pointers typedefs and cvr-quals.
(line 6)
* Data models: Data models. (line 6)
* Data object index section: The symtypetab sections.
(line 6)
* Data object section: The symtypetab sections.
(line 6)
* dictionary, CTF dictionary: CTF dictionaries. (line 6)
* double: Floating-point types. (line 6)
* endianness: CTF Preamble. (line 37)
* enum: Enums. (line 6)
* enum <1>: Forward declarations. (line 6)
* Enums: Enums. (line 6)
* float: Floating-point types. (line 6)
* Floating-point types: Floating-point types. (line 6)
* Forwards: Forward declarations. (line 6)
* Function info index section: The symtypetab sections.
(line 6)
* Function info section: The symtypetab sections.
(line 6)
* Function pointers: Function pointers. (line 6)
* int: Integer types. (line 6)
* Integer types: Integer types. (line 6)
* Label section: The label section. (line 6)
* libctf, effect of slices: Slices. (line 30)
* Limits: Limits of CTF. (line 6)
* long: Integer types. (line 6)
* long long: Integer types. (line 6)
* name_offset: CTF archive. (line 86)
* Overview: Overview. (line 6)
* Parent range: Type indexes and type IDs.
(line 6)
* Pointers: Pointers typedefs and cvr-quals.
(line 6)
* Pointers, to functions: Function pointers. (line 6)
* restrict: Pointers typedefs and cvr-quals.
(line 6)
* Sections, data object: The symtypetab sections.
(line 6)
* Sections, data object index: The symtypetab sections.
(line 6)
* Sections, function info: The symtypetab sections.
(line 6)
* Sections, function info index: The symtypetab sections.
(line 6)
* Sections, header: CTF header. (line 6)
* Sections, label: The label section. (line 6)
* Sections, string: The string section. (line 6)
* Sections, symtypetab: The symtypetab sections.
(line 6)
* Sections, type: The type section. (line 6)
* Sections, variable: The variable section. (line 6)
* short: Integer types. (line 6)
* signed char: Integer types. (line 6)
* signed double: Floating-point types. (line 6)
* signed float: Floating-point types. (line 6)
* signed int: Integer types. (line 6)
* signed long: Integer types. (line 6)
* signed long long: Integer types. (line 6)
* signed short: Integer types. (line 6)
* Slices: Slices. (line 6)
* Slices, effect on ctf_type_kind: Slices. (line 30)
* Slices, effect on ctf_type_reference: Slices. (line 30)
* String section: The string section. (line 6)
* struct: Structs and unions. (line 6)
* struct <1>: Forward declarations. (line 6)
* struct ctf_archive: CTF archive. (line 61)
* struct ctf_archive, ctfa_ctfs: CTF archive. (line 76)
* struct ctf_archive, ctfa_magic: CTF archive. (line 63)
* struct ctf_archive, ctfa_model: CTF archive. (line 66)
* struct ctf_archive, ctfa_names: CTF archive. (line 72)
* struct ctf_archive, ctfa_nfiles: CTF archive. (line 71)
* struct ctf_archive_modent: CTF archive. (line 83)
* struct ctf_archive_modent, ctf_offset: CTF archive. (line 88)
* struct ctf_archive_modent, name_offset: CTF archive. (line 86)
* struct ctf_array: Arrays. (line 18)
* struct ctf_array, cta_contents: Arrays. (line 20)
* struct ctf_array, cta_index: Arrays. (line 22)
* struct ctf_array, cta_nelems: Arrays. (line 29)
* struct ctf_enum: Enums. (line 18)
* struct ctf_enum, cte_name: Enums. (line 21)
* struct ctf_enum, cte_value: Enums. (line 24)
* struct ctf_header: CTF header. (line 44)
* struct ctf_header, cth_cuname: CTF header. (line 61)
* struct ctf_header, cth_flags: CTF Preamble. (line 30)
* struct ctf_header, cth_funcidxoff: CTF header. (line 82)
* struct ctf_header, cth_funcoff: CTF header. (line 74)
* struct ctf_header, cth_lbloff: CTF header. (line 66)
* struct ctf_header, cth_magic: CTF Preamble. (line 24)
* struct ctf_header, cth_objtidxoff: CTF header. (line 78)
* struct ctf_header, cth_objtoff: CTF header. (line 70)
* struct ctf_header, cth_parlabel: CTF header. (line 49)
* struct ctf_header, cth_parname: CTF header. (line 55)
* struct ctf_header, cth_preamble: CTF header. (line 47)
* struct ctf_header, cth_strlen: CTF header. (line 98)
* struct ctf_header, cth_stroff: CTF header. (line 95)
* struct ctf_header, cth_typeoff: CTF header. (line 91)
* struct ctf_header, cth_varoff: CTF header. (line 87)
* struct ctf_header, cth_version: CTF Preamble. (line 28)
