LLVM Bitcode File Format¶
Abstract¶
This document describes the LLVM bitstream file format and the encoding of the LLVM IR into it.
Overview¶
What is commonly known as the LLVM bitcode file format (also, sometimes anachronistically known as bytecode) is actually two things: a bitstream container format and an encoding of LLVM IR into the container format.
The bitstream format is an abstract encoding of structured data, very similar to XML in some ways. Like XML, bitstream files contain tags, and nested structures, and you can parse the file without having to understand the tags. Unlike XML, the bitstream format is a binary encoding, and unlike XML it provides a mechanism for the file to self-describe “abbreviations”, which are effectively size optimizations for the content.
LLVM IR files may be optionally embedded into a wrapper structure, or in a native object file. Both of these mechanisms make it easy to embed extra data along with LLVM IR files.
This document first describes the LLVM bitstream format, describes the wrapper format, then describes the record structure used by LLVM IR files.
Bitstream Format¶
The bitstream format is literally a stream of bits, with a very simple structure. This structure consists of the following concepts:
A “magic number” that identifies the contents of the stream.
Encoding primitives like variable bit-rate integers.
Blocks, which define nested content.
Data Records, which describe entities within the file.
Abbreviations, which specify compression optimizations for the file.
Note that the llvm-bcanalyzer tool can be used to dump and inspect arbitrary bitstreams, which is very useful for understanding the encoding.
Magic Numbers¶
The first four bytes of a bitstream are used as an application-specific magic number. Generic bitcode tools may look at the first four bytes to determine whether the stream is a known stream type. However, these tools should not determine whether a bitstream is valid based on its magic number alone. New application-specific bitstream formats are being developed all the time; tools should not reject them just because they have a hitherto unseen magic number.
Primitives¶
A bitstream literally consists of a stream of bits, which are read in order starting with the least significant bit of each byte. The stream is made up of a number of primitive values that encode a stream of unsigned integer values. These integers are encoded in two ways: either as Fixed Width Integers or as Variable Width Integers.
Fixed Width Integers¶
Fixed-width integer values have their low bits emitted directly to the file. For example, a 3-bit integer value encodes 1 as 001. Fixed width integers are used when there are a well-known number of options for a field. For example, boolean values are usually encoded with a 1-bit wide integer.
Variable Width Integers¶
Variable-width integer (VBR) values encode values of arbitrary size, optimizing for the case where the values are small. Given a 4-bit VBR field, any 3-bit value (0 through 7) is encoded directly, with the high bit set to zero. Values larger than N-1 bits emit their bits in a series of N-1 bit chunks, where all but the last set the high bit.
For example, the value 30 (0x1E) is encoded as 62 (0b0011’1110) when emitted as a vbr4 value. The first set of four bits starting from the least significant indicates the value 6 (110) with a continuation piece (indicated by a high bit of 1). The next set of four bits indicates a value of 24 (011 << 3) with no continuation. The sum (6+24) yields the value 30.
6-bit characters¶
6-bit characters encode common characters into a fixed 6-bit field. They represent the following characters with the following 6-bit values:
'a' .. 'z' --- 0 .. 25
'A' .. 'Z' --- 26 .. 51
'0' .. '9' --- 52 .. 61
'.' --- 62
'_' --- 63
This encoding is only suitable for encoding characters and strings that consist only of the above characters. It is completely incapable of encoding characters not in the set.
Word Alignment¶
Occasionally, it is useful to emit zero bits until the bitstream is a multiple of 32 bits. This ensures that the bit position in the stream can be represented as a multiple of 32-bit words.
Abbreviation IDs¶
A bitstream is a sequential series of Blocks and Data Records. Both of these start with an abbreviation ID encoded as a fixed-bitwidth field. The width is specified by the current block, as described below. The value of the abbreviation ID specifies either a builtin ID (which have special meanings, defined below) or one of the abbreviation IDs defined for the current block by the stream itself.
The set of builtin abbrev IDs is:
0 - END_BLOCK — This abbrev ID marks the end of the current block.
1 - ENTER_SUBBLOCK — This abbrev ID marks the beginning of a new block.
2 - DEFINE_ABBREV — This defines a new abbreviation.
3 - UNABBREV_RECORD — This ID specifies the definition of an unabbreviated record.
Abbreviation IDs 4 and above are defined by the stream itself, and specify an abbreviated record encoding.
Blocks¶
Blocks in a bitstream denote nested regions of the stream, and are identified by a content-specific id number (for example, LLVM IR uses an ID of 12 to represent function bodies). Block IDs 0-7 are reserved for standard blocks whose meaning is defined by Bitcode; block IDs 8 and greater are application specific. Nested blocks capture the hierarchical structure of the data encoded in it, and various properties are associated with blocks as the file is parsed. Block definitions allow the reader to efficiently skip blocks in constant time if the reader wants a summary of blocks, or if it wants to efficiently skip data it does not understand. The LLVM IR reader uses this mechanism to skip function bodies, lazily reading them on demand.
When reading and encoding the stream, several properties are maintained for the block. In particular, each block maintains:
A current abbrev id width. This value starts at 2 at the beginning of the stream, and is set every time a block record is entered. The block entry specifies the abbrev id width for the body of the block.
A set of abbreviations. Abbreviations may be defined within a block, in which case they are only defined in that block (neither subblocks nor enclosing blocks see the abbreviation). Abbreviations can also be defined inside a BLOCKINFO block, in which case they are defined in all blocks that match the ID that the
BLOCKINFO
block is describing.
As sub blocks are entered, these properties are saved and the new sub-block has its own set of abbreviations, and its own abbrev id width. When a sub-block is popped, the saved values are restored.
ENTER_SUBBLOCK Encoding¶
[ENTER_SUBBLOCK, blockidvbr8, newabbrevlenvbr4, <align32bits>, blocklen_32]
The ENTER_SUBBLOCK
abbreviation ID specifies the start of a new block
record. The blockid
value is encoded as an 8-bit VBR identifier, and
indicates the type of block being entered, which can be a standard block or
an application-specific block. The newabbrevlen
value is a 4-bit VBR, which
specifies the abbrev id width for the sub-block. The blocklen
value is a
32-bit aligned value that specifies the size of the subblock in 32-bit
words. This value allows the reader to skip over the entire block in one jump.
END_BLOCK Encoding¶
[END_BLOCK, <align32bits>]
The END_BLOCK
abbreviation ID specifies the end of the current block record.
Its end is aligned to 32-bits to ensure that the size of the block is an even
multiple of 32-bits.
Data Records¶
Data records consist of a record code and a number of (up to) 64-bit integer
values. The interpretation of the code and values is application specific and
may vary between different block types. Records can be encoded either using an
unabbrev record, or with an abbreviation. In the LLVM IR format, for example,
there is a record which encodes the target triple of a module. The code is
MODULE_CODE_TRIPLE
, and the values of the record are the ASCII codes for the
characters in the string.
UNABBREV_RECORD Encoding¶
[UNABBREV_RECORD, codevbr6, numopsvbr6, op0vbr6, op1vbr6, …]
An UNABBREV_RECORD
provides a default fallback encoding, which is both
completely general and extremely inefficient. It can describe an arbitrary
record by emitting the code and operands as VBRs.
For example, emitting an LLVM IR target triple as an unabbreviated record
requires emitting the UNABBREV_RECORD
abbrevid, a vbr6 for the
MODULE_CODE_TRIPLE
code, a vbr6 for the length of the string, which is equal
to the number of operands, and a vbr6 for each character. Because there are no
letters with values less than 32, each letter would need to be emitted as at
least a two-part VBR, which means that each letter would require at least 12
bits. This is not an efficient encoding, but it is fully general.
Abbreviated Record Encoding¶
[<abbrevid>, fields...]
An abbreviated record is an abbreviation id followed by a set of fields that are encoded according to the abbreviation definition. This allows records to be encoded significantly more densely than records encoded with the UNABBREV_RECORD type, and allows the abbreviation types to be specified in the stream itself, which allows the files to be completely self describing. The actual encoding of abbreviations is defined below.
The record code, which is the first field of an abbreviated record, may be encoded in the abbreviation definition (as a literal operand) or supplied in the abbreviated record (as a Fixed or VBR operand value).
Abbreviations¶
Abbreviations are an important form of compression for bitstreams. The idea is to specify a dense encoding for a class of records once, then use that encoding to emit many records. It takes space to emit the encoding into the file, but the space is recouped (hopefully plus some) when the records that use it are emitted.
Abbreviations can be determined dynamically per client, per file. Because the abbreviations are stored in the bitstream itself, different streams of the same format can contain different sets of abbreviations according to the needs of the specific stream. As a concrete example, LLVM IR files usually emit an abbreviation for binary operators. If a specific LLVM module contained no or few binary operators, the abbreviation does not need to be emitted.
DEFINE_ABBREV Encoding¶
[DEFINE_ABBREV, numabbrevopsvbr5, abbrevop0, abbrevop1, …]
A DEFINE_ABBREV
record adds an abbreviation to the list of currently defined
abbreviations in the scope of this block. This definition only exists inside
this immediate block — it is not visible in subblocks or enclosing blocks.
Abbreviations are implicitly assigned IDs sequentially starting from 4 (the
first application-defined abbreviation ID). Any abbreviations defined in a
BLOCKINFO
record for the particular block type receive IDs first, in order,
followed by any abbreviations defined within the block itself. Abbreviated data
records reference this ID to indicate what abbreviation they are invoking.
An abbreviation definition consists of the DEFINE_ABBREV
abbrevid followed
by a VBR that specifies the number of abbrev operands, then the abbrev operands
themselves. Abbreviation operands come in three forms. They all start with a
single bit that indicates whether the abbrev operand is a literal operand (when
the bit is 1) or an encoding operand (when the bit is 0).
Literal operands — [11, litvaluevbr8] — Literal operands specify that the value in the result is always a single specific value. This specific value is emitted as a vbr8 after the bit indicating that it is a literal operand.
Encoding info without data — [01, encoding3] — Operand encodings that do not have extra data are just emitted as their code.
Encoding info with data — [01, encoding3, valuevbr5] — Operand encodings that do have extra data are emitted as their code, followed by the extra data.
The possible operand encodings are:
Fixed (code 1): The field should be emitted as a fixed-width value, whose width is specified by the operand’s extra data.
VBR (code 2): The field should be emitted as a variable-width value, whose width is specified by the operand’s extra data.
Array (code 3): This field is an array of values. The array operand has no extra data, but expects another operand to follow it, indicating the element type of the array. When reading an array in an abbreviated record, the first integer is a vbr6 that indicates the array length, followed by the encoded elements of the array. An array may only occur as the last operand of an abbreviation (except for the one final operand that gives the array’s type).
Char6 (code 4): This field should be emitted as a char6-encoded value. This operand type takes no extra data. Char6 encoding is normally used as an array element type.
Blob (code 5): This field is emitted as a vbr6, followed by padding to a 32-bit boundary (for alignment) and an array of 8-bit objects. The array of bytes is further followed by tail padding to ensure that its total length is a multiple of 4 bytes. This makes it very efficient for the reader to decode the data without having to make a copy of it: it can use a pointer to the data in the mapped in file and poke directly at it. A blob may only occur as the last operand of an abbreviation.
For example, target triples in LLVM modules are encoded as a record of the form
[TRIPLE, 'a', 'b', 'c', 'd']
. Consider if the bitstream emitted the
following abbrev entry:
[0, Fixed, 4]
[0, Array]
[0, Char6]
When emitting a record with this abbreviation, the above entry would be emitted as:
[4abbrevwidth, 24, 4vbr6, 06, 16, 26, 36]
These values are:
The first value, 4, is the abbreviation ID for this abbreviation.
The second value, 2, is the record code for
TRIPLE
records within LLVM IR fileMODULE_BLOCK
blocks.The third value, 4, is the length of the array.
The rest of the values are the char6 encoded values for
"abcd"
.
With this abbreviation, the triple is emitted with only 37 bits (assuming a
abbrev id width of 3). Without the abbreviation, significantly more space would
be required to emit the target triple. Also, because the TRIPLE
value is
not emitted as a literal in the abbreviation, the abbreviation can also be used
for any other string value.
Standard Blocks¶
In addition to the basic block structure and record encodings, the bitstream also defines specific built-in block types. These block types specify how the stream is to be decoded or other metadata. In the future, new standard blocks may be added. Block IDs 0-7 are reserved for standard blocks.
#0 - BLOCKINFO Block¶
The BLOCKINFO
block allows the description of metadata for other blocks.
The currently specified records are:
[SETBID (#1), blockid]
[DEFINE_ABBREV, ...]
[BLOCKNAME, ...name...]
[SETRECORDNAME, RecordID, ...name...]
The SETBID
record (code 1) indicates which block ID is being described.
SETBID
records can occur multiple times throughout the block to change which
block ID is being described. There must be a SETBID
record prior to any
other records.
Standard DEFINE_ABBREV
records can occur inside BLOCKINFO
blocks, but
unlike their occurrence in normal blocks, the abbreviation is defined for blocks
matching the block ID we are describing, not the BLOCKINFO
block
itself. The abbreviations defined in BLOCKINFO
blocks receive abbreviation
IDs as described in DEFINE_ABBREV.
The BLOCKNAME
record (code 2) can optionally occur in this block. The
elements of the record are the bytes of the string name of the block.
llvm-bcanalyzer can use this to dump out bitcode files symbolically.
The SETRECORDNAME
record (code 3) can also optionally occur in this block.
The first operand value is a record ID number, and the rest of the elements of
the record are the bytes for the string name of the record. llvm-bcanalyzer can
use this to dump out bitcode files symbolically.
Note that although the data in BLOCKINFO
blocks is described as “metadata,”
the abbreviations they contain are essential for parsing records from the
corresponding blocks. It is not safe to skip them.
Bitcode Wrapper Format¶
Bitcode files for LLVM IR may optionally be wrapped in a simple wrapper structure. This structure contains a simple header that indicates the offset and size of the embedded BC file. This allows additional information to be stored alongside the BC file. The structure of this file header is:
[Magic32, Version32, Offset32, Size32, CPUType32]
Each of the fields are 32-bit fields stored in little endian form (as with the
rest of the bitcode file fields). The Magic number is always 0x0B17C0DE
and
the version is currently always 0
. The Offset field is the offset in bytes
to the start of the bitcode stream in the file, and the Size field is the size
in bytes of the stream. CPUType is a target-specific value that can be used to
encode the CPU of the target.
Native Object File Wrapper Format¶
Bitcode files for LLVM IR may also be wrapped in a native object file
(i.e. ELF, COFF, Mach-O). The bitcode must be stored in a section of the object
file named __LLVM,__bitcode
for MachO and .llvmbc
for the other object
formats. This wrapper format is useful for accommodating LTO in compilation
pipelines where intermediate objects must be native object files which contain
metadata in other sections.
Not all tools support this format. For example, lld and the gold plugin will ignore these sections when linking object files.
LLVM IR Encoding¶
LLVM IR is encoded into a bitstream by defining blocks and records. It uses blocks for things like constant pools, functions, symbol tables, etc. It uses records for things like instructions, global variable descriptors, type descriptions, etc. This document does not describe the set of abbreviations that the writer uses, as these are fully self-described in the file, and the reader is not allowed to build in any knowledge of this.
Basics¶
LLVM IR Magic Number¶
The magic number for LLVM IR files is:
[‘B’8, ‘C’8, 0x04, 0xC4, 0xE4, 0xD4]
Signed VBRs¶
Variable Width Integer encoding is an efficient way to encode arbitrary sized unsigned values, but is an extremely inefficient for encoding signed values, as signed values are otherwise treated as maximally large unsigned values.
As such, signed VBR values of a specific width are emitted as follows:
Positive values are emitted as VBRs of the specified width, but with their value shifted left by one.
Negative values are emitted as VBRs of the specified width, but the negated value is shifted left by one, and the low bit is set.
With this encoding, small positive and small negative values can both be emitted
efficiently. Signed VBR encoding is used in CST_CODE_INTEGER
and
CST_CODE_WIDE_INTEGER
records within CONSTANTS_BLOCK
blocks.
It is also used for phi instruction operands in MODULE_CODE_VERSION 1.
LLVM IR Blocks¶
LLVM IR is defined with the following blocks:
8 — MODULE_BLOCK — This is the top-level block that contains the entire module, and describes a variety of per-module information.
9 — PARAMATTR_BLOCK — This enumerates the parameter attributes.
10 — PARAMATTR_GROUP_BLOCK — This describes the attribute group table.
11 — CONSTANTS_BLOCK — This describes constants for a module or function.
12 — FUNCTION_BLOCK — This describes a function body.
14 — VALUE_SYMTAB_BLOCK — This describes a value symbol table.
15 — METADATA_BLOCK — This describes metadata items.
16 — METADATA_ATTACHMENT — This contains records associating metadata with function instruction values.
17 — TYPE_BLOCK — This describes all of the types in the module.
23 — STRTAB_BLOCK — The bitcode file’s string table.
MODULE_BLOCK Contents¶
The MODULE_BLOCK
block (id 8) is the top-level block for LLVM bitcode files,
and each module in a bitcode file must contain exactly one. A bitcode file with
multi-module bitcode is valid. In addition to records (described below)
containing information about the module, a MODULE_BLOCK
block may contain
the following sub-blocks:
MODULE_CODE_VERSION Record¶
[VERSION, version#]
The VERSION
record (code 1) contains a single value indicating the format
version. Versions 0, 1 and 2 are supported at this time. The difference between
version 0 and 1 is in the encoding of instruction operands in
each FUNCTION_BLOCK.
In version 0, each value defined by an instruction is assigned an ID
unique to the function. Function-level value IDs are assigned starting from
NumModuleValues
since they share the same namespace as module-level
values. The value enumerator resets after each function. When a value is
an operand of an instruction, the value ID is used to represent the operand.
For large functions or large modules, these operand values can be large.
The encoding in version 1 attempts to avoid large operand values in common cases. Instead of using the value ID directly, operands are encoded as relative to the current instruction. Thus, if an operand is the value defined by the previous instruction, the operand will be encoded as 1.
For example, instead of
#n = load #n-1
#n+1 = icmp eq #n, #const0
br #n+1, label #(bb1), label #(bb2)
version 1 will encode the instructions as
#n = load #1
#n+1 = icmp eq #1, (#n+1)-#const0
br #1, label #(bb1), label #(bb2)
Note in the example that operands which are constants also use the relative encoding, while operands like basic block labels do not use the relative encoding.
Forward references will result in a negative value. This can be inefficient, as operands are normally encoded as unsigned VBRs. However, forward references are rare, except in the case of phi instructions. For phi instructions, operands are encoded as Signed VBRs to deal with forward references.
In version 2, the meaning of module records FUNCTION
, GLOBALVAR
,
ALIAS
, IFUNC
and COMDAT
change such that the first two operands
specify an offset and size of a string in a string table (see STRTAB_BLOCK
Contents), the function name is removed from the FNENTRY
record in the
value symbol table, and the top-level VALUE_SYMTAB_BLOCK
may only contain
FNENTRY
records.
MODULE_CODE_TRIPLE Record¶
[TRIPLE, ...string...]
The TRIPLE
record (code 2) contains a variable number of values representing
the bytes of the target triple
specification string.
MODULE_CODE_DATALAYOUT Record¶
[DATALAYOUT, ...string...]
The DATALAYOUT
record (code 3) contains a variable number of values
representing the bytes of the target datalayout
specification string.
MODULE_CODE_ASM Record¶
[ASM, ...string...]
The ASM
record (code 4) contains a variable number of values representing
the bytes of module asm
strings, with individual assembly blocks separated
by newline (ASCII 10) characters.
MODULE_CODE_SECTIONNAME Record¶
[SECTIONNAME, ...string...]
The SECTIONNAME
record (code 5) contains a variable number of values
representing the bytes of a single section name string. There should be one
SECTIONNAME
record for each section name referenced (e.g., in global
variable or function section
attributes) within the module. These records
can be referenced by the 1-based index in the section fields of GLOBALVAR
or FUNCTION
records.
MODULE_CODE_DEPLIB Record¶
[DEPLIB, ...string...]
The DEPLIB
record (code 6) contains a variable number of values representing
the bytes of a single dependent library name string, one of the libraries
mentioned in a deplibs
declaration. There should be one DEPLIB
record
for each library name referenced.
MODULE_CODE_GLOBALVAR Record¶
[GLOBALVAR, strtab offset, strtab size, pointer type, isconst, initid, linkage, alignment, section, visibility, threadlocal, unnamed_addr, externally_initialized, dllstorageclass, comdat, attributes, preemptionspecifier]
The GLOBALVAR
record (code 7) marks the declaration or definition of a
global variable. The operand fields are:
strtab offset, strtab size: Specifies the name of the global variable. See STRTAB_BLOCK Contents.
pointer type: The type index of the pointer type used to point to this global variable
isconst: Non-zero if the variable is treated as constant within the module, or zero if it is not
initid: If non-zero, the value index of the initializer for this variable, plus 1.
linkage: An encoding of the linkage type for this variable:
external
: code 0weak
: code 1appending
: code 2internal
: code 3linkonce
: code 4dllimport
: code 5dllexport
: code 6extern_weak
: code 7common
: code 8private
: code 9weak_odr
: code 10linkonce_odr
: code 11available_externally
: code 12deprecated : code 13
deprecated : code 14
alignment*: The logarithm base 2 of the variable’s requested alignment, plus 1
section: If non-zero, the 1-based section index in the table of MODULE_CODE_SECTIONNAME entries.
visibility: If present, an encoding of the visibility of this variable:
default
: code 0hidden
: code 1protected
: code 2
threadlocal: If present, an encoding of the thread local storage mode of the variable:
not thread local
: code 0thread local; default TLS model
: code 1localdynamic
: code 2initialexec
: code 3localexec
: code 4
unnamed_addr: If present, an encoding of the
unnamed_addr
attribute of this variable:not
unnamed_addr
: code 0unnamed_addr
: code 1local_unnamed_addr
: code 2
dllstorageclass: If present, an encoding of the DLL storage class of this variable:
default
: code 0dllimport
: code 1dllexport
: code 2
comdat: An encoding of the COMDAT of this function
attributes: If nonzero, the 1-based index into the table of AttributeLists.
preemptionspecifier: If present, an encoding of the runtime preemption specifier of this variable:
dso_preemptable
: code 0dso_local
: code 1
MODULE_CODE_FUNCTION Record¶
[FUNCTION, strtab offset, strtab size, type, callingconv, isproto, linkage, paramattr, alignment, section, visibility, gc, prologuedata, dllstorageclass, comdat, prefixdata, personalityfn, preemptionspecifier]
The FUNCTION
record (code 8) marks the declaration or definition of a
function. The operand fields are:
strtab offset, strtab size: Specifies the name of the function. See STRTAB_BLOCK Contents.
type: The type index of the function type describing this function
callingconv: The calling convention number: *
ccc
: code 0 *fastcc
: code 8 *coldcc
: code 9 *webkit_jscc
: code 12 *anyregcc
: code 13 *preserve_mostcc
: code 14 *preserve_allcc
: code 15 *swiftcc
: code 16 *cxx_fast_tlscc
: code 17 *tailcc
: code 18 *cfguard_checkcc
: code 19 *swifttailcc
: code 20 *x86_stdcallcc
: code 64 *x86_fastcallcc
: code 65 *arm_apcscc
: code 66 *arm_aapcscc
: code 67 *arm_aapcs_vfpcc
: code 68isproto*: Non-zero if this entry represents a declaration rather than a definition
linkage: An encoding of the linkage type for this function
paramattr: If nonzero, the 1-based parameter attribute index into the table of PARAMATTR_CODE_ENTRY entries.
alignment: The logarithm base 2 of the function’s requested alignment, plus 1
section: If non-zero, the 1-based section index in the table of MODULE_CODE_SECTIONNAME entries.
visibility: An encoding of the visibility of this function
gc: If present and nonzero, the 1-based garbage collector index in the table of MODULE_CODE_GCNAME entries.
unnamed_addr: If present, an encoding of the unnamed_addr attribute of this function
prologuedata: If non-zero, the value index of the prologue data for this function, plus 1.
dllstorageclass: An encoding of the dllstorageclass of this function
comdat: An encoding of the COMDAT of this function
prefixdata: If non-zero, the value index of the prefix data for this function, plus 1.
personalityfn: If non-zero, the value index of the personality function for this function, plus 1.
preemptionspecifier: If present, an encoding of the runtime preemption specifier of this function.
MODULE_CODE_ALIAS Record¶
[ALIAS, strtab offset, strtab size, alias type, aliasee val#, linkage, visibility, dllstorageclass, threadlocal, unnamed_addr, preemptionspecifier]
The ALIAS
record (code 9) marks the definition of an alias. The operand
fields are
strtab offset, strtab size: Specifies the name of the alias. See STRTAB_BLOCK Contents.
alias type: The type index of the alias
aliasee val#: The value index of the aliased value
linkage: An encoding of the linkage type for this alias
visibility: If present, an encoding of the visibility of the alias
dllstorageclass: If present, an encoding of the dllstorageclass of the alias
threadlocal: If present, an encoding of the thread local property of the alias
unnamed_addr: If present, an encoding of the unnamed_addr attribute of this alias
preemptionspecifier: If present, an encoding of the runtime preemption specifier of this alias.
MODULE_CODE_GCNAME Record¶
[GCNAME, ...string...]
The GCNAME
record (code 11) contains a variable number of values
representing the bytes of a single garbage collector name string. There should
be one GCNAME
record for each garbage collector name referenced in function
gc
attributes within the module. These records can be referenced by 1-based
index in the gc fields of FUNCTION
records.
PARAMATTR_BLOCK Contents¶
The PARAMATTR_BLOCK
block (id 9) contains a table of entries describing the
attributes of function parameters. These entries are referenced by 1-based index
in the paramattr field of module block FUNCTION records, or within the
attr field of function block INST_INVOKE
and INST_CALL
records.
Entries within PARAMATTR_BLOCK
are constructed to ensure that each is unique
(i.e., no two indices represent equivalent attribute lists).
PARAMATTR_CODE_ENTRY Record¶
[ENTRY, attrgrp0, attrgrp1, ...]
The ENTRY
record (code 2) contains a variable number of values describing a
unique set of function parameter attributes. Each attrgrp value is used as a
key with which to look up an entry in the attribute group table described
in the PARAMATTR_GROUP_BLOCK
block.
PARAMATTR_CODE_ENTRY_OLD Record¶
Note
This is a legacy encoding for attributes, produced by LLVM versions 3.2 and earlier. It is guaranteed to be understood by the current LLVM version, as specified in the IR Backwards Compatibility policy.
[ENTRY, paramidx0, attr0, paramidx1, attr1...]
The ENTRY
record (code 1) contains an even number of values describing a
unique set of function parameter attributes. Each paramidx value indicates
which set of attributes is represented, with 0 representing the return value
attributes, 0xFFFFFFFF representing function attributes, and other values
representing 1-based function parameters. Each attr value is a bitmap with the
following interpretation:
bit 0:
zeroext
bit 1:
signext
bit 2:
noreturn
bit 3:
inreg
bit 4:
sret
bit 5:
nounwind
bit 6:
noalias
bit 7:
byval
bit 8:
nest
bit 9:
readnone
bit 10:
readonly
bit 11:
noinline
bit 12:
alwaysinline
bit 13:
optsize
bit 14:
ssp
bit 15:
sspreq
bits 16-31:
align n
bit 32:
nocapture
bit 33:
noredzone
bit 34:
noimplicitfloat
bit 35:
naked
bit 36:
inlinehint
bits 37-39:
alignstack n
, represented as the logarithm base 2 of the requested alignment, plus 1
PARAMATTR_GROUP_BLOCK Contents¶
The PARAMATTR_GROUP_BLOCK
block (id 10) contains a table of entries
describing the attribute groups present in the module. These entries can be
referenced within PARAMATTR_CODE_ENTRY
entries.
PARAMATTR_GRP_CODE_ENTRY Record¶
[ENTRY, grpid, paramidx, attr0, attr1, ...]
The ENTRY
record (code 3) contains grpid and paramidx values, followed
by a variable number of values describing a unique group of attributes. The
grpid value is a unique key for the attribute group, which can be referenced
within PARAMATTR_CODE_ENTRY
entries. The paramidx value indicates which
set of attributes is represented, with 0 representing the return value
attributes, 0xFFFFFFFF representing function attributes, and other values
representing 1-based function parameters.
Each attr is itself represented as a variable number of values:
kind, key [, ...], [value [, ...]]
Each attribute is either a well-known LLVM attribute (possibly with an integer value associated with it), or an arbitrary string (possibly with an arbitrary string value associated with it). The kind value is an integer code distinguishing between these possibilities:
code 0: well-known attribute
code 1: well-known attribute with an integer value
code 3: string attribute
code 4: string attribute with a string value
For well-known attributes (code 0 or 1), the key value is an integer code identifying the attribute. For attributes with an integer argument (code 1), the value value indicates the argument.
For string attributes (code 3 or 4), the key value is actually a variable number of values representing the bytes of a null-terminated string. For attributes with a string argument (code 4), the value value is similarly a variable number of values representing the bytes of a null-terminated string.
The integer codes are mapped to well-known attributes as follows.
code 1:
align(<n>)
code 2:
alwaysinline
code 3:
byval
code 4:
inlinehint
code 5:
inreg
code 6:
minsize
code 7:
naked
code 8:
nest
code 9:
noalias
code 10:
nobuiltin
code 11:
nocapture
code 12:
nodeduplicate
code 13:
noimplicitfloat
code 14:
noinline
code 15:
nonlazybind
code 16:
noredzone
code 17:
noreturn
code 18:
nounwind
code 19:
optsize
code 20:
readnone
code 21:
readonly
code 22:
returned
code 23:
returns_twice
code 24:
signext
code 25:
alignstack(<n>)
code 26:
ssp
code 27:
sspreq
code 28:
sspstrong
code 29:
sret
code 30:
sanitize_address
code 31:
sanitize_thread
code 32:
sanitize_memory
code 33:
uwtable
code 34:
zeroext
code 35:
builtin
code 36:
cold
code 37:
optnone
code 38:
inalloca
code 39:
nonnull
code 40:
jumptable
code 41:
dereferenceable(<n>)
code 42:
dereferenceable_or_null(<n>)
code 43:
convergent
code 44:
safestack
code 45:
argmemonly
code 46:
swiftself
code 47:
swifterror
code 48:
norecurse
code 49:
inaccessiblememonly
code 50:
inaccessiblememonly_or_argmemonly
code 51:
allocsize(<EltSizeParam>[, <NumEltsParam>])
code 52:
writeonly
code 53:
speculatable
code 54:
strictfp
code 55:
sanitize_hwaddress
code 56:
nocf_check
code 57:
optforfuzzing
code 58:
shadowcallstack
code 59:
speculative_load_hardening
code 60:
immarg
code 61:
willreturn
code 62:
nofree
code 63:
nosync
code 64:
sanitize_memtag
code 65:
preallocated
code 66:
no_merge
code 67:
null_pointer_is_valid
code 68:
noundef
code 69:
byref
code 70:
mustprogress
code 74:
vscale_range(<Min>[, <Max>])
code 75:
swiftasync
code 76:
nosanitize_coverage
code 77:
elementtype
code 78:
disable_sanitizer_instrumentation
code 79:
nosanitize_bounds
Note
The allocsize
attribute has a special encoding for its arguments. Its two
arguments, which are 32-bit integers, are packed into one 64-bit integer value
(i.e. (EltSizeParam << 32) | NumEltsParam
), with NumEltsParam
taking on
the sentinel value -1 if it is not specified.
Note
The vscale_range
attribute has a special encoding for its arguments. Its two
arguments, which are 32-bit integers, are packed into one 64-bit integer value
(i.e. (Min << 32) | Max
), with Max
taking on the value of Min
if
it is not specified.
TYPE_BLOCK Contents¶
The TYPE_BLOCK
block (id 17) contains records which constitute a table of
type operator entries used to represent types referenced within an LLVM
module. Each record (with the exception of NUMENTRY) generates a single type
table entry, which may be referenced by 0-based index from instructions,
constants, metadata, type symbol table entries, or other type operator records.
Entries within TYPE_BLOCK
are constructed to ensure that each entry is
unique (i.e., no two indices represent structurally equivalent types).
TYPE_CODE_NUMENTRY Record¶
[NUMENTRY, numentries]
The NUMENTRY
record (code 1) contains a single value which indicates the
total number of type code entries in the type table of the module. If present,
NUMENTRY
should be the first record in the block.
TYPE_CODE_VOID Record¶
[VOID]
The VOID
record (code 2) adds a void
type to the type table.
TYPE_CODE_HALF Record¶
[HALF]
The HALF
record (code 10) adds a half
(16-bit floating point) type to
the type table.
TYPE_CODE_BFLOAT Record¶
[BFLOAT]
The BFLOAT
record (code 23) adds a bfloat
(16-bit brain floating point)
type to the type table.
TYPE_CODE_FLOAT Record¶
[FLOAT]
The FLOAT
record (code 3) adds a float
(32-bit floating point) type to
the type table.
TYPE_CODE_DOUBLE Record¶
[DOUBLE]
The DOUBLE
record (code 4) adds a double
(64-bit floating point) type to
the type table.
TYPE_CODE_LABEL Record¶
[LABEL]
The LABEL
record (code 5) adds a label
type to the type table.
TYPE_CODE_OPAQUE Record¶
[OPAQUE]
The OPAQUE
record (code 6) adds an opaque
type to the type table, with
a name defined by a previously encountered STRUCT_NAME
record. Note that
distinct opaque
types are not unified.
TYPE_CODE_INTEGER Record¶
[INTEGER, width]
The INTEGER
record (code 7) adds an integer type to the type table. The
single width field indicates the width of the integer type.
TYPE_CODE_POINTER Record¶
[POINTER, pointee type, address space]
The POINTER
record (code 8) adds a pointer type to the type table. The
operand fields are
pointee type: The type index of the pointed-to type
address space: If supplied, the target-specific numbered address space where the pointed-to object resides. Otherwise, the default address space is zero.
TYPE_CODE_FUNCTION_OLD Record¶
Note
This is a legacy encoding for functions, produced by LLVM versions 3.0 and earlier. It is guaranteed to be understood by the current LLVM version, as specified in the IR Backwards Compatibility policy.
[FUNCTION_OLD, vararg, ignored, retty, ...paramty... ]
The FUNCTION_OLD
record (code 9) adds a function type to the type table.
The operand fields are
vararg: Non-zero if the type represents a varargs function
ignored: This value field is present for backward compatibility only, and is ignored
retty: The type index of the function’s return type
paramty: Zero or more type indices representing the parameter types of the function
TYPE_CODE_ARRAY Record¶
[ARRAY, numelts, eltty]
The ARRAY
record (code 11) adds an array type to the type table. The
operand fields are
numelts: The number of elements in arrays of this type
eltty: The type index of the array element type
TYPE_CODE_VECTOR Record¶
[VECTOR, numelts, eltty]
The VECTOR
record (code 12) adds a vector type to the type table. The
operand fields are
numelts: The number of elements in vectors of this type
eltty: The type index of the vector element type
TYPE_CODE_X86_FP80 Record¶
[X86_FP80]
The X86_FP80
record (code 13) adds an x86_fp80
(80-bit floating point)
type to the type table.
TYPE_CODE_FP128 Record¶
[FP128]
The FP128
record (code 14) adds an fp128
(128-bit floating point) type
to the type table.
TYPE_CODE_PPC_FP128 Record¶
[PPC_FP128]
The PPC_FP128
record (code 15) adds a ppc_fp128
(128-bit floating point)
type to the type table.
TYPE_CODE_METADATA Record¶
[METADATA]
The METADATA
record (code 16) adds a metadata
type to the type table.
TYPE_CODE_X86_MMX Record¶
[X86_MMX]
The X86_MMX
record (code 17) adds an x86_mmx
type to the type table.
TYPE_CODE_STRUCT_ANON Record¶
[STRUCT_ANON, ispacked, ...eltty...]
The STRUCT_ANON
record (code 18) adds a literal struct type to the type
table. The operand fields are
ispacked: Non-zero if the type represents a packed structure
eltty: Zero or more type indices representing the element types of the structure
TYPE_CODE_STRUCT_NAME Record¶
[STRUCT_NAME, ...string...]
The STRUCT_NAME
record (code 19) contains a variable number of values
representing the bytes of a struct name. The next OPAQUE
or
STRUCT_NAMED
record will use this name.
TYPE_CODE_STRUCT_NAMED Record¶
[STRUCT_NAMED, ispacked, ...eltty...]
The STRUCT_NAMED
record (code 20) adds an identified struct type to the
type table, with a name defined by a previously encountered STRUCT_NAME
record. The operand fields are
ispacked: Non-zero if the type represents a packed structure
eltty: Zero or more type indices representing the element types of the structure
TYPE_CODE_FUNCTION Record¶
[FUNCTION, vararg, retty, ...paramty... ]
The FUNCTION
record (code 21) adds a function type to the type table. The
operand fields are
vararg: Non-zero if the type represents a varargs function
retty: The type index of the function’s return type
paramty: Zero or more type indices representing the parameter types of the function
TYPE_CODE_X86_AMX Record¶
[X86_AMX]
The X86_AMX
record (code 24) adds an x86_amx
type to the type table.
CONSTANTS_BLOCK Contents¶
The CONSTANTS_BLOCK
block (id 11) …
FUNCTION_BLOCK Contents¶
The FUNCTION_BLOCK
block (id 12) …
In addition to the record types described below, a FUNCTION_BLOCK
block may
contain the following sub-blocks:
VALUE_SYMTAB_BLOCK Contents¶
The VALUE_SYMTAB_BLOCK
block (id 14) …
METADATA_BLOCK Contents¶
The METADATA_BLOCK
block (id 15) …
METADATA_ATTACHMENT Contents¶
The METADATA_ATTACHMENT
block (id 16) …
STRTAB_BLOCK Contents¶
The STRTAB
block (id 23) contains a single record (STRTAB_BLOB
, id 1)
with a single blob operand containing the bitcode file’s string table.
Strings in the string table are not null terminated. A record’s strtab offset and strtab size operands specify the byte offset and size of a string within the string table.
The string table is used by all preceding blocks in the bitcode file that are
not succeeded by another intervening STRTAB
block. Normally a bitcode
file will have a single string table, but it may have more than one if it
was created by binary concatenation of multiple bitcode files.