* struct ctf_lblent: The label section. (line 16)
* struct ctf_lblent, ctl_label: The label section. (line 19)
* struct ctf_lblent, ctl_type: The label section. (line 20)
* struct ctf_lmember_v2: Structs and unions. (line 59)
* struct ctf_lmember_v2, ctlm_name: Structs and unions. (line 61)
* struct ctf_lmember_v2, ctlm_offsethi: Structs and unions. (line 64)
* struct ctf_lmember_v2, ctlm_offsetlo: Structs and unions. (line 68)
* struct ctf_lmember_v2, ctlm_type: Structs and unions. (line 65)
* struct ctf_member_v2: Structs and unions. (line 47)
* struct ctf_member_v2, ctm_name: Structs and unions. (line 49)
* struct ctf_member_v2, ctm_offset: Structs and unions. (line 52)
* struct ctf_member_v2, ctm_type: Structs and unions. (line 55)
* struct ctf_preamble: CTF Preamble. (line 22)
* struct ctf_preamble, ctp_flags: CTF Preamble. (line 30)
* struct ctf_preamble, ctp_magic: CTF Preamble. (line 24)
* struct ctf_preamble, ctp_version: CTF Preamble. (line 28)
* struct ctf_slice: Slices. (line 42)
* struct ctf_slice, cts_bits: Slices. (line 59)
* struct ctf_slice, cts_offset: Slices. (line 49)
* struct ctf_slice, cts_type: Slices. (line 44)
* struct ctf_stype: The type section. (line 53)
* struct ctf_stype, ctt_info: The type section. (line 57)
* struct ctf_stype, ctt_size: The type section. (line 62)
* struct ctf_stype, ctt_type: The type section. (line 67)
* struct ctf_type: The type section. (line 53)
* struct ctf_type, ctt_info: The type section. (line 57)
* struct ctf_type, ctt_lsizehi: The type section. (line 76)
* struct ctf_type, ctt_lsizelo: The type section. (line 82)
* struct ctf_type, ctt_size: The type section. (line 62)
* struct ctf_varent: The variable section. (line 21)
* struct ctf_varent, ctv_name: The variable section. (line 24)
* struct ctf_varent, ctv_type: The variable section. (line 26)
* Structures: Structs and unions. (line 6)
* Symtypetab section: The symtypetab sections.
(line 6)
* Type IDs: Type indexes and type IDs.
(line 6)
* Type IDs, ranges: Type indexes and type IDs.
(line 6)
* Type indexes: Type indexes and type IDs.
(line 6)
* Type kinds: Type kinds. (line 6)
* Type section: The type section. (line 6)
* Type, IDs of: Type indexes and type IDs.
(line 6)
* Type, indexes of: Type indexes and type IDs.
(line 6)
* Type, kinds of: Type kinds. (line 6)
* typedef: Pointers typedefs and cvr-quals.
(line 6)
* Typedefs: Pointers typedefs and cvr-quals.
(line 6)
* Types, floating-point: Floating-point types. (line 6)
* Types, integer: Integer types. (line 6)
* Types, slices of integral: Slices. (line 6)
* union: Structs and unions. (line 6)
* union <1>: Forward declarations. (line 6)
* Unions: Structs and unions. (line 6)
* unsigned char: Integer types. (line 6)
* unsigned double: Floating-point types. (line 6)
* unsigned float: Floating-point types. (line 6)
* unsigned int: Integer types. (line 6)
* unsigned long: Integer types. (line 6)
* unsigned long long: Integer types. (line 6)
* unsigned short: Integer types. (line 6)
* Unused bits: Floating-point types. (line 52)
* Unused bits <1>: Floating-point types. (line 54)
* Unused bits <2>: Floating-point types. (line 56)
* Unused bits <3>: Floating-point types. (line 58)
* Unused bits <4>: Floating-point types. (line 60)
* Unused bits <5>: Floating-point types. (line 62)
* Variable section: The variable section. (line 6)
* volatile: Pointers typedefs and cvr-quals.
(line 6)

Tag Table:
Node: Top553
Node: Overview883
Node: CTF archive4220
Node: CTF dictionaries8938
Node: CTF Preamble9355
Node: CTF file-wide flags12041
Node: CTF header13539
Node: The type section19533
Node: The info word24320
Node: Type indexes and type IDs26932
Node: Type kinds30352
Node: Integer types33733
Node: Floating-point types37391
Node: Slices41572
Node: Pointers typedefs and cvr-quals45136
Node: Arrays46355
Node: Function pointers48130
Node: Enums48819
Node: Structs and unions50129
Node: Forward declarations54118
Node: The symtypetab sections55727
Node: The variable section58853
Node: The label section59999
Node: The string section60986
Node: Data models62260
Node: Limits of CTF62933
Node: Index64010

End Tag Table

Local Variables:
coding: utf-8
End: