This document is a reference manual for the LLVM assembly language. LLVM is a Static Single Assignment (SSA) based representation that provides type safety, low-level operations, flexibility, and the capability of representing ‘all’ high-level languages cleanly. It is the common code representation used throughout all phases of the LLVM compilation strategy.
The LLVM code representation is designed to be used in three different forms: as an in-memory compiler IR, as an on-disk bitcode representation (suitable for fast loading by a Just-In-Time compiler), and as a human readable assembly language representation. This allows LLVM to provide a powerful intermediate representation for efficient compiler transformations and analysis, while providing a natural means to debug and visualize the transformations. The three different forms of LLVM are all equivalent. This document describes the human readable representation and notation.
The LLVM representation aims to be light-weight and low-level while being expressive, typed, and extensible at the same time. It aims to be a “universal IR” of sorts, by being at a low enough level that high-level ideas may be cleanly mapped to it (similar to how microprocessors are “universal IR’s”, allowing many source languages to be mapped to them). By providing type information, LLVM can be used as the target of optimizations: for example, through pointer analysis, it can be proven that a C automatic variable is never accessed outside of the current function, allowing it to be promoted to a simple SSA value instead of a memory location.
It is important to note that this document describes ‘well formed’ LLVM assembly language. There is a difference between what the parser accepts and what is considered ‘well formed’. For example, the following instruction is syntactically okay, but not well formed:
%x = add i32 1, %x
because the definition of %x does not dominate all of its uses. The LLVM infrastructure provides a verification pass that may be used to verify that an LLVM module is well formed. This pass is automatically run by the parser after parsing input assembly and by the optimizer before it outputs bitcode. The violations pointed out by the verifier pass indicate bugs in transformation passes or input to the parser.
LLVM identifiers come in two basic types: global and local. Global identifiers (functions, global variables) begin with the '@' character. Local identifiers (register names, types) begin with the '%' character. Additionally, there are three different formats for identifiers, for different purposes:
LLVM requires that values start with a prefix for two reasons: Compilers don’t need to worry about name clashes with reserved words, and the set of reserved words may be expanded in the future without penalty. Additionally, unnamed identifiers allow a compiler to quickly come up with a temporary variable without having to avoid symbol table conflicts.
Reserved words in LLVM are very similar to reserved words in other languages. There are keywords for different opcodes (‘add‘, ‘bitcast‘, ‘ret‘, etc...), for primitive type names (‘void‘, ‘i32‘, etc...), and others. These reserved words cannot conflict with variable names, because none of them start with a prefix character ('%' or '@').
Here is an example of LLVM code to multiply the integer variable ‘%X‘ by 8:
The easy way:
%result = mul i32 %X, 8
After strength reduction:
%result = shl i32 %X, 3
And the hard way:
%0 = add i32 %X, %X ; yields i32:%0
%1 = add i32 %0, %0 ; yields i32:%1
%result = add i32 %1, %1
This last way of multiplying %X by 8 illustrates several important lexical features of LLVM:
It also shows a convention that we follow in this document. When demonstrating instructions, we will follow an instruction with a comment that defines the type and name of value produced.
LLVM programs are composed of Module‘s, each of which is a translation unit of the input programs. Each module consists of functions, global variables, and symbol table entries. Modules may be combined together with the LLVM linker, which merges function (and global variable) definitions, resolves forward declarations, and merges symbol table entries. Here is an example of the “hello world” module:
; Declare the string constant as a global constant.
@.str = private unnamed_addr constant [13 x i8] c"hello world\0A\00"
; External declaration of the puts function
declare i32 @puts(i8* nocapture) nounwind
; Definition of main function
define i32 @main() { ; i32()*
; Convert [13 x i8]* to i8*...
%cast210 = getelementptr [13 x i8], [13 x i8]* @.str, i64 0, i64 0
; Call puts function to write out the string to stdout.
call i32 @puts(i8* %cast210)
ret i32 0
}
; Named metadata
!0 = !{i32 42, null, !"string"}
!foo = !{!0}
This example is made up of a global variable named “.str”, an external declaration of the “puts” function, a function definition for “main” and named metadata “foo”.
In general, a module is made up of a list of global values (where both functions and global variables are global values). Global values are represented by a pointer to a memory location (in this case, a pointer to an array of char, and a pointer to a function), and have one of the following linkage types.
All Global Variables and Functions have one of the following types of linkage:
“appending” linkage may only be applied to global variables of pointer to array type. When two global variables with appending linkage are linked together, the two global arrays are appended together. This is the LLVM, typesafe, equivalent of having the system linker append together “sections” with identical names when .o files are linked.
Unfortunately this doesn’t correspond to any feature in .o files, so it can only be used for variables like llvm.global_ctors which llvm interprets specially.
It is illegal for a function declaration to have any linkage type other than external or extern_weak.
LLVM functions, calls and invokes can all have an optional calling convention specified for the call. The calling convention of any pair of dynamic caller/callee must match, or the behavior of the program is undefined. The following calling conventions are supported by LLVM, and more may be added in the future:
This calling convention has been implemented specifically for use by the Glasgow Haskell Compiler (GHC). It passes everything in registers, going to extremes to achieve this by disabling callee save registers. This calling convention should not be used lightly but only for specific situations such as an alternative to the register pinning performance technique often used when implementing functional programming languages. At the moment only X86 supports this convention and it has the following limitations:
This calling convention supports tail call optimization but requires both the caller and callee are using it.
This calling convention attempts to make the code in the caller as unintrusive as possible. This convention behaves identically to the C calling convention on how arguments and return values are passed, but it uses a different set of caller/callee-saved registers. This alleviates the burden of saving and recovering a large register set before and after the call in the caller. If the arguments are passed in callee-saved registers, then they will be preserved by the callee across the call. This doesn’t apply for values returned in callee-saved registers.
The idea behind this convention is to support calls to runtime functions that have a hot path and a cold path. The hot path is usually a small piece of code that doesn’t use many registers. The cold path might need to call out to another function and therefore only needs to preserve the caller-saved registers, which haven’t already been saved by the caller. The PreserveMost calling convention is very similar to the cold calling convention in terms of caller/callee-saved registers, but they are used for different types of function calls. coldcc is for function calls that are rarely executed, whereas preserve_mostcc function calls are intended to be on the hot path and definitely executed a lot. Furthermore preserve_mostcc doesn’t prevent the inliner from inlining the function call.
This calling convention will be used by a future version of the ObjectiveC runtime and should therefore still be considered experimental at this time. Although this convention was created to optimize certain runtime calls to the ObjectiveC runtime, it is not limited to this runtime and might be used by other runtimes in the future too. The current implementation only supports X86-64, but the intention is to support more architectures in the future.
This calling convention attempts to make the code in the caller even less intrusive than the PreserveMost calling convention. This calling convention also behaves identical to the C calling convention on how arguments and return values are passed, but it uses a different set of caller/callee-saved registers. This removes the burden of saving and recovering a large register set before and after the call in the caller. If the arguments are passed in callee-saved registers, then they will be preserved by the callee across the call. This doesn’t apply for values returned in callee-saved registers.
The idea behind this convention is to support calls to runtime functions that don’t need to call out to any other functions.
This calling convention, like the PreserveMost calling convention, will be used by a future version of the ObjectiveC runtime and should be considered experimental at this time.
Clang generates an access function to access C++-style TLS. The access function generally has an entry block, an exit block and an initialization block that is run at the first time. The entry and exit blocks can access a few TLS IR variables, each access will be lowered to a platform-specific sequence.
This calling convention aims to minimize overhead in the caller by preserving as many registers as possible (all the registers that are perserved on the fast path, composed of the entry and exit blocks).
This calling convention behaves identical to the C calling convention on how arguments and return values are passed, but it uses a different set of caller/callee-saved registers.
Given that each platform has its own lowering sequence, hence its own set of preserved registers, we can’t use the existing PreserveMost.
More calling conventions can be added/defined on an as-needed basis, to support Pascal conventions or any other well-known target-independent convention.
All Global Variables and Functions have one of the following visibility styles:
A symbol with internal or private linkage must have default visibility.
All Global Variables, Functions and Aliases can have one of the following DLL storage class:
A variable may be defined as thread_local, which means that it will not be shared by threads (each thread will have a separated copy of the variable). Not all targets support thread-local variables. Optionally, a TLS model may be specified:
If no explicit model is given, the “general dynamic” model is used.
The models correspond to the ELF TLS models; see ELF Handling For Thread-Local Storage for more information on under which circumstances the different models may be used. The target may choose a different TLS model if the specified model is not supported, or if a better choice of model can be made.
A model can also be specified in an alias, but then it only governs how the alias is accessed. It will not have any effect in the aliasee.
For platforms without linker support of ELF TLS model, the -femulated-tls flag can be used to generate GCC compatible emulated TLS code.
Global variables, functions and aliases may have an optional runtime preemption specifier. If a preemption specifier isn’t given explicitly, then a symbol is assumed to be dso_preemptable.
LLVM IR allows you to specify both “identified” and “literal” structure types. Literal types are uniqued structurally, but identified types are never uniqued. An opaque structural type can also be used to forward declare a type that is not yet available.
An example of an identified structure specification is:
%mytype = type { %mytype*, i32 }
Prior to the LLVM 3.0 release, identified types were structurally uniqued. Only literal types are uniqued in recent versions of LLVM.
Note: non-integral pointer types are a work in progress, and they should be considered experimental at this time.
LLVM IR optionally allows the frontend to denote pointers in certain address spaces as “non-integral” via the datalayout string. Non-integral pointer types represent pointers that have an unspecified bitwise representation; that is, the integral representation may be target dependent or unstable (not backed by a fixed integer).
inttoptr instructions converting integers to non-integral pointer types are ill-typed, and so are ptrtoint instructions converting values of non-integral pointer types to integers. Vector versions of said instructions are ill-typed as well.
Global variables define regions of memory allocated at compilation time instead of run-time.
Global variable definitions must be initialized.
Global variables in other translation units can also be declared, in which case they don’t have an initializer.
Either global variable definitions or declarations may have an explicit section to be placed in and may have an optional explicit alignment specified. If there is a mismatch between the explicit or inferred section information for the variable declaration and its definition the resulting behavior is undefined.
A variable may be defined as a global constant, which indicates that the contents of the variable will never be modified (enabling better optimization, allowing the global data to be placed in the read-only section of an executable, etc). Note that variables that need runtime initialization cannot be marked constant as there is a store to the variable.
LLVM explicitly allows declarations of global variables to be marked constant, even if the final definition of the global is not. This capability can be used to enable slightly better optimization of the program, but requires the language definition to guarantee that optimizations based on the ‘constantness’ are valid for the translation units that do not include the definition.
As SSA values, global variables define pointer values that are in scope (i.e. they dominate) all basic blocks in the program. Global variables always define a pointer to their “content” type because they describe a region of memory, and all memory objects in LLVM are accessed through pointers.
Global variables can be marked with unnamed_addr which indicates that the address is not significant, only the content. Constants marked like this can be merged with other constants if they have the same initializer. Note that a constant with significant address can be merged with a unnamed_addr constant, the result being a constant whose address is significant.
If the local_unnamed_addr attribute is given, the address is known to not be significant within the module.
A global variable may be declared to reside in a target-specific numbered address space. For targets that support them, address spaces may affect how optimizations are performed and/or what target instructions are used to access the variable. The default address space is zero. The address space qualifier must precede any other attributes.
LLVM allows an explicit section to be specified for globals. If the target supports it, it will emit globals to the section specified. Additionally, the global can placed in a comdat if the target has the necessary support.
External declarations may have an explicit section specified. Section information is retained in LLVM IR for targets that make use of this information. Attaching section information to an external declaration is an assertion that its definition is located in the specified section. If the definition is located in a different section, the behavior is undefined.
By default, global initializers are optimized by assuming that global variables defined within the module are not modified from their initial values before the start of the global initializer. This is true even for variables potentially accessible from outside the module, including those with external linkage or appearing in @llvm.used or dllexported variables. This assumption may be suppressed by marking the variable with externally_initialized.
An explicit alignment may be specified for a global, which must be a power of 2. If not present, or if the alignment is set to zero, the alignment of the global is set by the target to whatever it feels convenient. If an explicit alignment is specified, the global is forced to have exactly that alignment. Targets and optimizers are not allowed to over-align the global if the global has an assigned section. In this case, the extra alignment could be observable: for example, code could assume that the globals are densely packed in their section and try to iterate over them as an array, alignment padding would break this iteration. The maximum alignment is 1 << 29.
Globals can also have a DLL storage class, an optional runtime preemption specifier, an optional global attributes and an optional list of attached metadata.
Variables and aliases can have a Thread Local Storage Model.
Syntax:
@<GlobalVarName> = [Linkage] [PreemptionSpecifier] [Visibility]
[DLLStorageClass] [ThreadLocal]
[(unnamed_addr|local_unnamed_addr)] [AddrSpace]
[ExternallyInitialized]
<global | constant> <Type> [<InitializerConstant>]
[, section "name"] [, comdat [($name)]]
[, align <Alignment>] (, !name !N)*
For example, the following defines a global in a numbered address space with an initializer, section, and alignment:
@G = addrspace(5) constant float 1.0, section "foo", align 4
The following example just declares a global variable
@G = external global i32
The following example defines a thread-local global with the initialexec TLS model:
@G = thread_local(initialexec) global i32 0, align 4
LLVM function definitions consist of the “define” keyword, an optional linkage type, an optional runtime preemption specifier, an optional visibility style, an optional DLL storage class, an optional calling convention, an optional unnamed_addr attribute, a return type, an optional parameter attribute for the return type, a function name, a (possibly empty) argument list (each with optional parameter attributes), optional function attributes, an optional section, an optional alignment, an optional comdat, an optional garbage collector name, an optional prefix, an optional prologue, an optional personality, an optional list of attached metadata, an opening curly brace, a list of basic blocks, and a closing curly brace.
LLVM function declarations consist of the “declare” keyword, an optional linkage type, an optional visibility style, an optional DLL storage class, an optional calling convention, an optional unnamed_addr or local_unnamed_addr attribute, a return type, an optional parameter attribute for the return type, a function name, a possibly empty list of arguments, an optional alignment, an optional garbage collector name, an optional prefix, and an optional prologue.
A function definition contains a list of basic blocks, forming the CFG (Control Flow Graph) for the function. Each basic block may optionally start with a label (giving the basic block a symbol table entry), contains a list of instructions, and ends with a terminator instruction (such as a branch or function return). If an explicit label is not provided, a block is assigned an implicit numbered label, using the next value from the same counter as used for unnamed temporaries (see above). For example, if a function entry block does not have an explicit label, it will be assigned label “%0”, then the first unnamed temporary in that block will be “%1”, etc.
The first basic block in a function is special in two ways: it is immediately executed on entrance to the function, and it is not allowed to have predecessor basic blocks (i.e. there can not be any branches to the entry block of a function). Because the block can have no predecessors, it also cannot have any PHI nodes.
LLVM allows an explicit section to be specified for functions. If the target supports it, it will emit functions to the section specified. Additionally, the function can be placed in a COMDAT.
An explicit alignment may be specified for a function. If not present, or if the alignment is set to zero, the alignment of the function is set by the target to whatever it feels convenient. If an explicit alignment is specified, the function is forced to have at least that much alignment. All alignments must be a power of 2.
If the unnamed_addr attribute is given, the address is known to not be significant and two identical functions can be merged.
If the local_unnamed_addr attribute is given, the address is known to not be significant within the module.
Syntax:
define [linkage] [PreemptionSpecifier] [visibility] [DLLStorageClass]
[cconv] [ret attrs]
<ResultType> @<FunctionName> ([argument list])
[(unnamed_addr|local_unnamed_addr)] [fn Attrs] [section "name"]
[comdat [($name)]] [align N] [gc] [prefix Constant]
[prologue Constant] [personality Constant] (!name !N)* { ... }
The argument list is a comma separated sequence of arguments where each argument is of the following form:
Syntax:
<type> [parameter Attrs] [name]
Aliases, unlike function or variables, don’t create any new data. They are just a new symbol and metadata for an existing position.
Aliases have a name and an aliasee that is either a global value or a constant expression.
Aliases may have an optional linkage type, an optional runtime preemption specifier, an optional visibility style, an optional DLL storage class and an optional tls model.
Syntax:
@<Name> = [Linkage] [PreemptionSpecifier] [Visibility] [DLLStorageClass] [ThreadLocal] [(unnamed_addr|local_unnamed_addr)] alias <AliaseeTy>, <AliaseeTy>* @<Aliasee>
The linkage must be one of private, internal, linkonce, weak, linkonce_odr, weak_odr, external. Note that some system linkers might not correctly handle dropping a weak symbol that is aliased.
Aliases that are not unnamed_addr are guaranteed to have the same address as the aliasee expression. unnamed_addr ones are only guaranteed to point to the same content.
If the local_unnamed_addr attribute is given, the address is known to not be significant within the module.
Since aliases are only a second name, some restrictions apply, of which some can only be checked when producing an object file:
IFuncs, like as aliases, don’t create any new data or func. They are just a new symbol that dynamic linker resolves at runtime by calling a resolver function.
IFuncs have a name and a resolver that is a function called by dynamic linker that returns address of another function associated with the name.
IFunc may have an optional linkage type and an optional visibility style.
Syntax:
@<Name> = [Linkage] [Visibility] ifunc <IFuncTy>, <ResolverTy>* @<Resolver>
Comdat IR provides access to COFF and ELF object file COMDAT functionality.
Comdats have a name which represents the COMDAT key. All global objects that specify this key will only end up in the final object file if the linker chooses that key over some other key. Aliases are placed in the same COMDAT that their aliasee computes to, if any.
Comdats have a selection kind to provide input on how the linker should choose between keys in two different object files.
Syntax:
$<Name> = comdat SelectionKind
The selection kind must be one of the following:
Note that the Mach-O platform doesn’t support COMDATs, and ELF and WebAssembly only support any as a selection kind.
Here is an example of a COMDAT group where a function will only be selected if the COMDAT key’s section is the largest:
$foo = comdat largest
@foo = global i32 2, comdat($foo)
define void @bar() comdat($foo) {
ret void
}
As a syntactic sugar the $name can be omitted if the name is the same as the global name:
$foo = comdat any
@foo = global i32 2, comdat
In a COFF object file, this will create a COMDAT section with selection kind IMAGE_COMDAT_SELECT_LARGEST containing the contents of the @foo symbol and another COMDAT section with selection kind IMAGE_COMDAT_SELECT_ASSOCIATIVE which is associated with the first COMDAT section and contains the contents of the @bar symbol.
There are some restrictions on the properties of the global object. It, or an alias to it, must have the same name as the COMDAT group when targeting COFF. The contents and size of this object may be used during link-time to determine which COMDAT groups get selected depending on the selection kind. Because the name of the object must match the name of the COMDAT group, the linkage of the global object must not be local; local symbols can get renamed if a collision occurs in the symbol table.
The combined use of COMDATS and section attributes may yield surprising results. For example:
$foo = comdat any
$bar = comdat any
@g1 = global i32 42, section "sec", comdat($foo)
@g2 = global i32 42, section "sec", comdat($bar)
From the object file perspective, this requires the creation of two sections with the same name. This is necessary because both globals belong to different COMDAT groups and COMDATs, at the object file level, are represented by sections.
Note that certain IR constructs like global variables and functions may create COMDATs in the object file in addition to any which are specified using COMDAT IR. This arises when the code generator is configured to emit globals in individual sections (e.g. when -data-sections or -function-sections is supplied to llc).
Named metadata is a collection of metadata. Metadata nodes (but not metadata strings) are the only valid operands for a named metadata.
Syntax:
; Some unnamed metadata nodes, which are referenced by the named metadata.
!0 = !{!"zero"}
!1 = !{!"one"}
!2 = !{!"two"}
; A named metadata.
!name = !{!0, !1, !2}
The return type and each parameter of a function type may have a set of parameter attributes associated with them. Parameter attributes are used to communicate additional information about the result or parameters of a function. Parameter attributes are considered to be part of the function, not of the function type, so functions with different parameter attributes can have the same function type.
Parameter attributes are simple keywords that follow the type specified. If multiple parameter attributes are needed, they are space separated. For example:
declare i32 @printf(i8* noalias nocapture, ...)
declare i32 @atoi(i8 zeroext)
declare signext i8 @returns_signed_char()
Note that any attributes for the function result (nounwind, readonly) come immediately after the argument list.
Currently, only the following parameter attributes are defined:
This indicates that the pointer parameter should really be passed by value to the function. The attribute implies that a hidden copy of the pointee is made between the caller and the callee, so the callee is unable to modify the value in the caller. This attribute is only valid on LLVM pointer arguments. It is generally used to pass structs and arrays by value, but is also valid on pointers to scalars. The copy is considered to belong to the caller not the callee (for example, readonly functions should not write to byval parameters). This is not a valid attribute for return values.
The byval attribute also supports specifying an alignment with the align attribute. It indicates the alignment of the stack slot to form and the known alignment of the pointer specified to the call site. If the alignment is not specified, then the code generator makes a target-specific assumption.
inalloca
The inalloca argument attribute allows the caller to take the address of outgoing stack arguments. An inalloca argument must be a pointer to stack memory produced by an alloca instruction. The alloca, or argument allocation, must also be tagged with the inalloca keyword. Only the last argument may have the inalloca attribute, and that argument is guaranteed to be passed in memory.
An argument allocation may be used by a call at most once because the call may deallocate it. The inalloca attribute cannot be used in conjunction with other attributes that affect argument storage, like inreg, nest, sret, or byval. The inalloca attribute also disables LLVM’s implicit lowering of large aggregate return values, which means that frontend authors must lower them with sret pointers.
When the call site is reached, the argument allocation must have been the most recent stack allocation that is still live, or the behavior is undefined. It is possible to allocate additional stack space after an argument allocation and before its call site, but it must be cleared off with llvm.stackrestore.
See Design and Usage of the InAlloca Attribute for more information on how to use this attribute.
This indicates that the pointer value may be assumed by the optimizer to have the specified alignment.
Note that this attribute has additional semantics when combined with the byval attribute.
This indicates that objects accessed via pointer values based on the argument or return value are not also accessed, during the execution of the function, via pointer values not based on the argument or return value. The attribute on a return value also has additional semantics described below. The caller shares the responsibility with the callee for ensuring that these requirements are met. For further details, please see the discussion of the NoAlias response in alias analysis.
Note that this definition of noalias is intentionally similar to the definition of restrict in C99 for function arguments.
For function return values, C99’s restrict is not meaningful, while LLVM’s noalias is. Furthermore, the semantics of the noalias attribute on return values are stronger than the semantics of the attribute when used on function arguments. On function return values, the noalias attribute indicates that the function acts like a system memory allocation function, returning a pointer to allocated storage disjoint from the storage for any other object accessible to the caller.
This attribute is motivated to model and optimize Swift error handling. It can be applied to a parameter with pointer to pointer type or a pointer-sized alloca. At the call site, the actual argument that corresponds to a swifterror parameter has to come from a swifterror alloca or the swifterror parameter of the caller. A swifterror value (either the parameter or the alloca) can only be loaded and stored from, or used as a swifterror argument. This is not a valid attribute for return values and can only be applied to one parameter.
These constraints allow the calling convention to optimize access to swifterror variables by associating them with a specific register at call boundaries rather than placing them in memory. Since this does change the calling convention, a function which uses the swifterror attribute on a parameter is not ABI-compatible with one which does not.
These constraints also allow LLVM to assume that a swifterror argument does not alias any other memory visible within a function and that a swifterror alloca passed as an argument does not escape.
Each function may specify a garbage collector strategy name, which is simply a string:
define void @f() gc "name" { ... }
The supported values of name includes those built in to LLVM and any provided by loaded plugins. Specifying a GC strategy will cause the compiler to alter its output in order to support the named garbage collection algorithm. Note that LLVM itself does not contain a garbage collector, this functionality is restricted to generating machine code which can interoperate with a collector provided externally.
Prefix data is data associated with a function which the code generator will emit immediately before the function’s entrypoint. The purpose of this feature is to allow frontends to associate language-specific runtime metadata with specific functions and make it available through the function pointer while still allowing the function pointer to be called.
To access the data for a given function, a program may bitcast the function pointer to a pointer to the constant’s type and dereference index -1. This implies that the IR symbol points just past the end of the prefix data. For instance, take the example of a function annotated with a single i32,
define void @f() prefix i32 123 { ... }
The prefix data can be referenced as,
%0 = bitcast void* () @f to i32*
%a = getelementptr inbounds i32, i32* %0, i32 -1
%b = load i32, i32* %a
Prefix data is laid out as if it were an initializer for a global variable of the prefix data’s type. The function will be placed such that the beginning of the prefix data is aligned. This means that if the size of the prefix data is not a multiple of the alignment size, the function’s entrypoint will not be aligned. If alignment of the function’s entrypoint is desired, padding must be added to the prefix data.
A function may have prefix data but no body. This has similar semantics to the available_externally linkage in that the data may be used by the optimizers but will not be emitted in the object file.
The prologue attribute allows arbitrary code (encoded as bytes) to be inserted prior to the function body. This can be used for enabling function hot-patching and instrumentation.
To maintain the semantics of ordinary function calls, the prologue data must have a particular format. Specifically, it must begin with a sequence of bytes which decode to a sequence of machine instructions, valid for the module’s target, which transfer control to the point immediately succeeding the prologue data, without performing any other visible action. This allows the inliner and other passes to reason about the semantics of the function definition without needing to reason about the prologue data. Obviously this makes the format of the prologue data highly target dependent.
A trivial example of valid prologue data for the x86 architecture is i8 144, which encodes the nop instruction:
define void @f() prologue i8 144 { ... }
Generally prologue data can be formed by encoding a relative branch instruction which skips the metadata, as in this example of valid prologue data for the x86_64 architecture, where the first two bytes encode jmp .+10:
%0 = type <{ i8, i8, i8* }>
define void @f() prologue %0 <{ i8 235, i8 8, i8* @md}> { ... }
A function may have prologue data but no body. This has similar semantics to the available_externally linkage in that the data may be used by the optimizers but will not be emitted in the object file.
The personality attribute permits functions to specify what function to use for exception handling.
Attribute groups are groups of attributes that are referenced by objects within the IR. They are important for keeping .ll files readable, because a lot of functions will use the same set of attributes. In the degenerative case of a .ll file that corresponds to a single .c file, the single attribute group will capture the important command line flags used to build that file.
An attribute group is a module-level object. To use an attribute group, an object references the attribute group’s ID (e.g. #37). An object may refer to more than one attribute group. In that situation, the attributes from the different groups are merged.
Here is an example of attribute groups for a function that should always be inlined, has a stack alignment of 4, and which shouldn’t use SSE instructions:
; Target-independent attributes:
attributes #0 = { alwaysinline alignstack=4 }
; Target-dependent attributes:
attributes #1 = { "no-sse" }
; Function @f has attributes: alwaysinline, alignstack=4, and "no-sse".
define void @f() #0 #1 { ... }
Function attributes are set to communicate additional information about a function. Function attributes are considered to be part of the function, not of the function type, so functions with different function attributes can have the same function type.
Function attributes are simple keywords that follow the type specified. If multiple attributes are needed, they are space separated. For example:
define void @f() noinline { ... }
define void @f() alwaysinline { ... }
define void @f() alwaysinline optsize { ... }
define void @f() optsize { ... }
In some parallel execution models, there exist operations that cannot be made control-dependent on any additional values. We call such operations convergent, and mark them with this attribute.
The convergent attribute may appear on functions or call/invoke instructions. When it appears on a function, it indicates that calls to this function should not be made control-dependent on additional values. For example, the intrinsic llvm.nvvm.barrier0 is convergent, so calls to this intrinsic cannot be made control-dependent on additional values.
When it appears on a call/invoke, the convergent attribute indicates that we should treat the call as though we’re calling a convergent function. This is particularly useful on indirect calls; without this we may treat such calls as though the target is non-convergent.
The optimizer may remove the convergent attribute on functions when it can prove that the function does not execute any convergent operations. Similarly, the optimizer may remove convergent on calls/invokes when it can prove that the call/invoke cannot call a convergent function.
This attribute indicates that calls to the function cannot be duplicated. A call to a noduplicate function may be moved within its parent function, but may not be duplicated within its parent function.
A function containing a noduplicate call may still be an inlining candidate, provided that the call is not duplicated by inlining. That implies that the function has internal linkage and only has one call site, so the original call is dead after inlining.
This function attribute indicates that most optimization passes will skip this function, with the exception of interprocedural optimization passes. Code generation defaults to the “fast” instruction selector. This attribute cannot be used together with the alwaysinline attribute; this attribute is also incompatible with the minsize attribute and the optsize attribute.
This attribute requires the noinline attribute to be specified on the function as well, so the function is never inlined into any caller. Only functions with the alwaysinline attribute are valid candidates for inlining into the body of this function.
This attribute tells the code generator that the code generated for this function needs to follow certain conventions that make it possible for a runtime function to patch over it later. The exact effect of this attribute depends on its string value, for which there currently is one legal possibility:
"prologue-short-redirect" - This style of patchable function is intended to support patching a function prologue to redirect control away from the function in a thread safe manner. It guarantees that the first instruction of the function will be large enough to accommodate a short jump instruction, and will be sufficiently aligned to allow being fully changed via an atomic compare-and-swap instruction. While the first requirement can be satisfied by inserting large enough NOP, LLVM can and will try to re-purpose an existing instruction (i.e. one that would have to be emitted anyway) as the patchable instruction larger than a short jump.
"prologue-short-redirect" is currently only supported on x86-64.
This attribute by itself does not imply restrictions on inter-procedural optimizations. All of the semantic effects the patching may have to be separately conveyed via the linkage type.
This attribute indicates that the function will trigger a guard region in the end of the stack. It ensures that accesses to the stack must be no further apart than the size of the guard region to a previous access of the stack. It takes one required string value, the name of the stack probing function that will be called.
If a function that has a "probe-stack" attribute is inlined into a function with another "probe-stack" attribute, the resulting function has the "probe-stack" attribute of the caller. If a function that has a "probe-stack" attribute is inlined into a function that has no "probe-stack" attribute at all, the resulting function has the "probe-stack" attribute of the callee.
On a function, this attribute indicates that the function computes its result (or decides to unwind an exception) based strictly on its arguments, without dereferencing any pointer arguments or otherwise accessing any mutable state (e.g. memory, control registers, etc) visible to caller functions. It does not write through any pointer arguments (including byval arguments) and never changes any state visible to callers. This means while it cannot unwind exceptions by calling the C++ exception throwing methods (since they write to memory), there may be non-C++ mechanisms that throw exceptions without writing to LLVM visible memory.
On an argument, this attribute indicates that the function does not dereference that pointer argument, even though it may read or write the memory that the pointer points to if accessed through other pointers.
If a readnone function reads or writes memory visible to the program, or has other side-effects, the behavior is undefined. If a function reads from or writes to a readnone pointer argument, the behavior is undefined.
On a function, this attribute indicates that the function does not write through any pointer arguments (including byval arguments) or otherwise modify any state (e.g. memory, control registers, etc) visible to caller functions. It may dereference pointer arguments and read state that may be set in the caller. A readonly function always returns the same value (or unwinds an exception identically) when called with the same set of arguments and global state. This means while it cannot unwind exceptions by calling the C++ exception throwing methods (since they write to memory), there may be non-C++ mechanisms that throw exceptions without writing to LLVM visible memory.
On an argument, this attribute indicates that the function does not write through this pointer argument, even though it may write to the memory that the pointer points to.
If a readonly function writes memory visible to the program, or has other side-effects, the behavior is undefined. If a function writes to a readonly pointer argument, the behavior is undefined.
This attribute controls the behavior of stack probes: either the "probe-stack" attribute, or ABI-required stack probes, if any. It defines the size of the guard region. It ensures that if the function may use more stack space than the size of the guard region, stack probing sequence will be emitted. It takes one required integer value, which is 4096 by default.
If a function that has a "stack-probe-size" attribute is inlined into a function with another "stack-probe-size" attribute, the resulting function has the "stack-probe-size" attribute that has the lower numeric value. If a function that has a "stack-probe-size" attribute is inlined into a function that has no "stack-probe-size" attribute at all, the resulting function has the "stack-probe-size" attribute of the callee.
On a function, this attribute indicates that the function may write to but does not read from memory.
On an argument, this attribute indicates that the function may write to but does not read through this pointer argument (even though it may read from the memory that the pointer points to).
If a writeonly function reads memory visible to the program, or has other side-effects, the behavior is undefined. If a function reads from a writeonly pointer argument, the behavior is undefined.
This attribute indicates that the only memory accesses inside function are loads and stores from objects pointed to by its pointer-typed arguments, with arbitrary offsets. Or in other words, all memory operations in the function can refer to memory only using pointers based on its function arguments.
Note that argmemonly can be used together with readonly attribute in order to specify that function reads only from its arguments.
If an argmemonly function reads or writes memory other than the pointer arguments, or has other side-effects, the behavior is undefined.
This attribute indicates that SafeStack protection is enabled for this function.
If a function that has a safestack attribute is inlined into a function that doesn’t have a safestack attribute or which has an ssp, sspstrong or sspreq attribute, then the resulting function will have a safestack attribute.
This attribute indicates that the function should emit a stack smashing protector. It is in the form of a “canary” — a random value placed on the stack before the local variables that’s checked upon return from the function to see if it has been overwritten. A heuristic is used to determine if a function needs stack protectors or not. The heuristic used will enable protectors for functions with:
Variables that are identified as requiring a protector will be arranged on the stack such that they are adjacent to the stack protector guard.
If a function that has an ssp attribute is inlined into a function that doesn’t have an ssp attribute, then the resulting function will have an ssp attribute.
This attribute indicates that the function should always emit a stack smashing protector. This overrides the ssp function attribute.
Variables that are identified as requiring a protector will be arranged on the stack such that they are adjacent to the stack protector guard. The specific layout rules are:
If a function that has an sspreq attribute is inlined into a function that doesn’t have an sspreq attribute or which has an ssp or sspstrong attribute, then the resulting function will have an sspreq attribute.
This attribute indicates that the function should emit a stack smashing protector. This attribute causes a strong heuristic to be used when determining if a function needs stack protectors. The strong heuristic will enable protectors for functions with:
Variables that are identified as requiring a protector will be arranged on the stack such that they are adjacent to the stack protector guard. The specific layout rules are:
This overrides the ssp function attribute.
If a function that has an sspstrong attribute is inlined into a function that doesn’t have an sspstrong attribute, then the resulting function will have an sspstrong attribute.
Attributes may be set to communicate additional information about a global variable. Unlike function attributes, attributes on a global variable are grouped into a single attribute group.
Operand bundles are tagged sets of SSA values that can be associated with certain LLVM instructions (currently only call s and invoke s). In a way they are like metadata, but dropping them is incorrect and will change program semantics.
Syntax:
operand bundle set ::= '[' operand bundle (, operand bundle )* ']'
operand bundle ::= tag '(' [ bundle operand ] (, bundle operand )* ')'
bundle operand ::= SSA value
tag ::= string constant
Operand bundles are not part of a function’s signature, and a given function may be called from multiple places with different kinds of operand bundles. This reflects the fact that the operand bundles are conceptually a part of the call (or invoke), not the callee being dispatched to.
Operand bundles are a generic mechanism intended to support runtime-introspection-like functionality for managed languages. While the exact semantics of an operand bundle depend on the bundle tag, there are certain limitations to how much the presence of an operand bundle can influence the semantics of a program. These restrictions are described as the semantics of an “unknown” operand bundle. As long as the behavior of an operand bundle is describable within these restrictions, LLVM does not need to have special knowledge of the operand bundle to not miscompile programs containing it.
More specific types of operand bundles are described below.
Deoptimization operand bundles are characterized by the "deopt" operand bundle tag. These operand bundles represent an alternate “safe” continuation for the call site they’re attached to, and can be used by a suitable runtime to deoptimize the compiled frame at the specified call site. There can be at most one "deopt" operand bundle attached to a call site. Exact details of deoptimization is out of scope for the language reference, but it usually involves rewriting a compiled frame into a set of interpreted frames.
From the compiler’s perspective, deoptimization operand bundles make the call sites they’re attached to at least readonly. They read through all of their pointer typed operands (even if they’re not otherwise escaped) and the entire visible heap. Deoptimization operand bundles do not capture their operands except during deoptimization, in which case control will not be returned to the compiled frame.
The inliner knows how to inline through calls that have deoptimization operand bundles. Just like inlining through a normal call site involves composing the normal and exceptional continuations, inlining through a call site with a deoptimization operand bundle needs to appropriately compose the “safe” deoptimization continuation. The inliner does this by prepending the parent’s deoptimization continuation to every deoptimization continuation in the inlined body. E.g. inlining @f into @g in the following example
define void @f() {
call void @x() ;; no deopt state
call void @y() [ "deopt"(i32 10) ]
call void @y() [ "deopt"(i32 10), "unknown"(i8* null) ]
ret void
}
define void @g() {
call void @f() [ "deopt"(i32 20) ]
ret void
}
will result in
define void @g() {
call void @x() ;; still no deopt state
call void @y() [ "deopt"(i32 20, i32 10) ]
call void @y() [ "deopt"(i32 20, i32 10), "unknown"(i8* null) ]
ret void
}
It is the frontend’s responsibility to structure or encode the deoptimization state in a way that syntactically prepending the caller’s deoptimization state to the callee’s deoptimization state is semantically equivalent to composing the caller’s deoptimization continuation after the callee’s deoptimization continuation.
Funclet operand bundles are characterized by the "funclet" operand bundle tag. These operand bundles indicate that a call site is within a particular funclet. There can be at most one "funclet" operand bundle attached to a call site and it must have exactly one bundle operand.
If any funclet EH pads have been “entered” but not “exited” (per the description in the EH doc), it is undefined behavior to execute a call or invoke which:
Similarly, if no funclet EH pads have been entered-but-not-yet-exited, executing a call or invoke with a "funclet" bundle is undefined behavior.
GC transition operand bundles are characterized by the "gc-transition" operand bundle tag. These operand bundles mark a call as a transition between a function with one GC strategy to a function with a different GC strategy. If coordinating the transition between GC strategies requires additional code generation at the call site, these bundles may contain any values that are needed by the generated code. For more details, see GC Transitions.
Modules may contain “module-level inline asm” blocks, which corresponds to the GCC “file scope inline asm” blocks. These blocks are internally concatenated by LLVM and treated as a single unit, but may be separated in the .ll file if desired. The syntax is very simple:
module asm "inline asm code goes here"
module asm "more can go here"
The strings can contain any character by escaping non-printable characters. The escape sequence used is simply “\xx” where “xx” is the two digit hex code for the number.
Note that the assembly string must be parseable by LLVM’s integrated assembler (unless it is disabled), even when emitting a .s file.
A module may specify a target specific data layout string that specifies how data is to be laid out in memory. The syntax for the data layout is simply:
target datalayout = "layout specification"
The layout specification consists of a list of specifications separated by the minus sign character (‘-‘). Each specification starts with a letter and may include other information after the letter to define some aspect of the data layout. The specifications accepted are as follows:
If present, specifies that llvm names are mangled in the output. Symbols prefixed with the mangling escape character \01 are passed through directly to the assembler without the escape character. The mangling style options are
On every specification that takes a <abi>:<pref>, specifying the <pref> alignment is optional. If omitted, the preceding : should be omitted too and <pref> will be equal to <abi>.
When constructing the data layout for a given target, LLVM starts with a default set of specifications which are then (possibly) overridden by the specifications in the datalayout keyword. The default specifications are given in this list:
When LLVM is determining the alignment for a given type, it uses the following rules:
The function of the data layout string may not be what you expect. Notably, this is not a specification from the frontend of what alignment the code generator should use.
Instead, if specified, the target data layout is required to match what the ultimate code generator expects. This string is used by the mid-level optimizers to improve code, and this only works if it matches what the ultimate code generator uses. There is no way to generate IR that does not embed this target-specific detail into the IR. If you don’t specify the string, the default specifications will be used to generate a Data Layout and the optimization phases will operate accordingly and introduce target specificity into the IR with respect to these default specifications.
A module may specify a target triple string that describes the target host. The syntax for the target triple is simply:
target triple = "x86_64-apple-macosx10.7.0"
The target triple string consists of a series of identifiers delimited by the minus sign character (‘-‘). The canonical forms are:
ARCHITECTURE-VENDOR-OPERATING_SYSTEM
ARCHITECTURE-VENDOR-OPERATING_SYSTEM-ENVIRONMENT
This information is passed along to the backend so that it generates code for the proper architecture. It’s possible to override this on the command line with the -mtriple command line option.
Any memory access must be done through a pointer value associated with an address range of the memory access, otherwise the behavior is undefined. Pointer values are associated with address ranges according to the following rules:
A pointer value is based on another pointer value according to the following rules:
Note that this definition of “based” is intentionally similar to the definition of “based” in C99, though it is slightly weaker.
LLVM IR does not associate types with memory. The result type of a load merely indicates the size and alignment of the memory from which to load, as well as the interpretation of the value. The first operand type of a store similarly only indicates the size and alignment of the store.
Consequently, type-based alias analysis, aka TBAA, aka -fstrict-aliasing, is not applicable to general unadorned LLVM IR. Metadata may be used to encode additional information which specialized optimization passes may use to implement type-based alias analysis.
Certain memory accesses, such as load‘s, store‘s, and llvm.memcpy‘s may be marked volatile. The optimizers must not change the number of volatile operations or change their order of execution relative to other volatile operations. The optimizers may change the order of volatile operations relative to non-volatile operations. This is not Java’s “volatile” and has no cross-thread synchronization behavior.
IR-level volatile loads and stores cannot safely be optimized into llvm.memcpy or llvm.memmove intrinsics even when those intrinsics are flagged volatile. Likewise, the backend should never split or merge target-legal volatile load/store instructions.
Rationale
Platforms may rely on volatile loads and stores of natively supported data width to be executed as single instruction. For example, in C this holds for an l-value of volatile primitive type with native hardware support, but not necessarily for aggregate types. The frontend upholds these expectations, which are intentionally unspecified in the IR. The rules above ensure that IR transformations do not violate the frontend’s contract with the language.
The LLVM IR does not define any way to start parallel threads of execution or to register signal handlers. Nonetheless, there are platform-specific ways to create them, and we define LLVM IR’s behavior in their presence. This model is inspired by the C++0x memory model.
For a more informal introduction to this model, see the LLVM Atomic Instructions and Concurrency Guide.
We define a happens-before partial order as the least partial order that
Note that program order does not introduce happens-before edges between a thread and signals executing inside that thread.
Every (defined) read operation (load instructions, memcpy, atomic loads/read-modify-writes, etc.) R reads a series of bytes written by (defined) write operations (store instructions, atomic stores/read-modify-writes, memcpy, etc.). For the purposes of this section, initialized globals are considered to have a write of the initializer which is atomic and happens before any other read or write of the memory in question. For each byte of a read R, Rbyte may see any write to the same byte, except:
Given that definition, Rbyte is defined as follows:
R returns the value composed of the series of bytes it read. This implies that some bytes within the value may be undef without the entire value being undef. Note that this only defines the semantics of the operation; it doesn’t mean that targets will emit more than one instruction to read the series of bytes.
Note that in cases where none of the atomic intrinsics are used, this model places only one restriction on IR transformations on top of what is required for single-threaded execution: introducing a store to a byte which might not otherwise be stored is not allowed in general. (Specifically, in the case where another thread might write to and read from an address, introducing a store can change a load that may see exactly one write into a load that may see multiple writes.)
Atomic instructions (cmpxchg, atomicrmw, fence, atomic load, and atomic store) take ordering parameters that determine which other atomic instructions on the same address they synchronize with. These semantics are borrowed from Java and C++0x, but are somewhat more colloquial. If these descriptions aren’t precise enough, check those specs (see spec references in the atomics guide). fence instructions treat these orderings somewhat differently since they don’t take an address. See that instruction’s documentation for details.
For a simpler introduction to the ordering constraints, see the LLVM Atomic Instructions and Concurrency Guide.
If an atomic operation is marked syncscope("singlethread"), it only synchronizes with and only participates in the seq_cst total orderings of other operations running in the same thread (for example, in signal handlers).
If an atomic operation is marked syncscope("<target-scope>"), where <target-scope> is a target specific synchronization scope, then it is target dependent if it synchronizes with and participates in the seq_cst total orderings of other operations.
Otherwise, an atomic operation that is not marked syncscope("singlethread") or syncscope("<target-scope>") synchronizes with and participates in the seq_cst total orderings of other operations that are not marked syncscope("singlethread") or syncscope("<target-scope>").
The default LLVM floating-point environment assumes that floating-point instructions do not have side effects. Results assume the round-to-nearest rounding mode. No floating-point exception state is maintained in this environment. Therefore, there is no attempt to create or preserve invalid operation (SNaN) or division-by-zero exceptions in these examples:
%A = fdiv 0x7ff0000000000001, %X ; 64-bit SNaN hex value
%B = fdiv %X, 0.0
Safe:
%A = NaN
%B = NaN
The benefit of this exception-free assumption is that floating-point operations may be speculated freely without any other fast-math relaxations to the floating-point model.
Code that requires different behavior than this should use the Constrained Floating-Point Intrinsics.
LLVM IR floating-point operations (fadd, fsub, fmul, fdiv, frem, fcmp) and call may use the following flags to enable otherwise unsafe floating-point transformations.
Use-list directives encode the in-memory order of each use-list, allowing the order to be recreated. <order-indexes> is a comma-separated list of indexes that are assigned to the referenced value’s uses. The referenced value’s use-list is immediately sorted by these indexes.
Use-list directives may appear at function scope or global scope. They are not instructions, and have no effect on the semantics of the IR. When they’re at function scope, they must appear after the terminator of the final basic block.
If basic blocks have their address taken via blockaddress() expressions, uselistorder_bb can be used to reorder their use-lists from outside their function’s scope.
Syntax: |
---|
uselistorder <ty> <value>, { <order-indexes> }
uselistorder_bb @function, %block { <order-indexes> }
Examples: |
---|
define void @foo(i32 %arg1, i32 %arg2) {
entry:
; ... instructions ...
bb:
; ... instructions ...
; At function scope.
uselistorder i32 %arg1, { 1, 0, 2 }
uselistorder label %bb, { 1, 0 }
}
; At global scope.
uselistorder i32* @global, { 1, 2, 0 }
uselistorder i32 7, { 1, 0 }
uselistorder i32 (i32) @bar, { 1, 0 }
uselistorder_bb @foo, %bb, { 5, 1, 3, 2, 0, 4 }
The source filename string is set to the original module identifier, which will be the name of the compiled source file when compiling from source through the clang front end, for example. It is then preserved through the IR and bitcode.
This is currently necessary to generate a consistent unique global identifier for local functions used in profile data, which prepends the source file name to the local function name.
The syntax for the source file name is simply:
source_filename = "/path/to/source.c"
The LLVM type system is one of the most important features of the intermediate representation. Being typed enables a number of optimizations to be performed on the intermediate representation directly, without having to do extra analyses on the side before the transformation. A strong type system makes it easier to read the generated code and enables novel analyses and transformations that are not feasible to perform on normal three address code representations.
Overview: |
---|
The function type can be thought of as a function signature. It consists of a return type and a list of formal parameter types. The return type of a function type is a void type or first class type — except for label and metadata types.
Syntax: |
---|
<returntype> (<parameter list>)
...where ‘<parameter list>‘ is a comma-separated list of type specifiers. Optionally, the parameter list may include a type ..., which indicates that the function takes a variable number of arguments. Variable argument functions can access their arguments with the variable argument handling intrinsic functions. ‘<returntype>‘ is any type except label and metadata.
Examples: |
---|
i32 (i32) | function taking an i32, returning an i32 |
float (i16, i32 *) * | Pointer to a function that takes an i16 and a pointer to i32, returning float. |
i32 (i8*, ...) | A vararg function that takes at least one pointer to i8 (char in C), which returns an integer. This is the signature for printf in LLVM. |
{i32, i32} (i32) | A function taking an i32, returning a structure containing two i32 values |
The first class types are perhaps the most important. Values of these types are the only ones which can be produced by instructions.
These are the types that are valid in registers from CodeGen’s perspective.
Overview: |
---|
The integer type is a very simple type that simply specifies an arbitrary bit width for the integer type desired. Any bit width from 1 bit to 223-1 (about 8 million) can be specified.
Syntax: |
---|
iN
The number of bits the integer will occupy is specified by the N value.
i1 | a single-bit integer. |
i32 | a 32-bit integer. |
i1942652 | a really big integer of over 1 million bits. |
Type | Description |
---|---|
half | 16-bit floating-point value |
float | 32-bit floating-point value |
double | 64-bit floating-point value |
fp128 | 128-bit floating-point value (112-bit mantissa) |
x86_fp80 | 80-bit floating-point value (X87) |
ppc_fp128 | 128-bit floating-point value (two 64-bits) |
The binary format of half, float, double, and fp128 correspond to the IEEE-754-2008 specifications for binary16, binary32, binary64, and binary128 respectively.
Overview: |
---|
The x86_mmx type represents a value held in an MMX register on an x86 machine. The operations allowed on it are quite limited: parameters and return values, load and store, and bitcast. User-specified MMX instructions are represented as intrinsic or asm calls with arguments and/or results of this type. There are no arrays, vectors or constants of this type.
Syntax: |
---|
x86_mmx
Overview: |
---|
The pointer type is used to specify memory locations. Pointers are commonly used to reference objects in memory.
Pointer types may have an optional address space attribute defining the numbered address space where the pointed-to object resides. The default address space is number zero. The semantics of non-zero address spaces are target-specific.
Note that LLVM does not permit pointers to void (void*) nor does it permit pointers to labels (label*). Use i8* instead.
Syntax: |
---|
<type> *
Examples: |
---|
[4 x i32]* | A pointer to array of four i32 values. |
i32 (i32*) * | A pointer to a function that takes an i32*, returning an i32. |
i32 addrspace(5)* | A pointer to an i32 value that resides in address space #5. |
Overview: |
---|
A vector type is a simple derived type that represents a vector of elements. Vector types are used when multiple primitive data are operated in parallel using a single instruction (SIMD). A vector type requires a size (number of elements) and an underlying primitive data type. Vector types are considered first class.
Syntax: |
---|
< <# elements> x <elementtype> >
The number of elements is a constant integer value larger than 0; elementtype may be any integer, floating-point or pointer type. Vectors of size zero are not allowed.
Examples: |
---|
<4 x i32> | Vector of 4 32-bit integer values. |
<8 x float> | Vector of 8 32-bit floating-point values. |
<2 x i64> | Vector of 2 64-bit integer values. |
<4 x i64*> | Vector of 4 pointers to 64-bit integer values. |
Overview: |
---|
The token type is used when a value is associated with an instruction but all uses of the value must not attempt to introspect or obscure it. As such, it is not appropriate to have a phi or select of type token.
Syntax: |
---|
token
Overview: |
---|
The metadata type represents embedded metadata. No derived types may be created from metadata except for function arguments.
Syntax: |
---|
metadata
Aggregate Types are a subset of derived types that can contain multiple member types. Arrays and structs are aggregate types. Vectors are not considered to be aggregate types.
Overview: |
---|
The array type is a very simple derived type that arranges elements sequentially in memory. The array type requires a size (number of elements) and an underlying data type.
Syntax: |
---|
[<# elements> x <elementtype>]
The number of elements is a constant integer value; elementtype may be any type with a size.
Examples: |
---|
[40 x i32] | Array of 40 32-bit integer values. |
[41 x i32] | Array of 41 32-bit integer values. |
[4 x i8] | Array of 4 8-bit integer values. |
Here are some examples of multidimensional arrays:
[3 x [4 x i32]] | 3x4 array of 32-bit integer values. |
[12 x [10 x float]] | 12x10 array of single precision floating-point values. |
[2 x [3 x [4 x i16]]] | 2x3x4 array of 16-bit integer values. |
There is no restriction on indexing beyond the end of the array implied by a static type (though there are restrictions on indexing beyond the bounds of an allocated object in some cases). This means that single-dimension ‘variable sized array’ addressing can be implemented in LLVM with a zero length array type. An implementation of ‘pascal style arrays’ in LLVM could use the type “{ i32, [0 x float]}”, for example.
Overview: |
---|
The structure type is used to represent a collection of data members together in memory. The elements of a structure may be any type that has a size.
Structures in memory are accessed using ‘load‘ and ‘store‘ by getting a pointer to a field with the ‘getelementptr‘ instruction. Structures in registers are accessed using the ‘extractvalue‘ and ‘insertvalue‘ instructions.
Structures may optionally be “packed” structures, which indicate that the alignment of the struct is one byte, and that there is no padding between the elements. In non-packed structs, padding between field types is inserted as defined by the DataLayout string in the module, which is required to match what the underlying code generator expects.
Structures can either be “literal” or “identified”. A literal structure is defined inline with other types (e.g. {i32, i32}*) whereas identified types are always defined at the top level with a name. Literal types are uniqued by their contents and can never be recursive or opaque since there is no way to write one. Identified types can be recursive, can be opaqued, and are never uniqued.
Syntax: |
---|
%T1 = type { <type list> } ; Identified normal struct type
%T2 = type <{ <type list> }> ; Identified packed struct type
Examples: |
---|
{ i32, i32, i32 } | A triple of three i32 values |
{ float, i32 (i32) * } | A pair, where the first element is a float and the second element is a pointer to a function that takes an i32, returning an i32. |
<{ i8, i32 }> | A packed struct known to be 5 bytes in size. |
Overview: |
---|
Opaque structure types are used to represent named structure types that do not have a body specified. This corresponds (for example) to the C notion of a forward declared structure.
Syntax: |
---|
%X = type opaque
%52 = type opaque
Examples: |
---|
opaque | An opaque type. |
LLVM has several different basic types of constants. This section describes them all and their syntax.
The one non-intuitive notation for constants is the hexadecimal form of floating-point constants. For example, the form ‘double 0x432ff973cafa8000‘ is equivalent to (but harder to read than) ‘double 4.5e+15‘. The only time hexadecimal floating-point constants are required (and the only time that they are generated by the disassembler) is when a floating-point constant must be emitted but it cannot be represented as a decimal floating-point number in a reasonable number of digits. For example, NaN’s, infinities, and other special values are represented in their IEEE hexadecimal format so that assembly and disassembly do not cause any bits to change in the constants.
When using the hexadecimal form, constants of types half, float, and double are represented using the 16-digit form shown above (which matches the IEEE754 representation for double); half and float values must, however, be exactly representable as IEEE 754 half and single precision, respectively. Hexadecimal format is always used for long double, and there are three forms of long double. The 80-bit format used by x86 is represented as 0xK followed by 20 hexadecimal digits. The 128-bit format used by PowerPC (two adjacent doubles) is represented by 0xM followed by 32 hexadecimal digits. The IEEE 128-bit format is represented by 0xL followed by 32 hexadecimal digits. Long doubles will only work if they match the long double format on your target. The IEEE 16-bit format (half precision) is represented by 0xH followed by 4 hexadecimal digits. All hexadecimal formats are big-endian (sign bit at the left).
There are no constants of type x86_mmx.
Complex constants are a (potentially recursive) combination of simple constants and smaller complex constants.
The addresses of global variables and functions are always implicitly valid (link-time) constants. These constants are explicitly referenced when the identifier for the global is used and always have pointer type. For example, the following is a legal LLVM file:
@X = global i32 17
@Y = global i32 42
@Z = global [2 x i32*] [ i32* @X, i32* @Y ]
The string ‘undef‘ can be used anywhere a constant is expected, and indicates that the user of the value may receive an unspecified bit-pattern. Undefined values may be of any type (other than ‘label‘ or ‘void‘) and be used anywhere a constant is permitted.
Undefined values are useful because they indicate to the compiler that the program is well defined no matter what value is used. This gives the compiler more freedom to optimize. Here are some examples of (potentially surprising) transformations that are valid (in pseudo IR):
%A = add %X, undef
%B = sub %X, undef
%C = xor %X, undef
Safe:
%A = undef
%B = undef
%C = undef
This is safe because all of the output bits are affected by the undef bits. Any output bit can have a zero or one depending on the input bits.
%A = or %X, undef
%B = and %X, undef
Safe:
%A = -1
%B = 0
Safe:
%A = %X ;; By choosing undef as 0
%B = %X ;; By choosing undef as -1
Unsafe:
%A = undef
%B = undef
These logical operations have bits that are not always affected by the input. For example, if %X has a zero bit, then the output of the ‘and‘ operation will always be a zero for that bit, no matter what the corresponding bit from the ‘undef‘ is. As such, it is unsafe to optimize or assume that the result of the ‘and‘ is ‘undef‘. However, it is safe to assume that all bits of the ‘undef‘ could be 0, and optimize the ‘and‘ to 0. Likewise, it is safe to assume that all the bits of the ‘undef‘ operand to the ‘or‘ could be set, allowing the ‘or‘ to be folded to -1.
%A = select undef, %X, %Y
%B = select undef, 42, %Y
%C = select %X, %Y, undef
Safe:
%A = %X (or %Y)
%B = 42 (or %Y)
%C = %Y
Unsafe:
%A = undef
%B = undef
%C = undef
This set of examples shows that undefined ‘select‘ (and conditional branch) conditions can go either way, but they have to come from one of the two operands. In the %A example, if %X and %Y were both known to have a clear low bit, then %A would have to have a cleared low bit. However, in the %C example, the optimizer is allowed to assume that the ‘undef‘ operand could be the same as %Y, allowing the whole ‘select‘ to be eliminated.
%A = xor undef, undef
%B = undef
%C = xor %B, %B
%D = undef
%E = icmp slt %D, 4
%F = icmp gte %D, 4
Safe:
%A = undef
%B = undef
%C = undef
%D = undef
%E = undef
%F = undef
This example points out that two ‘undef‘ operands are not necessarily the same. This can be surprising to people (and also matches C semantics) where they assume that “X^X” is always zero, even if X is undefined. This isn’t true for a number of reasons, but the short answer is that an ‘undef‘ “variable” can arbitrarily change its value over its “live range”. This is true because the variable doesn’t actually have a live range. Instead, the value is logically read from arbitrary registers that happen to be around when needed, so the value is not necessarily consistent over time. In fact, %A and %C need to have the same semantics or the core LLVM “replace all uses with” concept would not hold.
%A = sdiv undef, %X
%B = sdiv %X, undef
Safe:
%A = 0
b: unreachable
These examples show the crucial difference between an undefined value and undefined behavior. An undefined value (like ‘undef‘) is allowed to have an arbitrary bit-pattern. This means that the %A operation can be constant folded to ‘0‘, because the ‘undef‘ could be zero, and zero divided by any value is zero. However, in the second example, we can make a more aggressive assumption: because the undef is allowed to be an arbitrary value, we are allowed to assume that it could be zero. Since a divide by zero has undefined behavior, we are allowed to assume that the operation does not execute at all. This allows us to delete the divide and all code after it. Because the undefined operation “can’t happen”, the optimizer can assume that it occurs in dead code.
a: store undef -> %X
b: store %X -> undef
Safe:
a: <deleted>
b: unreachable
A store of an undefined value can be assumed to not have any effect; we can assume that the value is overwritten with bits that happen to match what was already there. However, a store to an undefined location could clobber arbitrary memory, therefore, it has undefined behavior.
Poison values are similar to undef values, however they also represent the fact that an instruction or constant expression that cannot evoke side effects has nevertheless detected a condition that results in undefined behavior.
There is currently no way of representing a poison value in the IR; they only exist when produced by operations such as add with the nsw flag.
Poison value behavior is defined in terms of value dependence:
Poison values have the same behavior as undef values, with the additional effect that any instruction that has a dependence on a poison value has undefined behavior.
Here are some examples:
entry:
%poison = sub nuw i32 0, 1 ; Results in a poison value.
%still_poison = and i32 %poison, 0 ; 0, but also poison.
%poison_yet_again = getelementptr i32, i32* @h, i32 %still_poison
store i32 0, i32* %poison_yet_again ; memory at @h[0] is poisoned
store i32 %poison, i32* @g ; Poison value stored to memory.
%poison2 = load i32, i32* @g ; Poison value loaded back from memory.
store volatile i32 %poison, i32* @g ; External observation; undefined behavior.
%narrowaddr = bitcast i32* @g to i16*
%wideaddr = bitcast i32* @g to i64*
%poison3 = load i16, i16* %narrowaddr ; Returns a poison value.
%poison4 = load i64, i64* %wideaddr ; Returns a poison value.
%cmp = icmp slt i32 %poison, 0 ; Returns a poison value.
br i1 %cmp, label %true, label %end ; Branch to either destination.
true:
store volatile i32 0, i32* @g ; This is control-dependent on %cmp, so
; it has undefined behavior.
br label %end
end:
%p = phi i32 [ 0, %entry ], [ 1, %true ]
; Both edges into this PHI are
; control-dependent on %cmp, so this
; always results in a poison value.
store volatile i32 0, i32* @g ; This would depend on the store in %true
; if %cmp is true, or the store in %entry
; otherwise, so this is undefined behavior.
br i1 %cmp, label %second_true, label %second_end
; The same branch again, but this time the
; true block doesn't have side effects.
second_true:
; No side effects!
ret void
second_end:
store volatile i32 0, i32* @g ; This time, the instruction always depends
; on the store in %end. Also, it is
; control-equivalent to %end, so this is
; well-defined (ignoring earlier undefined
; behavior in this example).
blockaddress(@function, %block)
The ‘blockaddress‘ constant computes the address of the specified basic block in the specified function, and always has an i8* type. Taking the address of the entry block is illegal.
This value only has defined behavior when used as an operand to the ‘indirectbr‘ instruction, or for comparisons against null. Pointer equality tests between labels addresses results in undefined behavior — though, again, comparison against null is ok, and no label is equal to the null pointer. This may be passed around as an opaque pointer sized value as long as the bits are not inspected. This allows ptrtoint and arithmetic to be performed on these values so long as the original value is reconstituted before the indirectbr instruction.
Finally, some targets may provide defined semantics when using the value as the operand to an inline assembly, but that is target specific.
Constant expressions are used to allow expressions involving other constants to be used as constants. Constant expressions may be of any first class type and may involve any LLVM operation that does not have side effects (e.g. load and call are not supported). The following is the syntax for constant expressions:
LLVM supports inline assembler expressions (as opposed to Module-Level Inline Assembly) through the use of a special value. This value represents the inline assembler as a template string (containing the instructions to emit), a list of operand constraints (stored as a string), a flag that indicates whether or not the inline asm expression has side effects, and a flag indicating whether the function containing the asm needs to align its stack conservatively.
The template string supports argument substitution of the operands using “$” followed by a number, to indicate substitution of the given register/memory location, as specified by the constraint string. “${NUM:MODIFIER}” may also be used, where MODIFIER is a target-specific annotation for how to print the operand (See Asm template argument modifiers).
A literal “$” may be included by using “$$” in the template. To include other special characters into the output, the usual “\XX” escapes may be used, just as in other strings. Note that after template substitution, the resulting assembly string is parsed by LLVM’s integrated assembler unless it is disabled – even when emitting a .s file – and thus must contain assembly syntax known to LLVM.
LLVM also supports a few more substitions useful for writing inline assembly:
LLVM’s support for inline asm is modeled closely on the requirements of Clang’s GCC-compatible inline-asm support. Thus, the feature-set and the constraint and modifier codes listed here are similar or identical to those in GCC’s inline asm support. However, to be clear, the syntax of the template and constraint strings described here is not the same as the syntax accepted by GCC and Clang, and, while most constraint letters are passed through as-is by Clang, some get translated to other codes when converting from the C source to the LLVM assembly.
An example inline assembler expression is:
i32 (i32) asm "bswap $0", "=r,r"
Inline assembler expressions may only be used as the callee operand of a call or an invoke instruction. Thus, typically we have:
%X = call i32 asm "bswap $0", "=r,r"(i32 %Y)
Inline asms with side effects not visible in the constraint list must be marked as having side effects. This is done through the use of the ‘sideeffect‘ keyword, like so:
call void asm sideeffect "eieio", ""()
In some cases inline asms will contain code that will not work unless the stack is aligned in some way, such as calls or SSE instructions on x86, yet will not contain code that does that alignment within the asm. The compiler should make conservative assumptions about what the asm might contain and should generate its usual stack alignment code in the prologue if the ‘alignstack‘ keyword is present:
call void asm alignstack "eieio", ""()
Inline asms also support using non-standard assembly dialects. The assumed dialect is ATT. When the ‘inteldialect‘ keyword is present, the inline asm is using the Intel dialect. Currently, ATT and Intel are the only supported dialects. An example is:
call void asm inteldialect "eieio", ""()
If multiple keywords appear the ‘sideeffect‘ keyword must come first, the ‘alignstack‘ keyword second and the ‘inteldialect‘ keyword last.
The constraint list is a comma-separated string, each element containing one or more constraint codes.
For each element in the constraint list an appropriate register or memory operand will be chosen, and it will be made available to assembly template string expansion as $0 for the first constraint in the list, $1 for the second, etc.
There are three different types of constraints, which are distinguished by a prefix symbol in front of the constraint code: Output, Input, and Clobber. The constraints must always be given in that order: outputs first, then inputs, then clobbers. They cannot be intermingled.
There are also three different categories of constraint codes:
Output constraints are specified by an “=” prefix (e.g. “=r”). This indicates that the assembly will write to this operand, and the operand will then be made available as a return value of the asm expression. Output constraints do not consume an argument from the call instruction. (Except, see below about indirect outputs).
Normally, it is expected that no output locations are written to by the assembly expression until all of the inputs have been read. As such, LLVM may assign the same register to an output and an input. If this is not safe (e.g. if the assembly contains two instructions, where the first writes to one output, and the second reads an input and writes to a second output), then the “&” modifier must be used (e.g. “=&r”) to specify that the output is an “early-clobber” output. Marking an output as “early-clobber” ensures that LLVM will not use the same register for any inputs (other than an input tied to this output).
Input constraints do not have a prefix – just the constraint codes. Each input constraint will consume one argument from the call instruction. It is not permitted for the asm to write to any input register or memory location (unless that input is tied to an output). Note also that multiple inputs may all be assigned to the same register, if LLVM can determine that they necessarily all contain the same value.
Instead of providing a Constraint Code, input constraints may also “tie” themselves to an output constraint, by providing an integer as the constraint string. Tied inputs still consume an argument from the call instruction, and take up a position in the asm template numbering as is usual – they will simply be constrained to always use the same register as the output they’ve been tied to. For example, a constraint string of “=r,0” says to assign a register for output, and use that register as an input as well (it being the 0’th constraint).
It is permitted to tie an input to an “early-clobber” output. In that case, no other input may share the same register as the input tied to the early-clobber (even when the other input has the same value).
You may only tie an input to an output which has a register constraint, not a memory constraint. Only a single input may be tied to an output.
There is also an “interesting” feature which deserves a bit of explanation: if a register class constraint allocates a register which is too small for the value type operand provided as input, the input value will be split into multiple registers, and all of them passed to the inline asm.
However, this feature is often not as useful as you might think.
Firstly, the registers are not guaranteed to be consecutive. So, on those architectures that have instructions which operate on multiple consecutive instructions, this is not an appropriate way to support them. (e.g. the 32-bit SparcV8 has a 64-bit load, which instruction takes a single 32-bit register. The hardware then loads into both the named register, and the next register. This feature of inline asm would not be useful to support that.)
A few of the targets provide a template string modifier allowing explicit access to the second register of a two-register operand (e.g. MIPS L, M, and D). On such an architecture, you can actually access the second allocated register (yet, still, not any subsequent ones). But, in that case, you’re still probably better off simply splitting the value into two separate operands, for clarity. (e.g. see the description of the A constraint on X86, which, despite existing only for use with this feature, is not really a good idea to use)
Indirect output or input constraints can be specified by the “*” modifier (which goes after the “=” in case of an output). This indicates that the asm will write to or read from the contents of an address provided as an input argument. (Note that in this way, indirect outputs act more like an input than an output: just like an input, they consume an argument of the call expression, rather than producing a return value. An indirect output constraint is an “output” only in that the asm is expected to write to the contents of the input memory location, instead of just read from it).
This is most typically used for memory constraint, e.g. “=*m”, to pass the address of a variable as a value.
It is also possible to use an indirect register constraint, but only on output (e.g. “=*r”). This will cause LLVM to allocate a register for an output value normally, and then, separately emit a store to the address provided as input, after the provided inline asm. (It’s not clear what value this functionality provides, compared to writing the store explicitly after the asm statement, and it can only produce worse code, since it bypasses many optimization passes. I would recommend not using it.)
A clobber constraint is indicated by a “~” prefix. A clobber does not consume an input operand, nor generate an output. Clobbers cannot use any of the general constraint code letters – they may use only explicit register constraints, e.g. “~{eax}”. The one exception is that a clobber string of “~{memory}” indicates that the assembly writes to arbitrary undeclared memory locations – not only the memory pointed to by a declared indirect output.
Note that clobbering named registers that are also present in output constraints is not legal.
After a potential prefix comes constraint code, or codes.
A Constraint Code is either a single letter (e.g. “r”), a “^” character followed by two letters (e.g. “^wc”), or “{” register-name “}” (e.g. “{eax}”).
The one and two letter constraint codes are typically chosen to be the same as GCC’s constraint codes.
A single constraint may include one or more than constraint code in it, leaving it up to LLVM to choose which one to use. This is included mainly for compatibility with the translation of GCC inline asm coming from clang.
There are two ways to specify alternatives, and either or both may be used in an inline asm constraint list:
Putting those together, you might have a two operand constraint string like "rm|r,ri|rm". This indicates that if operand 0 is r or m, then operand 1 may be one of r or i. If operand 0 is r, then operand 1 may be one of r or m. But, operand 0 and 1 cannot both be of type m.
However, the use of either of the alternatives features is NOT recommended, as LLVM is not able to make an intelligent choice about which one to use. (At the point it currently needs to choose, not enough information is available to do so in a smart way.) Thus, it simply tries to make a choice that’s most likely to compile, not one that will be optimal performance. (e.g., given “rm”, it’ll always choose to use memory, not registers). And, if given multiple registers, or multiple register classes, it will simply choose the first one. (In fact, it doesn’t currently even ensure explicitly specified physical registers are unique, so specifying multiple physical registers as alternatives, like {r11}{r12},{r11}{r12}, will assign r11 to both operands, not at all what was intended.)
The constraint codes are, in general, expected to behave the same way they do in GCC. LLVM’s support is often implemented on an ‘as-needed’ basis, to support C inline asm code which was supported by GCC. A mismatch in behavior between LLVM and GCC likely indicates a bug in LLVM.
Some constraint codes are typically supported by all targets:
Other constraints are target-specific:
AArch64:
AMDGPU:
All ARM modes:
ARM and ARM’s Thumb2 mode:
ARM’s Thumb1 mode:
Hexagon:
MSP430:
MIPS:
NVPTX:
PowerPC:
Sparc:
SystemZ:
X86:
XCore:
In the asm template string, modifiers can be used on the operand reference, like “${0:n}”.
The modifiers are, in general, expected to behave the same way they do in GCC. LLVM’s support is often implemented on an ‘as-needed’ basis, to support C inline asm code which was supported by GCC. A mismatch in behavior between LLVM and GCC likely indicates a bug in LLVM.
Target-independent:
AArch64:
AMDGPU:
ARM:
Hexagon:
MSP430:
No additional modifiers.
MIPS:
NVPTX:
PowerPC:
Sparc:
SystemZ:
SystemZ implements only n, and does not support any of the other target-independent modifiers.
X86:
XCore:
No additional modifiers.
The call instructions that wrap inline asm nodes may have a “!srcloc” MDNode attached to it that contains a list of constant integers. If present, the code generator will use the integer as the location cookie value when report errors through the LLVMContext error reporting mechanisms. This allows a front-end to correlate backend errors that occur with inline asm back to the source code that produced it. For example:
call void asm sideeffect "something bad", ""(), !srcloc !42
...
!42 = !{ i32 1234567 }
It is up to the front-end to make sense of the magic numbers it places in the IR. If the MDNode contains multiple constants, the code generator will use the one that corresponds to the line of the asm that the error occurs on.
LLVM IR allows metadata to be attached to instructions in the program that can convey extra information about the code to the optimizers and code generator. One example application of metadata is source-level debug information. There are two metadata primitives: strings and nodes.
Metadata does not have a type, and is not a value. If referenced from a call instruction, it uses the metadata type.
All metadata are identified in syntax by a exclamation point (‘!‘).
A metadata string is a string surrounded by double quotes. It can contain any character by escaping non-printable characters with “\xx” where “xx” is the two digit hex code. For example: “!"test\00"”.
Metadata nodes are represented with notation similar to structure constants (a comma separated list of elements, surrounded by braces and preceded by an exclamation point). Metadata nodes can have any values as their operand. For example:
!{ !"test\00", i32 10}
Metadata nodes that aren’t uniqued use the distinct keyword. For example:
!0 = distinct !{!"test\00", i32 10}
distinct nodes are useful when nodes shouldn’t be merged based on their content. They can also occur when transformations cause uniquing collisions when metadata operands change.
A named metadata is a collection of metadata nodes, which can be looked up in the module symbol table. For example:
!foo = !{!4, !3}
Metadata can be used as function arguments. Here the llvm.dbg.value intrinsic is using three metadata arguments:
call void @llvm.dbg.value(metadata !24, metadata !25, metadata !26)
Metadata can be attached to an instruction. Here metadata !21 is attached to the add instruction using the !dbg identifier:
%indvar.next = add i64 %indvar, 1, !dbg !21
Metadata can also be attached to a function or a global variable. Here metadata !22 is attached to the f1 and f2 functions, and the globals ``g1 and g2 using the !dbg identifier:
declare !dbg !22 void @f1()
define void @f2() !dbg !22 {
ret void
}
@g1 = global i32 0, !dbg !22
@g2 = external global i32, !dbg !22
A transformation is required to drop any metadata attachment that it does not know or know it can’t preserve. Currently there is an exception for metadata attachment to globals for !type and !absolute_symbol which can’t be unconditionally dropped unless the global is itself deleted.
Metadata attached to a module using named metadata may not be dropped, with the exception of debug metadata (named metadata with the name !llvm.dbg.*).
More information about specific metadata nodes recognized by the optimizers and code generator is found below.
Specialized metadata nodes are custom data structures in metadata (as opposed to generic tuples). Their fields are labelled, and can be specified in any order.
These aren’t inherently debug info centric, but currently all the specialized metadata nodes are related to debug info.
DICompileUnit nodes represent a compile unit. The enums:, retainedTypes:, globals:, imports: and macros: fields are tuples containing the debug info to be emitted along with the compile unit, regardless of code optimizations (some nodes are only emitted if there are references to them from instructions). The debugInfoForProfiling: field is a boolean indicating whether or not line-table discriminators are updated to provide more-accurate debug info for profiling results.
!0 = !DICompileUnit(language: DW_LANG_C99, file: !1, producer: "clang",
isOptimized: true, flags: "-O2", runtimeVersion: 2,
splitDebugFilename: "abc.debug", emissionKind: FullDebug,
enums: !2, retainedTypes: !3, globals: !4, imports: !5,
macros: !6, dwoId: 0x0abcd)
Compile unit descriptors provide the root scope for objects declared in a specific compilation unit. File descriptors are defined using this scope. These descriptors are collected by a named metadata node !llvm.dbg.cu. They keep track of global variables, type information, and imported entities (declarations and namespaces).
DIFile nodes represent files. The filename: can include slashes.
!0 = !DIFile(filename: "path/to/file", directory: "/path/to/dir",
checksumkind: CSK_MD5,
checksum: "000102030405060708090a0b0c0d0e0f")
Files are sometimes used in scope: fields, and are the only valid target for file: fields. Valid values for checksumkind: field are: {CSK_None, CSK_MD5, CSK_SHA1}
DIBasicType nodes represent primitive types, such as int, bool and float. tag: defaults to DW_TAG_base_type.
!0 = !DIBasicType(name: "unsigned char", size: 8, align: 8,
encoding: DW_ATE_unsigned_char)
!1 = !DIBasicType(tag: DW_TAG_unspecified_type, name: "decltype(nullptr)")
The encoding: describes the details of the type. Usually it’s one of the following:
DW_ATE_address = 1
DW_ATE_boolean = 2
DW_ATE_float = 4
DW_ATE_signed = 5
DW_ATE_signed_char = 6
DW_ATE_unsigned = 7
DW_ATE_unsigned_char = 8
DISubroutineType nodes represent subroutine types. Their types: field refers to a tuple; the first operand is the return type, while the rest are the types of the formal arguments in order. If the first operand is null, that represents a function with no return value (such as void foo() {} in C++).
!0 = !BasicType(name: "int", size: 32, align: 32, DW_ATE_signed)
!1 = !BasicType(name: "char", size: 8, align: 8, DW_ATE_signed_char)
!2 = !DISubroutineType(types: !{null, !0, !1}) ; void (int, char)
DIDerivedType nodes represent types derived from other types, such as qualified types.
!0 = !DIBasicType(name: "unsigned char", size: 8, align: 8,
encoding: DW_ATE_unsigned_char)
!1 = !DIDerivedType(tag: DW_TAG_pointer_type, baseType: !0, size: 32,
align: 32)
The following tag: values are valid:
DW_TAG_member = 13
DW_TAG_pointer_type = 15
DW_TAG_reference_type = 16
DW_TAG_typedef = 22
DW_TAG_inheritance = 28
DW_TAG_ptr_to_member_type = 31
DW_TAG_const_type = 38
DW_TAG_friend = 42
DW_TAG_volatile_type = 53
DW_TAG_restrict_type = 55
DW_TAG_atomic_type = 71
DW_TAG_member is used to define a member of a composite type. The type of the member is the baseType:. The offset: is the member’s bit offset. If the composite type has an ODR identifier: and does not set flags: DIFwdDecl, then the member is uniqued based only on its name: and scope:.
DW_TAG_inheritance and DW_TAG_friend are used in the elements: field of composite types to describe parents and friends.
DW_TAG_typedef is used to provide a name for the baseType:.
DW_TAG_pointer_type, DW_TAG_reference_type, DW_TAG_const_type, DW_TAG_volatile_type, DW_TAG_restrict_type and DW_TAG_atomic_type are used to qualify the baseType:.
Note that the void * type is expressed as a type derived from NULL.
DICompositeType nodes represent types composed of other types, like structures and unions. elements: points to a tuple of the composed types.
If the source language supports ODR, the identifier: field gives the unique identifier used for type merging between modules. When specified, subprogram declarations and member derived types that reference the ODR-type in their scope: change uniquing rules.
For a given identifier:, there should only be a single composite type that does not have flags: DIFlagFwdDecl set. LLVM tools that link modules together will unique such definitions at parse time via the identifier: field, even if the nodes are distinct.
!0 = !DIEnumerator(name: "SixKind", value: 7)
!1 = !DIEnumerator(name: "SevenKind", value: 7)
!2 = !DIEnumerator(name: "NegEightKind", value: -8)
!3 = !DICompositeType(tag: DW_TAG_enumeration_type, name: "Enum", file: !12,
line: 2, size: 32, align: 32, identifier: "_M4Enum",
elements: !{!0, !1, !2})
The following tag: values are valid:
DW_TAG_array_type = 1
DW_TAG_class_type = 2
DW_TAG_enumeration_type = 4
DW_TAG_structure_type = 19
DW_TAG_union_type = 23
For DW_TAG_array_type, the elements: should be subrange descriptors, each representing the range of subscripts at that level of indexing. The DIFlagVector flag to flags: indicates that an array type is a native packed vector.
For DW_TAG_enumeration_type, the elements: should be enumerator descriptors, each representing the definition of an enumeration value for the set. All enumeration type descriptors are collected in the enums: field of the compile unit.
For DW_TAG_structure_type, DW_TAG_class_type, and DW_TAG_union_type, the elements: should be derived types with tag: DW_TAG_member, tag: DW_TAG_inheritance, or tag: DW_TAG_friend; or subprograms with isDefinition: false.
DISubrange nodes are the elements for DW_TAG_array_type variants of DICompositeType.
!0 = !DISubrange(count: 5, lowerBound: 0) ; array counting from 0
!1 = !DISubrange(count: 5, lowerBound: 1) ; array counting from 1
!2 = !DISubrange(count: -1) ; empty array.
; Scopes used in rest of example
!6 = !DIFile(filename: "vla.c", directory: "/path/to/file")
!7 = distinct !DICompileUnit(language: DW_LANG_C99, ...
!8 = distinct !DISubprogram(name: "foo", scope: !7, file: !6, line: 5, ...
; Use of local variable as count value
!9 = !DIBasicType(name: "int", size: 32, encoding: DW_ATE_signed)
!10 = !DILocalVariable(name: "count", scope: !8, file: !6, line: 42, type: !9)
!11 = !DISubrange(count !10, lowerBound: 0)
; Use of global variable as count value
!12 = !DIGlobalVariable(name: "count", scope: !8, file: !6, line: 22, type: !9)
!13 = !DISubrange(count !12, lowerBound: 0)
DIEnumerator nodes are the elements for DW_TAG_enumeration_type variants of DICompositeType.
!0 = !DIEnumerator(name: "SixKind", value: 7)
!1 = !DIEnumerator(name: "SevenKind", value: 7)
!2 = !DIEnumerator(name: "NegEightKind", value: -8)
DITemplateTypeParameter nodes represent type parameters to generic source language constructs. They are used (optionally) in DICompositeType and DISubprogram templateParams: fields.
!0 = !DITemplateTypeParameter(name: "Ty", type: !1)
DITemplateValueParameter nodes represent value parameters to generic source language constructs. tag: defaults to DW_TAG_template_value_parameter, but if specified can also be set to DW_TAG_GNU_template_template_param or DW_TAG_GNU_template_param_pack. They are used (optionally) in DICompositeType and DISubprogram templateParams: fields.
!0 = !DITemplateValueParameter(name: "Ty", type: !1, value: i32 7)
DINamespace nodes represent namespaces in the source language.
!0 = !DINamespace(name: "myawesomeproject", scope: !1, file: !2, line: 7)
DIGlobalVariable nodes represent global variables in the source language.
!0 = !DIGlobalVariable(name: "foo", linkageName: "foo", scope: !1,
file: !2, line: 7, type: !3, isLocal: true,
isDefinition: false, variable: i32* @foo,
declaration: !4)
All global variables should be referenced by the globals: field of a compile unit.
DISubprogram nodes represent functions from the source language. A DISubprogram may be attached to a function definition using !dbg metadata. The variables: field points at variables that must be retained, even if their IR counterparts are optimized out of the IR. The type: field must point at an DISubroutineType.
When isDefinition: false, subprograms describe a declaration in the type tree as opposed to a definition of a function. If the scope is a composite type with an ODR identifier: and that does not set flags: DIFwdDecl, then the subprogram declaration is uniqued based only on its linkageName: and scope:.
define void @_Z3foov() !dbg !0 {
...
}
!0 = distinct !DISubprogram(name: "foo", linkageName: "_Zfoov", scope: !1,
file: !2, line: 7, type: !3, isLocal: true,
isDefinition: true, scopeLine: 8,
containingType: !4,
virtuality: DW_VIRTUALITY_pure_virtual,
virtualIndex: 10, flags: DIFlagPrototyped,
isOptimized: true, unit: !5, templateParams: !6,
declaration: !7, variables: !8, thrownTypes: !9)
DILexicalBlock nodes describe nested blocks within a subprogram. The line number and column numbers are used to distinguish two lexical blocks at same depth. They are valid targets for scope: fields.
!0 = distinct !DILexicalBlock(scope: !1, file: !2, line: 7, column: 35)
Usually lexical blocks are distinct to prevent node merging based on operands.
DILexicalBlockFile nodes are used to discriminate between sections of a lexical block. The file: field can be changed to indicate textual inclusion, or the discriminator: field can be used to discriminate between control flow within a single block in the source language.
!0 = !DILexicalBlock(scope: !3, file: !4, line: 7, column: 35)
!1 = !DILexicalBlockFile(scope: !0, file: !4, discriminator: 0)
!2 = !DILexicalBlockFile(scope: !0, file: !4, discriminator: 1)
DILocation nodes represent source debug locations. The scope: field is mandatory, and points at an DILexicalBlockFile, an DILexicalBlock, or an DISubprogram.
!0 = !DILocation(line: 2900, column: 42, scope: !1, inlinedAt: !2)
DILocalVariable nodes represent local variables in the source language. If the arg: field is set to non-zero, then this variable is a subprogram parameter, and it will be included in the variables: field of its DISubprogram.
!0 = !DILocalVariable(name: "this", arg: 1, scope: !3, file: !2, line: 7,
type: !3, flags: DIFlagArtificial)
!1 = !DILocalVariable(name: "x", arg: 2, scope: !4, file: !2, line: 7,
type: !3)
!2 = !DILocalVariable(name: "y", scope: !5, file: !2, line: 7, type: !3)
DIExpression nodes represent expressions that are inspired by the DWARF expression language. They are used in debug intrinsics (such as llvm.dbg.declare and llvm.dbg.value) to describe how the referenced LLVM variable relates to the source language variable. Debug intrinsics are interpreted left-to-right: start by pushing the value/address operand of the intrinsic onto a stack, then repeatedly push and evaluate opcodes from the DIExpression until the final variable description is produced.
The current supported opcode vocabulary is limited:
DWARF specifies three kinds of simple location descriptions: Register, memory, and implicit location descriptions. Note that a location description is defined over certain ranges of a program, i.e the location of a variable may change over the course of the program. Register and memory location descriptions describe the concrete location of a source variable (in the sense that a debugger might modify its value), whereas implicit locations describe merely the actual value of a source variable which might not exist in registers or in memory (see DW_OP_stack_value).
A llvm.dbg.addr or llvm.dbg.declare intrinsic describes an indirect value (the address) of a source variable. The first operand of the intrinsic must be an address of some kind. A DIExpression attached to the intrinsic refines this address to produce a concrete location for the source variable.
A llvm.dbg.value intrinsic describes the direct value of a source variable. The first operand of the intrinsic may be a direct or indirect value. A DIExpresion attached to the intrinsic refines the first operand to produce a direct value. For example, if the first operand is an indirect value, it may be necessary to insert DW_OP_deref into the DIExpresion in order to produce a valid debug intrinsic.
Note
A DIExpression is interpreted in the same way regardless of which kind of debug intrinsic it’s attached to.
!0 = !DIExpression(DW_OP_deref)
!1 = !DIExpression(DW_OP_plus_uconst, 3)
!1 = !DIExpression(DW_OP_constu, 3, DW_OP_plus)
!2 = !DIExpression(DW_OP_bit_piece, 3, 7)
!3 = !DIExpression(DW_OP_deref, DW_OP_constu, 3, DW_OP_plus, DW_OP_LLVM_fragment, 3, 7)
!4 = !DIExpression(DW_OP_constu, 2, DW_OP_swap, DW_OP_xderef)
!5 = !DIExpression(DW_OP_constu, 42, DW_OP_stack_value)
DIObjCProperty nodes represent Objective-C property nodes.
!3 = !DIObjCProperty(name: "foo", file: !1, line: 7, setter: "setFoo",
getter: "getFoo", attributes: 7, type: !2)
DIImportedEntity nodes represent entities (such as modules) imported into a compile unit.
!2 = !DIImportedEntity(tag: DW_TAG_imported_module, name: "foo", scope: !0,
entity: !1, line: 7)
DIMacro nodes represent definition or undefinition of a macro identifiers. The name: field is the macro identifier, followed by macro parameters when defining a function-like macro, and the value field is the token-string used to expand the macro identifier.
!2 = !DIMacro(macinfo: DW_MACINFO_define, line: 7, name: "foo(x)",
value: "((x) + 1)")
!3 = !DIMacro(macinfo: DW_MACINFO_undef, line: 30, name: "foo")
DIMacroFile nodes represent inclusion of source files. The nodes: field is a list of DIMacro and DIMacroFile nodes that appear in the included source file.
!2 = !DIMacroFile(macinfo: DW_MACINFO_start_file, line: 7, file: !2,
nodes: !3)
In LLVM IR, memory does not have types, so LLVM’s own type system is not suitable for doing type based alias analysis (TBAA). Instead, metadata is added to the IR to describe a type system of a higher level language. This can be used to implement C/C++ strict type aliasing rules, but it can also be used to implement custom alias analysis behavior for other languages.
This description of LLVM’s TBAA system is broken into two parts: Semantics talks about high level issues, and Representation talks about the metadata encoding of various entities.
It is always possible to trace any TBAA node to a “root” TBAA node (details in the Representation section). TBAA nodes with different roots have an unknown aliasing relationship, and LLVM conservatively infers MayAlias between them. The rules mentioned in this section only pertain to TBAA nodes living under the same root.
The TBAA metadata system, referred to as “struct path TBAA” (not to be confused with tbaa.struct), consists of the following high level concepts: Type Descriptors, further subdivided into scalar type descriptors and struct type descriptors; and Access Tags.
Type descriptors describe the type system of the higher level language being compiled. Scalar type descriptors describe types that do not contain other types. Each scalar type has a parent type, which must also be a scalar type or the TBAA root. Via this parent relation, scalar types within a TBAA root form a tree. Struct type descriptors denote types that contain a sequence of other type descriptors, at known offsets. These contained type descriptors can either be struct type descriptors themselves or scalar type descriptors.
Access tags are metadata nodes attached to load and store instructions. Access tags use type descriptors to describe the location being accessed in terms of the type system of the higher level language. Access tags are tuples consisting of a base type, an access type and an offset. The base type is a scalar type descriptor or a struct type descriptor, the access type is a scalar type descriptor, and the offset is a constant integer.
The access tag (BaseTy, AccessTy, Offset) can describe one of two things:
- If BaseTy is a struct type, the tag describes a memory access (load or store) of a value of type AccessTy contained in the struct type BaseTy at offset Offset.
- If BaseTy is a scalar type, Offset must be 0 and BaseTy and AccessTy must be the same; and the access tag describes a scalar access with scalar type AccessTy.
We first define an ImmediateParent relation on (BaseTy, Offset) tuples this way:
- If BaseTy is a scalar type then ImmediateParent(BaseTy, 0) is (ParentTy, 0) where ParentTy is the parent of the scalar type as described in the TBAA metadata. ImmediateParent(BaseTy, Offset) is undefined if Offset is non-zero.
- If BaseTy is a struct type then ImmediateParent(BaseTy, Offset) is (NewTy, NewOffset) where NewTy is the type contained in BaseTy at offset Offset and NewOffset is Offset adjusted to be relative within that inner type.
A memory access with an access tag (BaseTy1, AccessTy1, Offset1) aliases a memory access with an access tag (BaseTy2, AccessTy2, Offset2) if either (BaseTy1, Offset1) is reachable from (Base2, Offset2) via the Parent relation or vice versa.
As a concrete example, the type descriptor graph for the following program
struct Inner {
int i; // offset 0
float f; // offset 4
};
struct Outer {
float f; // offset 0
double d; // offset 4
struct Inner inner_a; // offset 12
};
void f(struct Outer* outer, struct Inner* inner, float* f, int* i, char* c) {
outer->f = 0; // tag0: (OuterStructTy, FloatScalarTy, 0)
outer->inner_a.i = 0; // tag1: (OuterStructTy, IntScalarTy, 12)
outer->inner_a.f = 0.0; // tag2: (OuterStructTy, FloatScalarTy, 16)
*f = 0.0; // tag3: (FloatScalarTy, FloatScalarTy, 0)
}
is (note that in C and C++, char can be used to access any arbitrary type):
Root = "TBAA Root"
CharScalarTy = ("char", Root, 0)
FloatScalarTy = ("float", CharScalarTy, 0)
DoubleScalarTy = ("double", CharScalarTy, 0)
IntScalarTy = ("int", CharScalarTy, 0)
InnerStructTy = {"Inner" (IntScalarTy, 0), (FloatScalarTy, 4)}
OuterStructTy = {"Outer", (FloatScalarTy, 0), (DoubleScalarTy, 4),
(InnerStructTy, 12)}
with (e.g.) ImmediateParent(OuterStructTy, 12) = (InnerStructTy, 0), ImmediateParent(InnerStructTy, 0) = (IntScalarTy, 0), and ImmediateParent(IntScalarTy, 0) = (CharScalarTy, 0).
The root node of a TBAA type hierarchy is an MDNode with 0 operands or with exactly one MDString operand.
Scalar type descriptors are represented as an MDNode s with two operands. The first operand is an MDString denoting the name of the struct type. LLVM does not assign meaning to the value of this operand, it only cares about it being an MDString. The second operand is an MDNode which points to the parent for said scalar type descriptor, which is either another scalar type descriptor or the TBAA root. Scalar type descriptors can have an optional third argument, but that must be the constant integer zero.
Struct type descriptors are represented as MDNode s with an odd number of operands greater than 1. The first operand is an MDString denoting the name of the struct type. Like in scalar type descriptors the actual value of this name operand is irrelevant to LLVM. After the name operand, the struct type descriptors have a sequence of alternating MDNode and ConstantInt operands. With N starting from 1, the 2N - 1 th operand, an MDNode, denotes a contained field, and the 2N th operand, a ConstantInt, is the offset of the said contained field. The offsets must be in non-decreasing order.
Access tags are represented as MDNode s with either 3 or 4 operands. The first operand is an MDNode pointing to the node representing the base type. The second operand is an MDNode pointing to the node representing the access type. The third operand is a ConstantInt that states the offset of the access. If a fourth field is present, it must be a ConstantInt valued at 0 or 1. If it is 1 then the access tag states that the location being accessed is “constant” (meaning pointsToConstantMemory should return true; see other useful AliasAnalysis methods). The TBAA root of the access type and the base type of an access tag must be the same, and that is the TBAA root of the access tag.
The llvm.memcpy is often used to implement aggregate assignment operations in C and similar languages, however it is defined to copy a contiguous region of memory, which is more than strictly necessary for aggregate types which contain holes due to padding. Also, it doesn’t contain any TBAA information about the fields of the aggregate.
!tbaa.struct metadata can describe which memory subregions in a memcpy are padding and what the TBAA tags of the struct are.
The current metadata format is very simple. !tbaa.struct metadata nodes are a list of operands which are in conceptual groups of three. For each group of three, the first operand gives the byte offset of a field in bytes, the second gives its size in bytes, and the third gives its tbaa tag. e.g.:
!4 = !{ i64 0, i64 4, !1, i64 8, i64 4, !2 }
This describes a struct with two fields. The first is at offset 0 bytes with size 4 bytes, and has tbaa tag !1. The second is at offset 8 bytes and has size 4 bytes and has tbaa tag !2.
Note that the fields need not be contiguous. In this example, there is a 4 byte gap between the two fields. This gap represents padding which does not carry useful data and need not be preserved.
noalias and alias.scope metadata provide the ability to specify generic noalias memory-access sets. This means that some collection of memory access instructions (loads, stores, memory-accessing calls, etc.) that carry noalias metadata can specifically be specified not to alias with some other collection of memory access instructions that carry alias.scope metadata. Each type of metadata specifies a list of scopes where each scope has an id and a domain.
When evaluating an aliasing query, if for some domain, the set of scopes with that domain in one instruction’s alias.scope list is a subset of (or equal to) the set of scopes for that domain in another instruction’s noalias list, then the two memory accesses are assumed not to alias.
Because scopes in one domain don’t affect scopes in other domains, separate domains can be used to compose multiple independent noalias sets. This is used for example during inlining. As the noalias function parameters are turned into noalias scope metadata, a new domain is used every time the function is inlined.
The metadata identifying each domain is itself a list containing one or two entries. The first entry is the name of the domain. Note that if the name is a string then it can be combined across functions and translation units. A self-reference can be used to create globally unique domain names. A descriptive string may optionally be provided as a second list entry.
The metadata identifying each scope is also itself a list containing two or three entries. The first entry is the name of the scope. Note that if the name is a string then it can be combined across functions and translation units. A self-reference can be used to create globally unique scope names. A metadata reference to the scope’s domain is the second entry. A descriptive string may optionally be provided as a third list entry.
For example,
; Two scope domains:
!0 = !{!0}
!1 = !{!1}
; Some scopes in these domains:
!2 = !{!2, !0}
!3 = !{!3, !0}
!4 = !{!4, !1}
; Some scope lists:
!5 = !{!4} ; A list containing only scope !4
!6 = !{!4, !3, !2}
!7 = !{!3}
; These two instructions don't alias:
%0 = load float, float* %c, align 4, !alias.scope !5
store float %0, float* %arrayidx.i, align 4, !noalias !5
; These two instructions also don't alias (for domain !1, the set of scopes
; in the !alias.scope equals that in the !noalias list):
%2 = load float, float* %c, align 4, !alias.scope !5
store float %2, float* %arrayidx.i2, align 4, !noalias !6
; These two instructions may alias (for domain !0, the set of scopes in
; the !noalias list is not a superset of, or equal to, the scopes in the
; !alias.scope list):
%2 = load float, float* %c, align 4, !alias.scope !6
store float %0, float* %arrayidx.i, align 4, !noalias !7
fpmath metadata may be attached to any instruction of floating-point type. It can be used to express the maximum acceptable error in the result of that instruction, in ULPs, thus potentially allowing the compiler to use a more efficient but less accurate method of computing it. ULP is defined as follows:
If x is a real number that lies between two finite consecutive floating-point numbers a and b, without being equal to one of them, then ulp(x) = |b - a|, otherwise ulp(x) is the distance between the two non-equal finite floating-point numbers nearest x. Moreover, ulp(NaN) is NaN.
The metadata node shall consist of a single positive float type number representing the maximum relative error, for example:
!0 = !{ float 2.5 } ; maximum acceptable inaccuracy is 2.5 ULPs
range metadata may be attached only to load, call and invoke of integer types. It expresses the possible ranges the loaded value or the value returned by the called function at this call site is in. If the loaded or returned value is not in the specified range, the behavior is undefined. The ranges are represented with a flattened list of integers. The loaded value or the value returned is known to be in the union of the ranges defined by each consecutive pair. Each pair has the following properties:
In addition, the pairs must be in signed order of the lower bound and they must be non-contiguous.
Examples:
%a = load i8, i8* %x, align 1, !range !0 ; Can only be 0 or 1
%b = load i8, i8* %y, align 1, !range !1 ; Can only be 255 (-1), 0 or 1
%c = call i8 @foo(), !range !2 ; Can only be 0, 1, 3, 4 or 5
%d = invoke i8 @bar() to label %cont
unwind label %lpad, !range !3 ; Can only be -2, -1, 3, 4 or 5
...
!0 = !{ i8 0, i8 2 }
!1 = !{ i8 255, i8 2 }
!2 = !{ i8 0, i8 2, i8 3, i8 6 }
!3 = !{ i8 -2, i8 0, i8 3, i8 6 }
absolute_symbol metadata may be attached to a global variable declaration. It marks the declaration as a reference to an absolute symbol, which causes the backend to use absolute relocations for the symbol even in position independent code, and expresses the possible ranges that the global variable’s address (not its value) is in, in the same format as range metadata, with the extension that the pair all-ones,all-ones may be used to represent the full set.
Example (assuming 64-bit pointers):
@a = external global i8, !absolute_symbol !0 ; Absolute symbol in range [0,256)
@b = external global i8, !absolute_symbol !1 ; Absolute symbol in range [0,2^64)
...
!0 = !{ i64 0, i64 256 }
!1 = !{ i64 -1, i64 -1 }
callees metadata may be attached to indirect call sites. If callees metadata is attached to a call site, and any callee is not among the set of functions provided by the metadata, the behavior is undefined. The intent of this metadata is to facilitate optimizations such as indirect-call promotion. For example, in the code below, the call instruction may only target the add or sub functions:
%result = call i64 %binop(i64 %x, i64 %y), !callees !0
...
!0 = !{i64 (i64, i64)* @add, i64 (i64, i64)* @sub}
unpredictable metadata may be attached to any branch or switch instruction. It can be used to express the unpredictability of control flow. Similar to the llvm.expect intrinsic, it may be used to alter optimizations related to compare and branch instructions. The metadata is treated as a boolean value; if it exists, it signals that the branch or switch that it is attached to is completely unpredictable.
It is sometimes useful to attach information to loop constructs. Currently, loop metadata is implemented as metadata attached to the branch instruction in the loop latch block. This type of metadata refer to a metadata node that is guaranteed to be separate for each loop. The loop identifier metadata is specified with the name llvm.loop.
The loop identifier metadata is implemented using a metadata that refers to itself to avoid merging it with any other identifier metadata, e.g., during module linkage or function inlining. That is, each loop should refer to their own identification metadata even if they reside in separate functions. The following example contains loop identifier metadata for two separate loop constructs:
!0 = !{!0}
!1 = !{!1}
The loop identifier metadata can be used to specify additional per-loop metadata. Any operands after the first operand can be treated as user-defined metadata. For example the llvm.loop.unroll.count suggests an unroll factor to the loop unroller:
br i1 %exitcond, label %._crit_edge, label %.lr.ph, !llvm.loop !0
...
!0 = !{!0, !1}
!1 = !{!"llvm.loop.unroll.count", i32 4}
Metadata prefixed with llvm.loop.vectorize or llvm.loop.interleave are used to control per-loop vectorization and interleaving parameters such as vectorization width and interleave count. These metadata should be used in conjunction with llvm.loop loop identification metadata. The llvm.loop.vectorize and llvm.loop.interleave metadata are only optimization hints and the optimizer will only interleave and vectorize loops if it believes it is safe to do so. The llvm.mem.parallel_loop_access metadata which contains information about loop-carried memory dependencies can be helpful in determining the safety of these transformations.
This metadata suggests an interleave count to the loop interleaver. The first operand is the string llvm.loop.interleave.count and the second operand is an integer specifying the interleave count. For example:
!0 = !{!"llvm.loop.interleave.count", i32 4}
Note that setting llvm.loop.interleave.count to 1 disables interleaving multiple iterations of the loop. If llvm.loop.interleave.count is set to 0 then the interleave count will be determined automatically.
This metadata selectively enables or disables vectorization for the loop. The first operand is the string llvm.loop.vectorize.enable and the second operand is a bit. If the bit operand value is 1 vectorization is enabled. A value of 0 disables vectorization:
!0 = !{!"llvm.loop.vectorize.enable", i1 0}
!1 = !{!"llvm.loop.vectorize.enable", i1 1}
This metadata sets the target width of the vectorizer. The first operand is the string llvm.loop.vectorize.width and the second operand is an integer specifying the width. For example:
!0 = !{!"llvm.loop.vectorize.width", i32 4}
Note that setting llvm.loop.vectorize.width to 1 disables vectorization of the loop. If llvm.loop.vectorize.width is set to 0 or if the loop does not have this metadata the width will be determined automatically.
Metadata prefixed with llvm.loop.unroll are loop unrolling optimization hints such as the unroll factor. llvm.loop.unroll metadata should be used in conjunction with llvm.loop loop identification metadata. The llvm.loop.unroll metadata are only optimization hints and the unrolling will only be performed if the optimizer believes it is safe to do so.
This metadata suggests an unroll factor to the loop unroller. The first operand is the string llvm.loop.unroll.count and the second operand is a positive integer specifying the unroll factor. For example:
!0 = !{!"llvm.loop.unroll.count", i32 4}
If the trip count of the loop is less than the unroll count the loop will be partially unrolled.
This metadata disables loop unrolling. The metadata has a single operand which is the string llvm.loop.unroll.disable. For example:
!0 = !{!"llvm.loop.unroll.disable"}
This metadata disables runtime loop unrolling. The metadata has a single operand which is the string llvm.loop.unroll.runtime.disable. For example:
!0 = !{!"llvm.loop.unroll.runtime.disable"}
This metadata suggests that the loop should be fully unrolled if the trip count is known at compile time and partially unrolled if the trip count is not known at compile time. The metadata has a single operand which is the string llvm.loop.unroll.enable. For example:
!0 = !{!"llvm.loop.unroll.enable"}
This metadata suggests that the loop should be unrolled fully. The metadata has a single operand which is the string llvm.loop.unroll.full. For example:
!0 = !{!"llvm.loop.unroll.full"}
This metadata is treated very similarly to the llvm.loop.unroll metadata above, but affect the unroll and jam pass. In addition any loop with llvm.loop.unroll metadata but no llvm.loop.unroll_and_jam metadata will disable unroll and jam (so llvm.loop.unroll metadata will be left to the unroller, plus llvm.loop.unroll.disable metadata will disable unroll and jam too.)
The metadata for unroll and jam otherwise is the same as for unroll. llvm.loop.unroll_and_jam.enable, llvm.loop.unroll_and_jam.disable and llvm.loop.unroll_and_jam.count do the same as for unroll. llvm.loop.unroll_and_jam.full is not supported. Again these are only hints and the normal safety checks will still be performed.
This metadata suggests an unroll and jam factor to use, similarly to llvm.loop.unroll.count. The first operand is the string llvm.loop.unroll_and_jam.count and the second operand is a positive integer specifying the unroll factor. For example:
!0 = !{!"llvm.loop.unroll_and_jam.count", i32 4}
If the trip count of the loop is less than the unroll count the loop will be partially unroll and jammed.
This metadata disables loop unroll and jamming. The metadata has a single operand which is the string llvm.loop.unroll_and_jam.disable. For example:
!0 = !{!"llvm.loop.unroll_and_jam.disable"}
This metadata suggests that the loop should be fully unroll and jammed if the trip count is known at compile time and partially unrolled if the trip count is not known at compile time. The metadata has a single operand which is the string llvm.loop.unroll_and_jam.enable. For example:
!0 = !{!"llvm.loop.unroll_and_jam.enable"}
This metadata indicates that the loop should not be versioned for the purpose of enabling loop-invariant code motion (LICM). The metadata has a single operand which is the string llvm.loop.licm_versioning.disable. For example:
!0 = !{!"llvm.loop.licm_versioning.disable"}
Loop distribution allows splitting a loop into multiple loops. Currently, this is only performed if the entire loop cannot be vectorized due to unsafe memory dependencies. The transformation will attempt to isolate the unsafe dependencies into their own loop.
This metadata can be used to selectively enable or disable distribution of the loop. The first operand is the string llvm.loop.distribute.enable and the second operand is a bit. If the bit operand value is 1 distribution is enabled. A value of 0 disables distribution:
!0 = !{!"llvm.loop.distribute.enable", i1 0}
!1 = !{!"llvm.loop.distribute.enable", i1 1}
This metadata should be used in conjunction with llvm.loop loop identification metadata.
Metadata types used to annotate memory accesses with information helpful for optimizations are prefixed with llvm.mem.
The llvm.mem.parallel_loop_access metadata refers to a loop identifier, or metadata containing a list of loop identifiers for nested loops. The metadata is attached to memory accessing instructions and denotes that no loop carried memory dependence exist between it and other instructions denoted with the same loop identifier. The metadata on memory reads also implies that if conversion (i.e. speculative execution within a loop iteration) is safe.
Precisely, given two instructions m1 and m2 that both have the llvm.mem.parallel_loop_access metadata, with L1 and L2 being the set of loops associated with that metadata, respectively, then there is no loop carried dependence between m1 and m2 for loops in both L1 and L2.
As a special case, if all memory accessing instructions in a loop have llvm.mem.parallel_loop_access metadata that refers to that loop, then the loop has no loop carried memory dependences and is considered to be a parallel loop.
Note that if not all memory access instructions have such metadata referring to the loop, then the loop is considered not being trivially parallel. Additional memory dependence analysis is required to make that determination. As a fail safe mechanism, this causes loops that were originally parallel to be considered sequential (if optimization passes that are unaware of the parallel semantics insert new memory instructions into the loop body).
Example of a loop that is considered parallel due to its correct use of both llvm.loop and llvm.mem.parallel_loop_access metadata types that refer to the same loop identifier metadata.
for.body:
...
%val0 = load i32, i32* %arrayidx, !llvm.mem.parallel_loop_access !0
...
store i32 %val0, i32* %arrayidx1, !llvm.mem.parallel_loop_access !0
...
br i1 %exitcond, label %for.end, label %for.body, !llvm.loop !0
for.end:
...
!0 = !{!0}
It is also possible to have nested parallel loops. In that case the memory accesses refer to a list of loop identifier metadata nodes instead of the loop identifier metadata node directly:
outer.for.body:
...
%val1 = load i32, i32* %arrayidx3, !llvm.mem.parallel_loop_access !2
...
br label %inner.for.body
inner.for.body:
...
%val0 = load i32, i32* %arrayidx1, !llvm.mem.parallel_loop_access !0
...
store i32 %val0, i32* %arrayidx2, !llvm.mem.parallel_loop_access !0
...
br i1 %exitcond, label %inner.for.end, label %inner.for.body, !llvm.loop !1
inner.for.end:
...
store i32 %val1, i32* %arrayidx4, !llvm.mem.parallel_loop_access !2
...
br i1 %exitcond, label %outer.for.end, label %outer.for.body, !llvm.loop !2
outer.for.end: ; preds = %for.body
...
!0 = !{!1, !2} ; a list of loop identifiers
!1 = !{!1} ; an identifier for the inner loop
!2 = !{!2} ; an identifier for the outer loop
irr_loop metadata may be attached to the terminator instruction of a basic block that’s an irreducible loop header (note that an irreducible loop has more than once header basic blocks.) If irr_loop metadata is attached to the terminator instruction of a basic block that is not really an irreducible loop header, the behavior is undefined. The intent of this metadata is to improve the accuracy of the block frequency propagation. For example, in the code below, the block header0 may have a loop header weight (relative to the other headers of the irreducible loop) of 100:
header0:
...
br i1 %cmp, label %t1, label %t2, !irr_loop !0
...
!0 = !{"loop_header_weight", i64 100}
Irreducible loop header weights are typically based on profile data.
The experimental invariant.group metadata may be attached to load/store instructions referencing a single metadata with no entries. The existence of the invariant.group metadata on the instruction tells the optimizer that every load and store to the same pointer operand can be assumed to load or store the same value (but see the llvm.launder.invariant.group intrinsic which affects when two pointers are considered the same). Pointers returned by bitcast or getelementptr with only zero indices are considered the same.
Examples:
@unknownPtr = external global i8
...
%ptr = alloca i8
store i8 42, i8* %ptr, !invariant.group !0
call void @foo(i8* %ptr)
%a = load i8, i8* %ptr, !invariant.group !0 ; Can assume that value under %ptr didn't change
call void @foo(i8* %ptr)
%newPtr = call i8* @getPointer(i8* %ptr)
%c = load i8, i8* %newPtr, !invariant.group !0 ; Can't assume anything, because we only have information about %ptr
%unknownValue = load i8, i8* @unknownPtr
store i8 %unknownValue, i8* %ptr, !invariant.group !0 ; Can assume that %unknownValue == 42
call void @foo(i8* %ptr)
%newPtr2 = call i8* @llvm.launder.invariant.group(i8* %ptr)
%d = load i8, i8* %newPtr2, !invariant.group !0 ; Can't step through launder.invariant.group to get value of %ptr
...
declare void @foo(i8*)
declare i8* @getPointer(i8*)
declare i8* @llvm.launder.invariant.group(i8*)
!0 = !{}
The invariant.group metadata must be dropped when replacing one pointer by another based on aliasing information. This is because invariant.group is tied to the SSA value of the pointer operand.
%v = load i8, i8* %x, !invariant.group !0
; if %x mustalias %y then we can replace the above instruction with
%v = load i8, i8* %y
Note that this is an experimental feature, which means that its semantics might change in the future.
The associated metadata may be attached to a global object declaration with a single argument that references another global object.
This metadata prevents discarding of the global object in linker GC unless the referenced object is also discarded. The linker support for this feature is spotty. For best compatibility, globals carrying this metadata may also:
It does not have any effect on non-ELF targets.
Example:
$a = comdat any
@a = global i32 1, comdat $a
@b = internal global i32 2, comdat $a, section "abc", !associated !0
!0 = !{i32* @a}
The prof metadata is used to record profile data in the IR. The first operand of the metadata node indicates the profile metadata type. There are currently 3 types: branch_weights, function_entry_count, and VP.
Branch weight metadata attached to a branch, select, switch or call instruction represents the likeliness of the associated branch being taken. For more information, see LLVM Branch Weight Metadata.
Function entry count metadata can be attached to function definitions to record the number of times the function is called. Used with BFI information, it is also used to derive the basic block profile count. For more information, see LLVM Branch Weight Metadata.
VP (value profile) metadata can be attached to instructions that have value profile information. Currently this is indirect calls (where it records the hottest callees) and calls to memory intrinsics such as memcpy, memmove, and memset (where it records the hottest byte lengths).
Each VP metadata node contains “VP” string, then a uint32_t value for the value profiling kind, a uint64_t value for the total number of times the instruction is executed, followed by uint64_t value and execution count pairs. The value profiling kind is 0 for indirect call targets and 1 for memory operations. For indirect call targets, each profile value is a hash of the callee function name, and for memory operations each value is the byte length.
Note that the value counts do not need to add up to the total count listed in the third operand (in practice only the top hottest values are tracked and reported).
Indirect call example:
call void %f(), !prof !1
!1 = !{!"VP", i32 0, i64 1600, i64 7651369219802541373, i64 1030, i64 -4377547752858689819, i64 410}
Note that the VP type is 0 (the second operand), which indicates this is an indirect call value profile data. The third operand indicates that the indirect call executed 1600 times. The 4th and 6th operands give the hashes of the 2 hottest target functions’ names (this is the same hash used to represent function names in the profile database), and the 5th and 7th operands give the execution count that each of the respective prior target functions was called.
Information about the module as a whole is difficult to convey to LLVM’s subsystems. The LLVM IR isn’t sufficient to transmit this information. The llvm.module.flags named metadata exists in order to facilitate this. These flags are in the form of key / value pairs — much like a dictionary — making it easy for any subsystem who cares about a flag to look it up.
The llvm.module.flags metadata contains a list of metadata triplets. Each triplet has the following form:
When two (or more) modules are merged together, the resulting llvm.module.flags metadata is the union of the modules’ flags. That is, for each unique metadata ID string, there will be exactly one entry in the merged modules llvm.module.flags metadata table, and the value for that entry will be determined by the merge behavior flag, as described below. The only exception is that entries with the Require behavior are always preserved.
The following behaviors are supported:
Value | Behavior |
---|---|
1 |
|
2 |
|
3 |
|
4 |
|
5 |
|
6 |
|
7 |
|
It is an error for a particular unique flag ID to have multiple behaviors, except in the case of Require (which adds restrictions on another metadata value) or Override.
An example of module flags:
!0 = !{ i32 1, !"foo", i32 1 }
!1 = !{ i32 4, !"bar", i32 37 }
!2 = !{ i32 2, !"qux", i32 42 }
!3 = !{ i32 3, !"qux",
!{
!"foo", i32 1
}
}
!llvm.module.flags = !{ !0, !1, !2, !3 }
Metadata !0 has the ID !"foo" and the value ‘1’. The behavior if two or more !"foo" flags are seen is to emit an error if their values are not equal.
Metadata !1 has the ID !"bar" and the value ‘37’. The behavior if two or more !"bar" flags are seen is to use the value ‘37’.
Metadata !2 has the ID !"qux" and the value ‘42’. The behavior if two or more !"qux" flags are seen is to emit a warning if their values are not equal.
Metadata !3 has the ID !"qux" and the value:
!{ !"foo", i32 1 }
The behavior is to emit an error if the llvm.module.flags does not contain a flag with the ID !"foo" that has the value ‘1’ after linking is performed.
On the Mach-O platform, Objective-C stores metadata about garbage collection in a special section called “image info”. The metadata consists of a version number and a bitmask specifying what types of garbage collection are supported (if any) by the file. If two or more modules are linked together their garbage collection metadata needs to be merged rather than appended together.
The Objective-C garbage collection module flags metadata consists of the following key-value pairs:
Key | Value |
---|---|
Objective-C Version | [Required] — The Objective-C ABI version. Valid values are 1 and 2. |
Objective-C Image Info Version | [Required] — The version of the image info section. Currently always 0. |
Objective-C Image Info Section | [Required] — The section to place the metadata. Valid values are "__OBJC, __image_info, regular" for Objective-C ABI version 1, and "__DATA,__objc_imageinfo, regular, no_dead_strip" for Objective-C ABI version 2. |
Objective-C Garbage Collection | [Required] — Specifies whether garbage collection is supported or not. Valid values are 0, for no garbage collection, and 2, for garbage collection supported. |
Objective-C GC Only | [Optional] — Specifies that only garbage collection is supported. If present, its value must be 6. This flag requires that the Objective-C Garbage Collection flag have the value 2. |
Some important flag interactions:
The ARM backend emits a section into each generated object file describing the options that it was compiled with (in a compiler-independent way) to prevent linking incompatible objects, and to allow automatic library selection. Some of these options are not visible at the IR level, namely wchar_t width and enum width.
To pass this information to the backend, these options are encoded in module flags metadata, using the following key-value pairs:
Key | Value |
---|---|
short_wchar |
|
short_enum |
|
For example, the following metadata section specifies that the module was compiled with a wchar_t width of 4 bytes, and the underlying type of an enum is the smallest type which can represent all of its values:
!llvm.module.flags = !{!0, !1}
!0 = !{i32 1, !"short_wchar", i32 1}
!1 = !{i32 1, !"short_enum", i32 0}
Some targets support embedding flags to the linker inside individual object files. Typically this is used in conjunction with language extensions which allow source files to explicitly declare the libraries they depend on, and have these automatically be transmitted to the linker via object files.
These flags are encoded in the IR using named metadata with the name !llvm.linker.options. Each operand is expected to be a metadata node which should be a list of other metadata nodes, each of which should be a list of metadata strings defining linker options.
For example, the following metadata section specifies two separate sets of linker options, presumably to link against libz and the Cocoa framework:
!0 = !{ !"-lz" },
!1 = !{ !"-framework", !"Cocoa" } } }
!llvm.linker.options = !{ !0, !1 }
The metadata encoding as lists of lists of options, as opposed to a collapsed list of options, is chosen so that the IR encoding can use multiple option strings to specify e.g., a single library, while still having that specifier be preserved as an atomic element that can be recognized by a target specific assembly writer or object file emitter.
Each individual option is required to be either a valid option for the target’s linker, or an option that is reserved by the target specific assembly writer or object file emitter. No other aspect of these options is defined by the IR.
Compiling with ThinLTO causes the building of a compact summary of the module that is emitted into the bitcode. The summary is emitted into the LLVM assembly and identified in syntax by a caret (‘^‘).
Note that temporarily the summary entries are skipped when parsing the assembly, although the parsing support is actively being implemented. The following describes when the summary entries will be parsed once implemented. The summary will be parsed into a ModuleSummaryIndex object under the same conditions where summary index is currently built from bitcode. Specifically, tools that test the Thin Link portion of a ThinLTO compile (i.e. llvm-lto and llvm-lto2), or when parsing a combined index for a distributed ThinLTO backend via clang’s “-fthinlto-index=<>” flag. Additionally, it will be parsed into a bitcode output, along with the Module IR, via the “llvm-as” tool. Tools that parse the Module IR for the purposes of optimization (e.g. “clang -x ir” and “opt”), will ignore the summary entries (just as they currently ignore summary entries in a bitcode input file).
There are currently 3 types of summary entries in the LLVM assembly: module paths, global values, and type identifiers.
Each module path summary entry lists a module containing global values included in the summary. For a single IR module there will be one such entry, but in a combined summary index produced during the thin link, there will be one module path entry per linked module with summary.
Example:
^0 = module: (path: "/path/to/file.o", hash: (2468601609, 1329373163, 1565878005, 638838075, 3148790418))
The path field is a string path to the bitcode file, and the hash field is the 160-bit SHA-1 hash of the IR bitcode contents, used for incremental builds and caching.
Each global value summary entry corresponds to a global value defined or referenced by a summarized module.
Example:
^4 = gv: (name: "f"[, summaries: (Summary)[, (Summary)]*]?) ; guid = 14740650423002898831
For declarations, there will not be a summary list. For definitions, a global value will contain a list of summaries, one per module containing a definition. There can be multiple entries in a combined summary index for symbols with weak linkage.
Each Summary format will depend on whether the global value is a function, variable, or alias.
If the global value is a function, the Summary entry will look like:
function: (module: ^0, flags: (linkage: external, notEligibleToImport: 0, live: 0, dsoLocal: 0), insts: 2[, FuncFlags]?[, Calls]?[, TypeIdInfo]?[, Refs]?
The module field includes the summary entry id for the module containing this definition, and the flags field contains information such as the linkage type, a flag indicating whether it is legal to import the definition, whether it is globally live and whether the linker resolved it to a local definition (the latter two are populated during the thin link). The insts field contains the number of IR instructions in the function. Finally, there are several optional fields: FuncFlags, Calls, TypeIdInfo, Refs.
If the global value is a variable, the Summary entry will look like:
variable: (module: ^0, flags: (linkage: external, notEligibleToImport: 0, live: 0, dsoLocal: 0)[, Refs]?
The variable entry contains a subset of the fields in a function summary, see the descriptions there.
If the global value is an alias, the Summary entry will look like:
alias: (module: ^0, flags: (linkage: external, notEligibleToImport: 0, live: 0, dsoLocal: 0), aliasee: ^2)
The module and flags fields are as described for a function summary. The aliasee field contains a reference to the global value summary entry of the aliasee.
The optional FuncFlags field looks like:
funcFlags: (readNone: 0, readOnly: 0, noRecurse: 0, returnDoesNotAlias: 0)
If unspecified, flags are assumed to hold the conservative false value of 0.
The optional Calls field looks like:
calls: ((Callee)[, (Callee)]*)
where each Callee looks like:
callee: ^1[, hotness: None]?[, relbf: 0]?
The callee refers to the summary entry id of the callee. At most one of hotness (which can take the values Unknown, Cold, None, Hot, and Critical), and relbf (which holds the integer branch frequency relative to the entry frequency, scaled down by 2^8) may be specified. The defaults are Unknown and 0, respectively.
The optional Refs field looks like:
refs: ((Ref)[, (Ref)]*)
where each Ref contains a reference to the summary id of the referenced value (e.g. ^1).
The optional TypeIdInfo field, used for Control Flow Integrity, looks like:
typeIdInfo: [(TypeTests)]?[, (TypeTestAssumeVCalls)]?[, (TypeCheckedLoadVCalls)]?[, (TypeTestAssumeConstVCalls)]?[, (TypeCheckedLoadConstVCalls)]?
These optional fields have the following forms:
typeTests: (TypeIdRef[, TypeIdRef]*)
Where each TypeIdRef refers to a type id by summary id or GUID.
typeTestAssumeVCalls: (VFuncId[, VFuncId]*)
Where each VFuncId has the format:
vFuncId: (TypeIdRef, offset: 16)
Where each TypeIdRef refers to a type id by summary id or GUID preceeded by a guid: tag.
typeCheckedLoadVCalls: (VFuncId[, VFuncId]*)
Where each VFuncId has the format described for TypeTestAssumeVCalls.
typeTestAssumeConstVCalls: (ConstVCall[, ConstVCall]*)
Where each ConstVCall has the format:
VFuncId, args: (Arg[, Arg]*)
and where each VFuncId has the format described for TypeTestAssumeVCalls, and each Arg is an integer argument number.
typeCheckedLoadConstVCalls: (ConstVCall[, ConstVCall]*)
Where each ConstVCall has the format described for TypeTestAssumeConstVCalls.
Each type id summary entry corresponds to a type identifier resolution which is generated during the LTO link portion of the compile when building with Control Flow Integrity, so these are only present in a combined summary index.
Example:
^4 = typeid: (name: "_ZTS1A", summary: (typeTestRes: (kind: allOnes, sizeM1BitWidth: 7[, alignLog2: 0]?[, sizeM1: 0]?[, bitMask: 0]?[, inlineBits: 0]?)[, WpdResolutions]?)) ; guid = 7004155349499253778
The typeTestRes gives the type test resolution kind (which may be unsat, byteArray, inline, single, or allOnes), and the size-1 bit width. It is followed by optional flags, which default to 0, and an optional WpdResolutions (whole program devirtualization resolution) field that looks like:
wpdResolutions: ((offset: 0, WpdRes)[, (offset: 1, WpdRes)]*
where each entry is a mapping from the given byte offset to the whole-program devirtualization resolution WpdRes, that has one of the following formats:
wpdRes: (kind: branchFunnel)
wpdRes: (kind: singleImpl, singleImplName: "_ZN1A1nEi")
wpdRes: (kind: indir)
Additionally, each wpdRes has an optional resByArg field, which describes the resolutions for calls with all constant integer arguments:
resByArg: (ResByArg[, ResByArg]*)
where ResByArg is:
args: (Arg[, Arg]*), byArg: (kind: UniformRetVal[, info: 0][, byte: 0][, bit: 0])
Where the kind can be Indir, UniformRetVal, UniqueRetVal or VirtualConstProp. The info field is only used if the kind is UniformRetVal (indicates the uniform return value), or UniqueRetVal (holds the return value associated with the unique vtable (0 or 1)). The byte and bit fields are only used if the target does not support the use of absolute symbols to store constants.
LLVM has a number of “magic” global variables that contain data that affect code generation or other IR semantics. These are documented here. All globals of this sort should have a section specified as “llvm.metadata”. This section and all globals that start with “llvm.” are reserved for use by LLVM.
The @llvm.used global is an array which has appending linkage. This array contains a list of pointers to named global variables, functions and aliases which may optionally have a pointer cast formed of bitcast or getelementptr. For example, a legal use of it is:
@X = global i8 4
@Y = global i32 123
@llvm.used = appending global [2 x i8*] [
i8* @X,
i8* bitcast (i32* @Y to i8*)
], section "llvm.metadata"
If a symbol appears in the @llvm.used list, then the compiler, assembler, and linker are required to treat the symbol as if there is a reference to the symbol that it cannot see (which is why they have to be named). For example, if a variable has internal linkage and no references other than that from the @llvm.used list, it cannot be deleted. This is commonly used to represent references from inline asms and other things the compiler cannot “see”, and corresponds to “attribute((used))” in GNU C.
On some targets, the code generator must emit a directive to the assembler or object file to prevent the assembler and linker from molesting the symbol.
The @llvm.compiler.used directive is the same as the @llvm.used directive, except that it only prevents the compiler from touching the symbol. On targets that support it, this allows an intelligent linker to optimize references to the symbol without being impeded as it would be by @llvm.used.
This is a rare construct that should only be used in rare circumstances, and should not be exposed to source languages.
%0 = type { i32, void ()*, i8* }
@llvm.global_ctors = appending global [1 x %0] [%0 { i32 65535, void ()* @ctor, i8* @data }]
The @llvm.global_ctors array contains a list of constructor functions, priorities, and an optional associated global or function. The functions referenced by this array will be called in ascending order of priority (i.e. lowest first) when the module is loaded. The order of functions with the same priority is not defined.
If the third field is present, non-null, and points to a global variable or function, the initializer function will only run if the associated data from the current module is not discarded.
%0 = type { i32, void ()*, i8* }
@llvm.global_dtors = appending global [1 x %0] [%0 { i32 65535, void ()* @dtor, i8* @data }]
The @llvm.global_dtors array contains a list of destructor functions, priorities, and an optional associated global or function. The functions referenced by this array will be called in descending order of priority (i.e. highest first) when the module is unloaded. The order of functions with the same priority is not defined.
If the third field is present, non-null, and points to a global variable or function, the destructor function will only run if the associated data from the current module is not discarded.
The LLVM instruction set consists of several different classifications of instructions: terminator instructions, binary instructions, bitwise binary instructions, memory instructions, and other instructions.
As mentioned previously, every basic block in a program ends with a “Terminator” instruction, which indicates which block should be executed after the current block is finished. These terminator instructions typically yield a ‘void‘ value: they produce control flow, not values (the one exception being the ‘invoke‘ instruction).
The terminator instructions are: ‘ret‘, ‘br‘, ‘switch‘, ‘indirectbr‘, ‘invoke‘, ‘resume‘, ‘catchswitch‘, ‘catchret‘, ‘cleanupret‘, and ‘unreachable‘.
ret <type> <value> ; Return a value from a non-void function
ret void ; Return from void function
The ‘ret‘ instruction is used to return control flow (and optionally a value) from a function back to the caller.
There are two forms of the ‘ret‘ instruction: one that returns a value and then causes control flow, and one that just causes control flow to occur.
The ‘ret‘ instruction optionally accepts a single argument, the return value. The type of the return value must be a ‘first class‘ type.
A function is not well formed if it it has a non-void return type and contains a ‘ret‘ instruction with no return value or a return value with a type that does not match its type, or if it has a void return type and contains a ‘ret‘ instruction with a return value.
When the ‘ret‘ instruction is executed, control flow returns back to the calling function’s context. If the caller is a “call” instruction, execution continues at the instruction after the call. If the caller was an “invoke” instruction, execution continues at the beginning of the “normal” destination block. If the instruction returns a value, that value shall set the call or invoke instruction’s return value.
The ‘br‘ instruction is used to cause control flow to transfer to a different basic block in the current function. There are two forms of this instruction, corresponding to a conditional branch and an unconditional branch.
The conditional branch form of the ‘br‘ instruction takes a single ‘i1‘ value and two ‘label‘ values. The unconditional form of the ‘br‘ instruction takes a single ‘label‘ value as a target.
Upon execution of a conditional ‘br‘ instruction, the ‘i1‘ argument is evaluated. If the value is true, control flows to the ‘iftrue‘ label argument. If “cond” is false, control flows to the ‘iffalse‘ label argument.
The ‘switch‘ instruction is used to transfer control flow to one of several different places. It is a generalization of the ‘br‘ instruction, allowing a branch to occur to one of many possible destinations.
The ‘switch‘ instruction uses three parameters: an integer comparison value ‘value‘, a default ‘label‘ destination, and an array of pairs of comparison value constants and ‘label‘s. The table is not allowed to contain duplicate constant entries.
The switch instruction specifies a table of values and destinations. When the ‘switch‘ instruction is executed, this table is searched for the given value. If the value is found, control flow is transferred to the corresponding destination; otherwise, control flow is transferred to the default destination.
Depending on properties of the target machine and the particular switch instruction, this instruction may be code generated in different ways. For example, it could be generated as a series of chained conditional branches or with a lookup table.
; Emulate a conditional br instruction
%Val = zext i1 %value to i32
switch i32 %Val, label %truedest [ i32 0, label %falsedest ]
; Emulate an unconditional br instruction
switch i32 0, label %dest [ ]
; Implement a jump table:
switch i32 %val, label %otherwise [ i32 0, label %onzero
i32 1, label %onone
i32 2, label %ontwo ]
The ‘indirectbr‘ instruction implements an indirect branch to a label within the current function, whose address is specified by “address”. Address must be derived from a blockaddress constant.
The ‘address‘ argument is the address of the label to jump to. The rest of the arguments indicate the full set of possible destinations that the address may point to. Blocks are allowed to occur multiple times in the destination list, though this isn’t particularly useful.
This destination list is required so that dataflow analysis has an accurate understanding of the CFG.
Control transfers to the block specified in the address argument. All possible destination blocks must be listed in the label list, otherwise this instruction has undefined behavior. This implies that jumps to labels defined in other functions have undefined behavior as well.
This is typically implemented with a jump through a register.
<result> = invoke [cconv] [ret attrs] <ty>|<fnty> <fnptrval>(<function args>) [fn attrs]
[operand bundles] to label <normal label> unwind label <exception label>
The ‘invoke‘ instruction causes control to transfer to a specified function, with the possibility of control flow transfer to either the ‘normal‘ label or the ‘exception‘ label. If the callee function returns with the “ret” instruction, control flow will return to the “normal” label. If the callee (or any indirect callees) returns via the “resume” instruction or other exception handling mechanism, control is interrupted and continued at the dynamically nearest “exception” label.
The ‘exception‘ label is a landing pad for the exception. As such, ‘exception‘ label is required to have the “landingpad” instruction, which contains the information about the behavior of the program after unwinding happens, as its first non-PHI instruction. The restrictions on the “landingpad” instruction’s tightly couples it to the “invoke” instruction, so that the important information contained within the “landingpad” instruction can’t be lost through normal code motion.
This instruction requires several arguments:
This instruction is designed to operate as a standard ‘call‘ instruction in most regards. The primary difference is that it establishes an association with a label, which is used by the runtime library to unwind the stack.
This instruction is used in languages with destructors to ensure that proper cleanup is performed in the case of either a longjmp or a thrown exception. Additionally, this is important for implementation of ‘catch‘ clauses in high-level languages that support them.
For the purposes of the SSA form, the definition of the value returned by the ‘invoke‘ instruction is deemed to occur on the edge from the current block to the “normal” label. If the callee unwinds then no return value is available.
The ‘resume‘ instruction requires one argument, which must have the same type as the result of any ‘landingpad‘ instruction in the same function.
The ‘resume‘ instruction resumes propagation of an existing (in-flight) exception whose unwinding was interrupted with a landingpad instruction.
<resultval> = catchswitch within <parent> [ label <handler1>, label <handler2>, ... ] unwind to caller
<resultval> = catchswitch within <parent> [ label <handler1>, label <handler2>, ... ] unwind label <default>
The ‘catchswitch‘ instruction is used by LLVM’s exception handling system to describe the set of possible catch handlers that may be executed by the EH personality routine.
The parent argument is the token of the funclet that contains the catchswitch instruction. If the catchswitch is not inside a funclet, this operand may be the token none.
The default argument is the label of another basic block beginning with either a cleanuppad or catchswitch instruction. This unwind destination must be a legal target with respect to the parent links, as described in the exception handling documentation.
The handlers are a nonempty list of successor blocks that each begin with a catchpad instruction.
Executing this instruction transfers control to one of the successors in handlers, if appropriate, or continues to unwind via the unwind label if present.
The catchswitch is both a terminator and a “pad” instruction, meaning that it must be both the first non-phi instruction and last instruction in the basic block. Therefore, it must be the only non-phi instruction in the block.
The first argument to a ‘catchret‘ indicates which catchpad it exits. It must be a catchpad. The second argument to a ‘catchret‘ specifies where control will transfer to next.
The ‘catchret‘ instruction ends an existing (in-flight) exception whose unwinding was interrupted with a catchpad instruction. The personality function gets a chance to execute arbitrary code to, for example, destroy the active exception. Control then transfers to normal.
The token argument must be a token produced by a catchpad instruction. If the specified catchpad is not the most-recently-entered not-yet-exited funclet pad (as described in the EH documentation), the catchret‘s behavior is undefined.
The ‘cleanupret‘ instruction requires one argument, which indicates which cleanuppad it exits, and must be a cleanuppad. If the specified cleanuppad is not the most-recently-entered not-yet-exited funclet pad (as described in the EH documentation), the cleanupret‘s behavior is undefined.
The ‘cleanupret‘ instruction also has an optional successor, continue, which must be the label of another basic block beginning with either a cleanuppad or catchswitch instruction. This unwind destination must be a legal target with respect to the parent links, as described in the exception handling documentation.
The ‘cleanupret‘ instruction indicates to the personality function that one cleanuppad it transferred control to has ended. It transfers control to continue or unwinds out of the function.
The ‘unreachable‘ instruction has no defined semantics. This instruction is used to inform the optimizer that a particular portion of the code is not reachable. This can be used to indicate that the code after a no-return function cannot be reached, and other facts.
The ‘unreachable‘ instruction has no defined semantics.
Binary operators are used to do most of the computation in a program. They require two operands of the same type, execute an operation on them, and produce a single value. The operands might represent multiple data, as is the case with the vector data type. The result value has the same type as its operands.
There are several different binary operators:
<result> = add <ty> <op1>, <op2> ; yields ty:result
<result> = add nuw <ty> <op1>, <op2> ; yields ty:result
<result> = add nsw <ty> <op1>, <op2> ; yields ty:result
<result> = add nuw nsw <ty> <op1>, <op2> ; yields ty:result
The two arguments to the ‘add‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
The value produced is the integer sum of the two operands.
If the sum has unsigned overflow, the result returned is the mathematical result modulo 2n, where n is the bit width of the result.
Because LLVM integers use a two’s complement representation, this instruction is appropriate for both signed and unsigned integers.
nuw and nsw stand for “No Unsigned Wrap” and “No Signed Wrap”, respectively. If the nuw and/or nsw keywords are present, the result value of the add is a poison value if unsigned and/or signed overflow, respectively, occurs.
The two arguments to the ‘fadd‘ instruction must be floating-point or vector of floating-point values. Both arguments must have identical types.
The value produced is the floating-point sum of the two operands. This instruction is assumed to execute in the default floating-point environment. This instruction can also take any number of fast-math flags, which are optimization hints to enable otherwise unsafe floating-point optimizations:
<result> = sub <ty> <op1>, <op2> ; yields ty:result
<result> = sub nuw <ty> <op1>, <op2> ; yields ty:result
<result> = sub nsw <ty> <op1>, <op2> ; yields ty:result
<result> = sub nuw nsw <ty> <op1>, <op2> ; yields ty:result
The ‘sub‘ instruction returns the difference of its two operands.
Note that the ‘sub‘ instruction is used to represent the ‘neg‘ instruction present in most other intermediate representations.
The two arguments to the ‘sub‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
The value produced is the integer difference of the two operands.
If the difference has unsigned overflow, the result returned is the mathematical result modulo 2n, where n is the bit width of the result.
Because LLVM integers use a two’s complement representation, this instruction is appropriate for both signed and unsigned integers.
nuw and nsw stand for “No Unsigned Wrap” and “No Signed Wrap”, respectively. If the nuw and/or nsw keywords are present, the result value of the sub is a poison value if unsigned and/or signed overflow, respectively, occurs.
The ‘fsub‘ instruction returns the difference of its two operands.
Note that the ‘fsub‘ instruction is used to represent the ‘fneg‘ instruction present in most other intermediate representations.
The two arguments to the ‘fsub‘ instruction must be floating-point or vector of floating-point values. Both arguments must have identical types.
The value produced is the floating-point difference of the two operands. This instruction is assumed to execute in the default floating-point environment. This instruction can also take any number of fast-math flags, which are optimization hints to enable otherwise unsafe floating-point optimizations:
<result> = mul <ty> <op1>, <op2> ; yields ty:result
<result> = mul nuw <ty> <op1>, <op2> ; yields ty:result
<result> = mul nsw <ty> <op1>, <op2> ; yields ty:result
<result> = mul nuw nsw <ty> <op1>, <op2> ; yields ty:result
The two arguments to the ‘mul‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
The value produced is the integer product of the two operands.
If the result of the multiplication has unsigned overflow, the result returned is the mathematical result modulo 2n, where n is the bit width of the result.
Because LLVM integers use a two’s complement representation, and the result is the same width as the operands, this instruction returns the correct result for both signed and unsigned integers. If a full product (e.g. i32 * i32 -> i64) is needed, the operands should be sign-extended or zero-extended as appropriate to the width of the full product.
nuw and nsw stand for “No Unsigned Wrap” and “No Signed Wrap”, respectively. If the nuw and/or nsw keywords are present, the result value of the mul is a poison value if unsigned and/or signed overflow, respectively, occurs.
The two arguments to the ‘fmul‘ instruction must be floating-point or vector of floating-point values. Both arguments must have identical types.
The value produced is the floating-point product of the two operands. This instruction is assumed to execute in the default floating-point environment. This instruction can also take any number of fast-math flags, which are optimization hints to enable otherwise unsafe floating-point optimizations:
<result> = udiv <ty> <op1>, <op2> ; yields ty:result
<result> = udiv exact <ty> <op1>, <op2> ; yields ty:result
The two arguments to the ‘udiv‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
The value produced is the unsigned integer quotient of the two operands.
Note that unsigned integer division and signed integer division are distinct operations; for signed integer division, use ‘sdiv‘.
Division by zero is undefined behavior. For vectors, if any element of the divisor is zero, the operation has undefined behavior.
If the exact keyword is present, the result value of the udiv is a poison value if %op1 is not a multiple of %op2 (as such, “((a udiv exact b) mul b) == a”).
<result> = sdiv <ty> <op1>, <op2> ; yields ty:result
<result> = sdiv exact <ty> <op1>, <op2> ; yields ty:result
The two arguments to the ‘sdiv‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
The value produced is the signed integer quotient of the two operands rounded towards zero.
Note that signed integer division and unsigned integer division are distinct operations; for unsigned integer division, use ‘udiv‘.
Division by zero is undefined behavior. For vectors, if any element of the divisor is zero, the operation has undefined behavior. Overflow also leads to undefined behavior; this is a rare case, but can occur, for example, by doing a 32-bit division of -2147483648 by -1.
If the exact keyword is present, the result value of the sdiv is a poison value if the result would be rounded.
The two arguments to the ‘fdiv‘ instruction must be floating-point or vector of floating-point values. Both arguments must have identical types.
The value produced is the floating-point quotient of the two operands. This instruction is assumed to execute in the default floating-point environment. This instruction can also take any number of fast-math flags, which are optimization hints to enable otherwise unsafe floating-point optimizations:
The ‘urem‘ instruction returns the remainder from the unsigned division of its two arguments.
The two arguments to the ‘urem‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
This instruction returns the unsigned integer remainder of a division. This instruction always performs an unsigned division to get the remainder.
Note that unsigned integer remainder and signed integer remainder are distinct operations; for signed integer remainder, use ‘srem‘.
Taking the remainder of a division by zero is undefined behavior. For vectors, if any element of the divisor is zero, the operation has undefined behavior.
The ‘srem‘ instruction returns the remainder from the signed division of its two operands. This instruction can also take vector versions of the values in which case the elements must be integers.
The two arguments to the ‘srem‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
This instruction returns the remainder of a division (where the result is either zero or has the same sign as the dividend, op1), not the modulo operator (where the result is either zero or has the same sign as the divisor, op2) of a value. For more information about the difference, see The Math Forum. For a table of how this is implemented in various languages, please see Wikipedia: modulo operation.
Note that signed integer remainder and unsigned integer remainder are distinct operations; for unsigned integer remainder, use ‘urem‘.
Taking the remainder of a division by zero is undefined behavior. For vectors, if any element of the divisor is zero, the operation has undefined behavior. Overflow also leads to undefined behavior; this is a rare case, but can occur, for example, by taking the remainder of a 32-bit division of -2147483648 by -1. (The remainder doesn’t actually overflow, but this rule lets srem be implemented using instructions that return both the result of the division and the remainder.)
The two arguments to the ‘frem‘ instruction must be floating-point or vector of floating-point values. Both arguments must have identical types.
The value produced is the floating-point remainder of the two operands. This is the same output as a libm ‘fmod‘ function, but without any possibility of setting errno. The remainder has the same sign as the dividend. This instruction is assumed to execute in the default floating-point environment. This instruction can also take any number of fast-math flags, which are optimization hints to enable otherwise unsafe floating-point optimizations:
Bitwise binary operators are used to do various forms of bit-twiddling in a program. They are generally very efficient instructions and can commonly be strength reduced from other instructions. They require two operands of the same type, execute an operation on them, and produce a single value. The resulting value is the same type as its operands.
<result> = shl <ty> <op1>, <op2> ; yields ty:result
<result> = shl nuw <ty> <op1>, <op2> ; yields ty:result
<result> = shl nsw <ty> <op1>, <op2> ; yields ty:result
<result> = shl nuw nsw <ty> <op1>, <op2> ; yields ty:result
The ‘shl‘ instruction returns the first operand shifted to the left a specified number of bits.
Both arguments to the ‘shl‘ instruction must be the same integer or vector of integer type. ‘op2‘ is treated as an unsigned value.
The value produced is op1 * 2op2 mod 2n, where n is the width of the result. If op2 is (statically or dynamically) equal to or larger than the number of bits in op1, this instruction returns a poison value. If the arguments are vectors, each vector element of op1 is shifted by the corresponding shift amount in op2.
If the nuw keyword is present, then the shift produces a poison value if it shifts out any non-zero bits. If the nsw keyword is present, then the shift produces a poison value if it shifts out any bits that disagree with the resultant sign bit.
<result> = lshr <ty> <op1>, <op2> ; yields ty:result
<result> = lshr exact <ty> <op1>, <op2> ; yields ty:result
The ‘lshr‘ instruction (logical shift right) returns the first operand shifted to the right a specified number of bits with zero fill.
Both arguments to the ‘lshr‘ instruction must be the same integer or vector of integer type. ‘op2‘ is treated as an unsigned value.
This instruction always performs a logical shift right operation. The most significant bits of the result will be filled with zero bits after the shift. If op2 is (statically or dynamically) equal to or larger than the number of bits in op1, this instruction returns a poison value. If the arguments are vectors, each vector element of op1 is shifted by the corresponding shift amount in op2.
If the exact keyword is present, the result value of the lshr is a poison value if any of the bits shifted out are non-zero.
<result> = lshr i32 4, 1 ; yields i32:result = 2
<result> = lshr i32 4, 2 ; yields i32:result = 1
<result> = lshr i8 4, 3 ; yields i8:result = 0
<result> = lshr i8 -2, 1 ; yields i8:result = 0x7F
<result> = lshr i32 1, 32 ; undefined
<result> = lshr <2 x i32> < i32 -2, i32 4>, < i32 1, i32 2> ; yields: result=<2 x i32> < i32 0x7FFFFFFF, i32 1>
<result> = ashr <ty> <op1>, <op2> ; yields ty:result
<result> = ashr exact <ty> <op1>, <op2> ; yields ty:result
The ‘ashr‘ instruction (arithmetic shift right) returns the first operand shifted to the right a specified number of bits with sign extension.
Both arguments to the ‘ashr‘ instruction must be the same integer or vector of integer type. ‘op2‘ is treated as an unsigned value.
This instruction always performs an arithmetic shift right operation, The most significant bits of the result will be filled with the sign bit of op1. If op2 is (statically or dynamically) equal to or larger than the number of bits in op1, this instruction returns a poison value. If the arguments are vectors, each vector element of op1 is shifted by the corresponding shift amount in op2.
If the exact keyword is present, the result value of the ashr is a poison value if any of the bits shifted out are non-zero.
<result> = ashr i32 4, 1 ; yields i32:result = 2
<result> = ashr i32 4, 2 ; yields i32:result = 1
<result> = ashr i8 4, 3 ; yields i8:result = 0
<result> = ashr i8 -2, 1 ; yields i8:result = -1
<result> = ashr i32 1, 32 ; undefined
<result> = ashr <2 x i32> < i32 -2, i32 4>, < i32 1, i32 3> ; yields: result=<2 x i32> < i32 -1, i32 0>
The two arguments to the ‘and‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
The two arguments to the ‘or‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
The ‘xor‘ instruction returns the bitwise logical exclusive or of its two operands. The xor is used to implement the “one’s complement” operation, which is the “~” operator in C.
The two arguments to the ‘xor‘ instruction must be integer or vector of integer values. Both arguments must have identical types.
LLVM supports several instructions to represent vector operations in a target-independent manner. These instructions cover the element-access and vector-specific operations needed to process vectors effectively. While LLVM does directly support these vector operations, many sophisticated algorithms will want to use target-specific intrinsics to take full advantage of a specific target.
The ‘extractelement‘ instruction extracts a single scalar element from a vector at a specified index.
The first operand of an ‘extractelement‘ instruction is a value of vector type. The second operand is an index indicating the position from which to extract the element. The index may be a variable of any integer type.
The result is a scalar of the same type as the element type of val. Its value is the value at position idx of val. If idx exceeds the length of val, the result is a poison value.
The ‘insertelement‘ instruction inserts a scalar element into a vector at a specified index.
The first operand of an ‘insertelement‘ instruction is a value of vector type. The second operand is a scalar value whose type must equal the element type of the first operand. The third operand is an index indicating the position at which to insert the value. The index may be a variable of any integer type.
The result is a vector of the same type as val. Its element values are those of val except at position idx, where it gets the value elt. If idx exceeds the length of val, the result is a poison value.
<result> = shufflevector <n x <ty>> <v1>, <n x <ty>> <v2>, <m x i32> <mask> ; yields <m x <ty>>
The ‘shufflevector‘ instruction constructs a permutation of elements from two input vectors, returning a vector with the same element type as the input and length that is the same as the shuffle mask.
The first two operands of a ‘shufflevector‘ instruction are vectors with the same type. The third argument is a shuffle mask whose element type is always ‘i32’. The result of the instruction is a vector whose length is the same as the shuffle mask and whose element type is the same as the element type of the first two operands.
The shuffle mask operand is required to be a constant vector with either constant integer or undef values.
The elements of the two input vectors are numbered from left to right across both of the vectors. The shuffle mask operand specifies, for each element of the result vector, which element of the two input vectors the result element gets. If the shuffle mask is undef, the result vector is undef. If any element of the mask operand is undef, that element of the result is undef. If the shuffle mask selects an undef element from one of the input vectors, the resulting element is undef.
<result> = shufflevector <4 x i32> %v1, <4 x i32> %v2,
<4 x i32> <i32 0, i32 4, i32 1, i32 5> ; yields <4 x i32>
<result> = shufflevector <4 x i32> %v1, <4 x i32> undef,
<4 x i32> <i32 0, i32 1, i32 2, i32 3> ; yields <4 x i32> - Identity shuffle.
<result> = shufflevector <8 x i32> %v1, <8 x i32> undef,
<4 x i32> <i32 0, i32 1, i32 2, i32 3> ; yields <4 x i32>
<result> = shufflevector <4 x i32> %v1, <4 x i32> %v2,
<8 x i32> <i32 0, i32 1, i32 2, i32 3, i32 4, i32 5, i32 6, i32 7 > ; yields <8 x i32>
LLVM supports several instructions for working with aggregate values.
The ‘extractvalue‘ instruction extracts the value of a member field from an aggregate value.
The first operand of an ‘extractvalue‘ instruction is a value of struct or array type. The other operands are constant indices to specify which value to extract in a similar manner as indices in a ‘getelementptr‘ instruction.
The major differences to getelementptr indexing are:
The result is the value at the position in the aggregate specified by the index operands.
<result> = insertvalue <aggregate type> <val>, <ty> <elt>, <idx>{, <idx>}* ; yields <aggregate type>
The first operand of an ‘insertvalue‘ instruction is a value of struct or array type. The second operand is a first-class value to insert. The following operands are constant indices indicating the position at which to insert the value in a similar manner as indices in a ‘extractvalue‘ instruction. The value to insert must have the same type as the value identified by the indices.
The result is an aggregate of the same type as val. Its value is that of val except that the value at the position specified by the indices is that of elt.
A key design point of an SSA-based representation is how it represents memory. In LLVM, no memory locations are in SSA form, which makes things very simple. This section describes how to read, write, and allocate memory in LLVM.
<result> = alloca [inalloca] <type> [, <ty> <NumElements>] [, align <alignment>] [, addrspace(<num>)] ; yields type addrspace(num)*:result
The ‘alloca‘ instruction allocates memory on the stack frame of the currently executing function, to be automatically released when this function returns to its caller. The object is always allocated in the address space for allocas indicated in the datalayout.
The ‘alloca‘ instruction allocates sizeof(<type>)*NumElements bytes of memory on the runtime stack, returning a pointer of the appropriate type to the program. If “NumElements” is specified, it is the number of elements allocated, otherwise “NumElements” is defaulted to be one. If a constant alignment is specified, the value result of the allocation is guaranteed to be aligned to at least that boundary. The alignment may not be greater than 1 << 29. If not specified, or if zero, the target can choose to align the allocation on any convenient boundary compatible with the type.
‘type‘ may be any sized type.
Memory is allocated; a pointer is returned. The operation is undefined if there is insufficient stack space for the allocation. ‘alloca‘d memory is automatically released when the function returns. The ‘alloca‘ instruction is commonly used to represent automatic variables that must have an address available. When the function returns (either with the ret or resume instructions), the memory is reclaimed. Allocating zero bytes is legal, but the returned pointer may not be unique. The order in which memory is allocated (ie., which way the stack grows) is not specified.
<result> = load [volatile] <ty>, <ty>* <pointer>[, align <alignment>][, !nontemporal !<index>][, !invariant.load !<index>][, !invariant.group !<index>][, !nonnull !<index>][, !dereferenceable !<deref_bytes_node>][, !dereferenceable_or_null !<deref_bytes_node>][, !align !<align_node>]
<result> = load atomic [volatile] <ty>, <ty>* <pointer> [syncscope("<target-scope>")] <ordering>, align <alignment> [, !invariant.group !<index>]
!<index> = !{ i32 1 }
!<deref_bytes_node> = !{i64 <dereferenceable_bytes>}
!<align_node> = !{ i64 <value_alignment> }
The argument to the load instruction specifies the memory address from which to load. The type specified must be a first class type of known size (i.e. not containing an opaque structural type). If the load is marked as volatile, then the optimizer is not allowed to modify the number or order of execution of this load with other volatile operations.
If the load is marked as atomic, it takes an extra ordering and optional syncscope("<target-scope>") argument. The release and acq_rel orderings are not valid on load instructions. Atomic loads produce defined results when they may see multiple atomic stores. The type of the pointee must be an integer, pointer, or floating-point type whose bit width is a power of two greater than or equal to eight and less than or equal to a target-specific size limit. align must be explicitly specified on atomic loads, and the load has undefined behavior if the alignment is not set to a value which is at least the size in bytes of the pointee. !nontemporal does not have any defined semantics for atomic loads.
The optional constant align argument specifies the alignment of the operation (that is, the alignment of the memory address). A value of 0 or an omitted align argument means that the operation has the ABI alignment for the target. It is the responsibility of the code emitter to ensure that the alignment information is correct. Overestimating the alignment results in undefined behavior. Underestimating the alignment may produce less efficient code. An alignment of 1 is always safe. The maximum possible alignment is 1 << 29. An alignment value higher than the size of the loaded type implies memory up to the alignment value bytes can be safely loaded without trapping in the default address space. Access of the high bytes can interfere with debugging tools, so should not be accessed if the function has the sanitize_thread or sanitize_address attributes.
The optional !nontemporal metadata must reference a single metadata name <index> corresponding to a metadata node with one i32 entry of value 1. The existence of the !nontemporal metadata on the instruction tells the optimizer and code generator that this load is not expected to be reused in the cache. The code generator may select special instructions to save cache bandwidth, such as the MOVNT instruction on x86.
The optional !invariant.load metadata must reference a single metadata name <index> corresponding to a metadata node with no entries. If a load instruction tagged with the !invariant.load metadata is executed, the optimizer may assume the memory location referenced by the load contains the same value at all points in the program where the memory location is known to be dereferenceable; otherwise, the behavior is undefined.
The optional !nonnull metadata must reference a single metadata name <index> corresponding to a metadata node with no entries. The existence of the !nonnull metadata on the instruction tells the optimizer that the value loaded is known to never be null. If the value is null at runtime, the behavior is undefined. This is analogous to the nonnull attribute on parameters and return values. This metadata can only be applied to loads of a pointer type.
The optional !dereferenceable metadata must reference a single metadata name <deref_bytes_node> corresponding to a metadata node with one i64 entry. The existence of the !dereferenceable metadata on the instruction tells the optimizer that the value loaded is known to be dereferenceable. The number of bytes known to be dereferenceable is specified by the integer value in the metadata node. This is analogous to the ‘’dereferenceable’’ attribute on parameters and return values. This metadata can only be applied to loads of a pointer type.
The optional !dereferenceable_or_null metadata must reference a single metadata name <deref_bytes_node> corresponding to a metadata node with one i64 entry. The existence of the !dereferenceable_or_null metadata on the instruction tells the optimizer that the value loaded is known to be either dereferenceable or null. The number of bytes known to be dereferenceable is specified by the integer value in the metadata node. This is analogous to the ‘’dereferenceable_or_null’’ attribute on parameters and return values. This metadata can only be applied to loads of a pointer type.
The optional !align metadata must reference a single metadata name <align_node> corresponding to a metadata node with one i64 entry. The existence of the !align metadata on the instruction tells the optimizer that the value loaded is known to be aligned to a boundary specified by the integer value in the metadata node. The alignment must be a power of 2. This is analogous to the ‘’align’’ attribute on parameters and return values. This metadata can only be applied to loads of a pointer type. If the returned value is not appropriately aligned at runtime, the behavior is undefined.
The location of memory pointed to is loaded. If the value being loaded is of scalar type then the number of bytes read does not exceed the minimum number of bytes needed to hold all bits of the type. For example, loading an i24 reads at most three bytes. When loading a value of a type like i20 with a size that is not an integral number of bytes, the result is undefined if the value was not originally written using a store of the same type.
store [volatile] <ty> <value>, <ty>* <pointer>[, align <alignment>][, !nontemporal !<index>][, !invariant.group !<index>] ; yields void
store atomic [volatile] <ty> <value>, <ty>* <pointer> [syncscope("<target-scope>")] <ordering>, align <alignment> [, !invariant.group !<index>] ; yields void
There are two arguments to the store instruction: a value to store and an address at which to store it. The type of the <pointer> operand must be a pointer to the first class type of the <value> operand. If the store is marked as volatile, then the optimizer is not allowed to modify the number or order of execution of this store with other volatile operations. Only values of first class types of known size (i.e. not containing an opaque structural type) can be stored.
If the store is marked as atomic, it takes an extra ordering and optional syncscope("<target-scope>") argument. The acquire and acq_rel orderings aren’t valid on store instructions. Atomic loads produce defined results when they may see multiple atomic stores. The type of the pointee must be an integer, pointer, or floating-point type whose bit width is a power of two greater than or equal to eight and less than or equal to a target-specific size limit. align must be explicitly specified on atomic stores, and the store has undefined behavior if the alignment is not set to a value which is at least the size in bytes of the pointee. !nontemporal does not have any defined semantics for atomic stores.
The optional constant align argument specifies the alignment of the operation (that is, the alignment of the memory address). A value of 0 or an omitted align argument means that the operation has the ABI alignment for the target. It is the responsibility of the code emitter to ensure that the alignment information is correct. Overestimating the alignment results in undefined behavior. Underestimating the alignment may produce less efficient code. An alignment of 1 is always safe. The maximum possible alignment is 1 << 29. An alignment value higher than the size of the stored type implies memory up to the alignment value bytes can be stored to without trapping in the default address space. Storing to the higher bytes however may result in data races if another thread can access the same address. Introducing a data race is not allowed. Storing to the extra bytes is not allowed even in situations where a data race is known to not exist if the function has the sanitize_address attribute.
The optional !nontemporal metadata must reference a single metadata name <index> corresponding to a metadata node with one i32 entry of value 1. The existence of the !nontemporal metadata on the instruction tells the optimizer and code generator that this load is not expected to be reused in the cache. The code generator may select special instructions to save cache bandwidth, such as the MOVNT instruction on x86.
The optional !invariant.group metadata must reference a single metadata name <index>. See invariant.group metadata.
The contents of memory are updated to contain <value> at the location specified by the <pointer> operand. If <value> is of scalar type then the number of bytes written does not exceed the minimum number of bytes needed to hold all bits of the type. For example, storing an i24 writes at most three bytes. When writing a value of a type like i20 with a size that is not an integral number of bytes, it is unspecified what happens to the extra bits that do not belong to the type, but they will typically be overwritten.
‘fence‘ instructions take an ordering argument which defines what synchronizes-with edges they add. They can only be given acquire, release, acq_rel, and seq_cst orderings.
A fence A which has (at least) release ordering semantics synchronizes with a fence B with (at least) acquire ordering semantics if and only if there exist atomic operations X and Y, both operating on some atomic object M, such that A is sequenced before X, X modifies M (either directly or through some side effect of a sequence headed by X), Y is sequenced before B, and Y observes M. This provides a happens-before dependency between A and B. Rather than an explicit fence, one (but not both) of the atomic operations X or Y might provide a release or acquire (resp.) ordering constraint and still synchronize-with the explicit fence and establish the happens-before edge.
A fence which has seq_cst ordering, in addition to having both acquire and release semantics specified above, participates in the global program order of other seq_cst operations and/or fences.
A fence instruction can also take an optional “syncscope” argument.
cmpxchg [weak] [volatile] <ty>* <pointer>, <ty> <cmp>, <ty> <new> [syncscope("<target-scope>")] <success ordering> <failure ordering> ; yields { ty, i1 }
The ‘cmpxchg‘ instruction is used to atomically modify memory. It loads a value in memory and compares it to a given value. If they are equal, it tries to store a new value into the memory.
There are three arguments to the ‘cmpxchg‘ instruction: an address to operate on, a value to compare to the value currently be at that address, and a new value to place at that address if the compared values are equal. The type of ‘<cmp>’ must be an integer or pointer type whose bit width is a power of two greater than or equal to eight and less than or equal to a target-specific size limit. ‘<cmp>’ and ‘<new>’ must have the same type, and the type of ‘<pointer>’ must be a pointer to that type. If the cmpxchg is marked as volatile, then the optimizer is not allowed to modify the number or order of execution of this cmpxchg with other volatile operations.
The success and failure ordering arguments specify how this cmpxchg synchronizes with other atomic operations. Both ordering parameters must be at least monotonic, the ordering constraint on failure must be no stronger than that on success, and the failure ordering cannot be either release or acq_rel.
A cmpxchg instruction can also take an optional “syncscope” argument.
The pointer passed into cmpxchg must have alignment greater than or equal to the size in memory of the operand.
The contents of memory at the location specified by the ‘<pointer>‘ operand is read and compared to ‘<cmp>‘; if the values are equal, ‘<new>‘ is written to the location. The original value at the location is returned, together with a flag indicating success (true) or failure (false).
If the cmpxchg operation is marked as weak then a spurious failure is permitted: the operation may not write <new> even if the comparison matched.
If the cmpxchg operation is strong (the default), the i1 value is 1 if and only if the value loaded equals cmp.
A successful cmpxchg is a read-modify-write instruction for the purpose of identifying release sequences. A failed cmpxchg is equivalent to an atomic load with an ordering parameter determined the second ordering parameter.
entry:
%orig = load atomic i32, i32* %ptr unordered, align 4 ; yields i32
br label %loop
loop:
%cmp = phi i32 [ %orig, %entry ], [%value_loaded, %loop]
%squared = mul i32 %cmp, %cmp
%val_success = cmpxchg i32* %ptr, i32 %cmp, i32 %squared acq_rel monotonic ; yields { i32, i1 }
%value_loaded = extractvalue { i32, i1 } %val_success, 0
%success = extractvalue { i32, i1 } %val_success, 1
br i1 %success, label %done, label %loop
done:
...
atomicrmw [volatile] <operation> <ty>* <pointer>, <ty> <value> [syncscope("<target-scope>")] <ordering> ; yields ty
There are three arguments to the ‘atomicrmw‘ instruction: an operation to apply, an address whose value to modify, an argument to the operation. The operation must be one of the following keywords:
The type of ‘<value>’ must be an integer type whose bit width is a power of two greater than or equal to eight and less than or equal to a target-specific size limit. The type of the ‘<pointer>‘ operand must be a pointer to that type. If the atomicrmw is marked as volatile, then the optimizer is not allowed to modify the number or order of execution of this atomicrmw with other volatile operations.
A atomicrmw instruction can also take an optional “syncscope” argument.
The contents of memory at the location specified by the ‘<pointer>‘ operand are atomically read, modified, and written back. The original value at the location is returned. The modification is specified by the operation argument:
<result> = getelementptr <ty>, <ty>* <ptrval>{, [inrange] <ty> <idx>}*
<result> = getelementptr inbounds <ty>, <ty>* <ptrval>{, [inrange] <ty> <idx>}*
<result> = getelementptr <ty>, <ptr vector> <ptrval>, [inrange] <vector index type> <idx>
The ‘getelementptr‘ instruction is used to get the address of a subelement of an aggregate data structure. It performs address calculation only and does not access memory. The instruction can also be used to calculate a vector of such addresses.
The first argument is always a type used as the basis for the calculations. The second argument is always a pointer or a vector of pointers, and is the base address to start from. The remaining arguments are indices that indicate which of the elements of the aggregate object are indexed. The interpretation of each index is dependent on the type being indexed into. The first index always indexes the pointer value given as the second argument, the second index indexes a value of the type pointed to (not necessarily the value directly pointed to, since the first index can be non-zero), etc. The first type indexed into must be a pointer value, subsequent types can be arrays, vectors, and structs. Note that subsequent types being indexed into can never be pointers, since that would require loading the pointer before continuing calculation.
The type of each index argument depends on the type it is indexing into. When indexing into a (optionally packed) structure, only i32 integer constants are allowed (when using a vector of indices they must all be the same i32 integer constant). When indexing into an array, pointer or vector, integers of any width are allowed, and they are not required to be constant. These integers are treated as signed values where relevant.
For example, let’s consider a C code fragment and how it gets compiled to LLVM:
struct RT {
char A;
int B[10][20];
char C;
};
struct ST {
int X;
double Y;
struct RT Z;
};
int *foo(struct ST *s) {
return &s[1].Z.B[5][13];
}
The LLVM code generated by Clang is:
%struct.RT = type { i8, [10 x [20 x i32]], i8 }
%struct.ST = type { i32, double, %struct.RT }
define i32* @foo(%struct.ST* %s) nounwind uwtable readnone optsize ssp {
entry:
%arrayidx = getelementptr inbounds %struct.ST, %struct.ST* %s, i64 1, i32 2, i32 1, i64 5, i64 13
ret i32* %arrayidx
}
In the example above, the first index is indexing into the ‘%struct.ST*‘ type, which is a pointer, yielding a ‘%struct.ST‘ = ‘{ i32, double, %struct.RT }‘ type, a structure. The second index indexes into the third element of the structure, yielding a ‘%struct.RT‘ = ‘{ i8 , [10 x [20 x i32]], i8 }‘ type, another structure. The third index indexes into the second element of the structure, yielding a ‘[10 x [20 x i32]]‘ type, an array. The two dimensions of the array are subscripted into, yielding an ‘i32‘ type. The ‘getelementptr‘ instruction returns a pointer to this element, thus computing a value of ‘i32*‘ type.
Note that it is perfectly legal to index partially through a structure, returning a pointer to an inner element. Because of this, the LLVM code for the given testcase is equivalent to:
define i32* @foo(%struct.ST* %s) {
%t1 = getelementptr %struct.ST, %struct.ST* %s, i32 1 ; yields %struct.ST*:%t1
%t2 = getelementptr %struct.ST, %struct.ST* %t1, i32 0, i32 2 ; yields %struct.RT*:%t2
%t3 = getelementptr %struct.RT, %struct.RT* %t2, i32 0, i32 1 ; yields [10 x [20 x i32]]*:%t3
%t4 = getelementptr [10 x [20 x i32]], [10 x [20 x i32]]* %t3, i32 0, i32 5 ; yields [20 x i32]*:%t4
%t5 = getelementptr [20 x i32], [20 x i32]* %t4, i32 0, i32 13 ; yields i32*:%t5
ret i32* %t5
}
If the inbounds keyword is present, the result value of the getelementptr is a poison value if the base pointer is not an in bounds address of an allocated object, or if any of the addresses that would be formed by successive addition of the offsets implied by the indices to the base address with infinitely precise signed arithmetic are not an in bounds address of that allocated object. The in bounds addresses for an allocated object are all the addresses that point into the object, plus the address one byte past the end. The only in bounds address for a null pointer in the default address-space is the null pointer itself. In cases where the base is a vector of pointers the inbounds keyword applies to each of the computations element-wise.
If the inbounds keyword is not present, the offsets are added to the base address with silently-wrapping two’s complement arithmetic. If the offsets have a different width from the pointer, they are sign-extended or truncated to the width of the pointer. The result value of the getelementptr may be outside the object pointed to by the base pointer. The result value may not necessarily be used to access memory though, even if it happens to point into allocated storage. See the Pointer Aliasing Rules section for more information.
If the inrange keyword is present before any index, loading from or storing to any pointer derived from the getelementptr has undefined behavior if the load or store would access memory outside of the bounds of the element selected by the index marked as inrange. The result of a pointer comparison or ptrtoint (including ptrtoint-like operations involving memory) involving a pointer derived from a getelementptr with the inrange keyword is undefined, with the exception of comparisons in the case where both operands are in the range of the element selected by the inrange keyword, inclusive of the address one past the end of that element. Note that the inrange keyword is currently only allowed in constant getelementptr expressions.
The getelementptr instruction is often confusing. For some more insight into how it works, see the getelementptr FAQ.
; yields [12 x i8]*:aptr
%aptr = getelementptr {i32, [12 x i8]}, {i32, [12 x i8]}* %saptr, i64 0, i32 1
; yields i8*:vptr
%vptr = getelementptr {i32, <2 x i8>}, {i32, <2 x i8>}* %svptr, i64 0, i32 1, i32 1
; yields i8*:eptr
%eptr = getelementptr [12 x i8], [12 x i8]* %aptr, i64 0, i32 1
; yields i32*:iptr
%iptr = getelementptr [10 x i32], [10 x i32]* @arr, i16 0, i16 0
The getelementptr returns a vector of pointers, instead of a single address, when one or more of its arguments is a vector. In such cases, all vector arguments should have the same number of elements, and every scalar argument will be effectively broadcast into a vector during address calculation.
; All arguments are vectors:
; A[i] = ptrs[i] + offsets[i]*sizeof(i8)
%A = getelementptr i8, <4 x i8*> %ptrs, <4 x i64> %offsets
; Add the same scalar offset to each pointer of a vector:
; A[i] = ptrs[i] + offset*sizeof(i8)
%A = getelementptr i8, <4 x i8*> %ptrs, i64 %offset
; Add distinct offsets to the same pointer:
; A[i] = ptr + offsets[i]*sizeof(i8)
%A = getelementptr i8, i8* %ptr, <4 x i64> %offsets
; In all cases described above the type of the result is <4 x i8*>
The two following instructions are equivalent:
getelementptr %struct.ST, <4 x %struct.ST*> %s, <4 x i64> %ind1,
<4 x i32> <i32 2, i32 2, i32 2, i32 2>,
<4 x i32> <i32 1, i32 1, i32 1, i32 1>,
<4 x i32> %ind4,
<4 x i64> <i64 13, i64 13, i64 13, i64 13>
getelementptr %struct.ST, <4 x %struct.ST*> %s, <4 x i64> %ind1,
i32 2, i32 1, <4 x i32> %ind4, i64 13
Let’s look at the C code, where the vector version of getelementptr makes sense:
// Let's assume that we vectorize the following loop:
double *A, *B; int *C;
for (int i = 0; i < size; ++i) {
A[i] = B[C[i]];
}
; get pointers for 8 elements from array B
%ptrs = getelementptr double, double* %B, <8 x i32> %C
; load 8 elements from array B into A
%A = call <8 x double> @llvm.masked.gather.v8f64.v8p0f64(<8 x double*> %ptrs,
i32 8, <8 x i1> %mask, <8 x double> %passthru)
The instructions in this category are the conversion instructions (casting) which all take a single operand and a type. They perform various bit conversions on the operand.
The ‘trunc‘ instruction takes a value to trunc, and a type to trunc it to. Both types must be of integer types, or vectors of the same number of integers. The bit size of the value must be larger than the bit size of the destination type, ty2. Equal sized types are not allowed.
The ‘trunc‘ instruction truncates the high order bits in value and converts the remaining bits to ty2. Since the source size must be larger than the destination size, trunc cannot be a no-op cast. It will always truncate bits.
The ‘zext‘ instruction takes a value to cast, and a type to cast it to. Both types must be of integer types, or vectors of the same number of integers. The bit size of the value must be smaller than the bit size of the destination type, ty2.
The zext fills the high order bits of the value with zero bits until it reaches the size of the destination type, ty2.
When zero extending from i1, the result will always be either 0 or 1.
The ‘sext‘ instruction takes a value to cast, and a type to cast it to. Both types must be of integer types, or vectors of the same number of integers. The bit size of the value must be smaller than the bit size of the destination type, ty2.
The ‘sext‘ instruction performs a sign extension by copying the sign bit (highest order bit) of the value until it reaches the bit size of the type ty2.
When sign extending from i1, the extension always results in -1 or 0.
The ‘fptrunc‘ instruction takes a floating-point value to cast and a floating-point type to cast it to. The size of value must be larger than the size of ty2. This implies that fptrunc cannot be used to make a no-op cast.
The ‘fptrunc‘ instruction casts a value from a larger floating-point type to a smaller floating-point type. This instruction is assumed to execute in the default floating-point environment.
The ‘fpext‘ instruction takes a floating-point value to cast, and a floating-point type to cast it to. The source type must be smaller than the destination type.
The ‘fpext‘ instruction extends the value from a smaller floating-point type to a larger floating-point type. The fpext cannot be used to make a no-op cast because it always changes bits. Use bitcast to make a no-op cast for a floating-point cast.
The ‘fptoui‘ converts a floating-point value to its unsigned integer equivalent of type ty2.
The ‘fptoui‘ instruction takes a value to cast, which must be a scalar or vector floating-point value, and a type to cast it to ty2, which must be an integer type. If ty is a vector floating-point type, ty2 must be a vector integer type with the same number of elements as ty
The ‘fptoui‘ instruction converts its floating-point operand into the nearest (rounding towards zero) unsigned integer value. If the value cannot fit in ty2, the result is a poison value.
The ‘fptosi‘ instruction converts floating-point value to type ty2.
The ‘fptosi‘ instruction takes a value to cast, which must be a scalar or vector floating-point value, and a type to cast it to ty2, which must be an integer type. If ty is a vector floating-point type, ty2 must be a vector integer type with the same number of elements as ty
The ‘fptosi‘ instruction converts its floating-point operand into the nearest (rounding towards zero) signed integer value. If the value cannot fit in ty2, the result is a poison value.
The ‘uitofp‘ instruction regards value as an unsigned integer and converts that value to the ty2 type.
The ‘uitofp‘ instruction takes a value to cast, which must be a scalar or vector integer value, and a type to cast it to ty2, which must be an floating-point type. If ty is a vector integer type, ty2 must be a vector floating-point type with the same number of elements as ty
The ‘uitofp‘ instruction interprets its operand as an unsigned integer quantity and converts it to the corresponding floating-point value. If the value cannot be exactly represented, it is rounded using the default rounding mode.
The ‘sitofp‘ instruction regards value as a signed integer and converts that value to the ty2 type.
The ‘sitofp‘ instruction takes a value to cast, which must be a scalar or vector integer value, and a type to cast it to ty2, which must be an floating-point type. If ty is a vector integer type, ty2 must be a vector floating-point type with the same number of elements as ty
The ‘sitofp‘ instruction interprets its operand as a signed integer quantity and converts it to the corresponding floating-point value. If the value cannot be exactly represented, it is rounded using the default rounding mode.
The ‘ptrtoint‘ instruction converts the pointer or a vector of pointers value to the integer (or vector of integers) type ty2.
The ‘ptrtoint‘ instruction takes a value to cast, which must be a value of type pointer or a vector of pointers, and a type to cast it to ty2, which must be an integer or a vector of integers type.
The ‘ptrtoint‘ instruction converts value to integer type ty2 by interpreting the pointer value as an integer and either truncating or zero extending that value to the size of the integer type. If value is smaller than ty2 then a zero extension is done. If value is larger than ty2 then a truncation is done. If they are the same size, then nothing is done (no-op cast) other than a type change.
The ‘inttoptr‘ instruction takes an integer value to cast, and a type to cast it to, which must be a pointer type.
The ‘inttoptr‘ instruction converts value to type ty2 by applying either a zero extension or a truncation depending on the size of the integer value. If value is larger than the size of a pointer then a truncation is done. If value is smaller than the size of a pointer then a zero extension is done. If they are the same size, nothing is done (no-op cast).
%X = inttoptr i32 255 to i32* ; yields zero extension on 64-bit architecture
%Y = inttoptr i32 255 to i32* ; yields no-op on 32-bit architecture
%Z = inttoptr i64 0 to i32* ; yields truncation on 32-bit architecture
%Z = inttoptr <4 x i32> %G to <4 x i8*>; yields truncation of vector G to four pointers
The ‘bitcast‘ instruction takes a value to cast, which must be a non-aggregate first class value, and a type to cast it to, which must also be a non-aggregate first class type. The bit sizes of value and the destination type, ty2, must be identical. If the source type is a pointer, the destination type must also be a pointer of the same size. This instruction supports bitwise conversion of vectors to integers and to vectors of other types (as long as they have the same size).
The ‘bitcast‘ instruction converts value to type ty2. It is always a no-op cast because no bits change with this conversion. The conversion is done as if the value had been stored to memory and read back as type ty2. Pointer (or vector of pointers) types may only be converted to other pointer (or vector of pointers) types with the same address space through this instruction. To convert pointers to other types, use the inttoptr or ptrtoint instructions first.
The ‘addrspacecast‘ instruction converts ptrval from pty in address space n to type pty2 in address space m.
The ‘addrspacecast‘ instruction takes a pointer or vector of pointer value to cast and a pointer type to cast it to, which must have a different address space.
The ‘addrspacecast‘ instruction converts the pointer value ptrval to type pty2. It can be a no-op cast or a complex value modification, depending on the target and the address space pair. Pointer conversions within the same address space must be performed with the bitcast instruction. Note that if the address space conversion is legal then both result and operand refer to the same memory location.
The instructions in this category are the “miscellaneous” instructions, which defy better classification.
The ‘icmp‘ instruction returns a boolean value or a vector of boolean values based on comparison of its two integer, integer vector, pointer, or pointer vector operands.
The ‘icmp‘ instruction takes three operands. The first operand is the condition code indicating the kind of comparison to perform. It is not a value, just a keyword. The possible condition codes are:
The remaining two arguments must be integer or pointer or integer vector typed. They must also be identical types.
The ‘icmp‘ compares op1 and op2 according to the condition code given as cond. The comparison performed always yields either an i1 or vector of i1 result, as follows:
If the operands are pointer typed, the pointer values are compared as if they were integers.
If the operands are integer vectors, then they are compared element by element. The result is an i1 vector with the same number of elements as the values being compared. Otherwise, the result is an i1.
<result> = icmp eq i32 4, 5 ; yields: result=false
<result> = icmp ne float* %X, %X ; yields: result=false
<result> = icmp ult i16 4, 5 ; yields: result=true
<result> = icmp sgt i16 4, 5 ; yields: result=false
<result> = icmp ule i16 -4, 5 ; yields: result=false
<result> = icmp sge i16 4, 5 ; yields: result=false
The ‘fcmp‘ instruction returns a boolean value or vector of boolean values based on comparison of its operands.
If the operands are floating-point scalars, then the result type is a boolean (i1).
If the operands are floating-point vectors, then the result type is a vector of boolean with the same number of elements as the operands being compared.
The ‘fcmp‘ instruction takes three operands. The first operand is the condition code indicating the kind of comparison to perform. It is not a value, just a keyword. The possible condition codes are:
Ordered means that neither operand is a QNAN while unordered means that either operand may be a QNAN.
Each of val1 and val2 arguments must be either a floating-point type or a vector of floating-point type. They must have identical types.
The ‘fcmp‘ instruction compares op1 and op2 according to the condition code given as cond. If the operands are vectors, then the vectors are compared element by element. Each comparison performed always yields an i1 result, as follows:
The fcmp instruction can also optionally take any number of fast-math flags, which are optimization hints to enable otherwise unsafe floating-point optimizations.
Any set of fast-math flags are legal on an fcmp instruction, but the only flags that have any effect on its semantics are those that allow assumptions to be made about the values of input arguments; namely nnan, ninf, and reassoc. See Fast-Math Flags for more information.
The ‘phi‘ instruction is used to implement the φ node in the SSA graph representing the function.
The type of the incoming values is specified with the first type field. After this, the ‘phi‘ instruction takes a list of pairs as arguments, with one pair for each predecessor basic block of the current block. Only values of first class type may be used as the value arguments to the PHI node. Only labels may be used as the label arguments.
There must be no non-phi instructions between the start of a basic block and the PHI instructions: i.e. PHI instructions must be first in a basic block.
For the purposes of the SSA form, the use of each incoming value is deemed to occur on the edge from the corresponding predecessor block to the current block (but after any definition of an ‘invoke‘ instruction’s return value on the same edge).
At runtime, the ‘phi‘ instruction logically takes on the value specified by the pair corresponding to the predecessor basic block that executed just prior to the current block.
<result> = select selty <cond>, <ty> <val1>, <ty> <val2> ; yields ty
selty is either i1 or {<N x i1>}
The ‘select‘ instruction is used to choose one value based on a condition, without IR-level branching.
The ‘select‘ instruction requires an ‘i1’ value or a vector of ‘i1’ values indicating the condition, and two values of the same first class type.
If the condition is an i1 and it evaluates to 1, the instruction returns the first value argument; otherwise, it returns the second value argument.
If the condition is a vector of i1, then the value arguments must be vectors of the same size, and the selection is done element by element.
If the condition is an i1 and the value arguments are vectors of the same size, then an entire vector is selected.
<result> = [tail | musttail | notail ] call [fast-math flags] [cconv] [ret attrs] <ty>|<fnty> <fnptrval>(<function args>) [fn attrs]
[ operand bundles ]
This instruction requires several arguments:
The optional tail and musttail markers indicate that the optimizers should perform tail call optimization. The tail marker is a hint that can be ignored. The musttail marker means that the call must be tail call optimized in order for the program to be correct. The musttail marker provides these guarantees:
Both markers imply that the callee does not access allocas from the caller. The tail marker additionally implies that the callee does not access varargs from the caller, while musttail implies that varargs from the caller are passed to the callee. Calls marked musttail must obey the following additional rules:
Tail call optimization for calls marked tail is guaranteed to occur if the following conditions are met:
The optional notail marker indicates that the optimizers should not add tail or musttail markers to the call. It is used to prevent tail call optimization from being performed on the call.
The optional fast-math flags marker indicates that the call has one or more fast-math flags, which are optimization hints to enable otherwise unsafe floating-point optimizations. Fast-math flags are only valid for calls that return a floating-point scalar or vector type.
The optional “cconv” marker indicates which calling convention the call should use. If none is specified, the call defaults to using C calling conventions. The calling convention of the call must match the calling convention of the target function, or else the behavior is undefined.
The optional Parameter Attributes list for return values. Only ‘zeroext‘, ‘signext‘, and ‘inreg‘ attributes are valid here.
‘ty‘: the type of the call instruction itself which is also the type of the return value. Functions that return no value are marked void.
‘fnty‘: shall be the signature of the function being called. The argument types must match the types implied by this signature. This type can be omitted if the function is not varargs.
‘fnptrval‘: An LLVM value containing a pointer to a function to be called. In most cases, this is a direct function call, but indirect call‘s are just as possible, calling an arbitrary pointer to function value.
‘function args‘: argument list whose types match the function signature argument types and parameter attributes. All arguments must be of first class type. If the function signature indicates the function accepts a variable number of arguments, the extra arguments can be specified.
The optional function attributes list.
The optional operand bundles list.
The ‘call‘ instruction is used to cause control flow to transfer to a specified function, with its incoming arguments bound to the specified values. Upon a ‘ret‘ instruction in the called function, control flow continues with the instruction after the function call, and the return value of the function is bound to the result argument.
%retval = call i32 @test(i32 %argc)
call i32 (i8*, ...)* @printf(i8* %msg, i32 12, i8 42) ; yields i32
%X = tail call i32 @foo() ; yields i32
%Y = tail call fastcc i32 @foo() ; yields i32
call void %foo(i8 97 signext)
%struct.A = type { i32, i8 }
%r = call %struct.A @foo() ; yields { i32, i8 }
%gr = extractvalue %struct.A %r, 0 ; yields i32
%gr1 = extractvalue %struct.A %r, 1 ; yields i8
%Z = call void @foo() noreturn ; indicates that %foo never returns normally
%ZZ = call zeroext i32 @bar() ; Return value is %zero extended
llvm treats calls to some functions with names and arguments that match the standard C99 library as being the C99 library functions, and may perform optimizations or generate code for them under that assumption. This is something we’d like to change in the future to provide better support for freestanding environments and non-C-based languages.
The ‘va_arg‘ instruction is used to access arguments passed through the “variable argument” area of a function call. It is used to implement the va_arg macro in C.
This instruction takes a va_list* value and the type of the argument. It returns a value of the specified argument type and increments the va_list to point to the next argument. The actual type of va_list is target specific.
The ‘va_arg‘ instruction loads an argument of the specified type from the specified va_list and causes the va_list to point to the next argument. For more information, see the variable argument handling Intrinsic Functions.
It is legal for this instruction to be called in a function which does not take a variable number of arguments, for example, the vfprintf function.
va_arg is an LLVM instruction instead of an intrinsic function because it takes a type as an argument.
See the variable argument processing section.
Note that the code generator does not yet fully support va_arg on many targets. Also, it does not currently support va_arg with aggregate types on any target.
<resultval> = landingpad <resultty> <clause>+
<resultval> = landingpad <resultty> cleanup <clause>*
<clause> := catch <type> <value>
<clause> := filter <array constant type> <array constant>
The ‘landingpad‘ instruction is used by LLVM’s exception handling system to specify that a basic block is a landing pad — one where the exception lands, and corresponds to the code found in the catch portion of a try/catch sequence. It defines values supplied by the personality function upon re-entry to the function. The resultval has the type resultty.
The optional cleanup flag indicates that the landing pad block is a cleanup.
A clause begins with the clause type — catch or filter — and contains the global variable representing the “type” that may be caught or filtered respectively. Unlike the catch clause, the filter clause takes an array constant as its argument. Use “[0 x i8**] undef” for a filter which cannot throw. The ‘landingpad‘ instruction must contain at least one clause or the cleanup flag.
The ‘landingpad‘ instruction defines the values which are set by the personality function upon re-entry to the function, and therefore the “result type” of the landingpad instruction. As with calling conventions, how the personality function results are represented in LLVM IR is target specific.
The clauses are applied in order from top to bottom. If two landingpad instructions are merged together through inlining, the clauses from the calling function are appended to the list of clauses. When the call stack is being unwound due to an exception being thrown, the exception is compared against each clause in turn. If it doesn’t match any of the clauses, and the cleanup flag is not set, then unwinding continues further up the call stack.
The landingpad instruction has several restrictions:
;; A landing pad which can catch an integer.
%res = landingpad { i8*, i32 }
catch i8** @_ZTIi
;; A landing pad that is a cleanup.
%res = landingpad { i8*, i32 }
cleanup
;; A landing pad which can catch an integer and can only throw a double.
%res = landingpad { i8*, i32 }
catch i8** @_ZTIi
filter [1 x i8**] [@_ZTId]
The ‘catchpad‘ instruction is used by LLVM’s exception handling system to specify that a basic block begins a catch handler — one where a personality routine attempts to transfer control to catch an exception.
The catchswitch operand must always be a token produced by a catchswitch instruction in a predecessor block. This ensures that each catchpad has exactly one predecessor block, and it always terminates in a catchswitch.
The args correspond to whatever information the personality routine requires to know if this is an appropriate handler for the exception. Control will transfer to the catchpad if this is the first appropriate handler for the exception.
The resultval has the type token and is used to match the catchpad to corresponding catchrets and other nested EH pads.
When the call stack is being unwound due to an exception being thrown, the exception is compared against the args. If it doesn’t match, control will not reach the catchpad instruction. The representation of args is entirely target and personality function-specific.
Like the landingpad instruction, the catchpad instruction must be the first non-phi of its parent basic block.
The meaning of the tokens produced and consumed by catchpad and other “pad” instructions is described in the Windows exception handling documentation.
When a catchpad has been “entered” but not yet “exited” (as described in the EH documentation), it is undefined behavior to execute a call or invoke that does not carry an appropriate “funclet” bundle.
The ‘cleanuppad‘ instruction is used by LLVM’s exception handling system to specify that a basic block is a cleanup block — one where a personality routine attempts to transfer control to run cleanup actions. The args correspond to whatever additional information the personality function requires to execute the cleanup. The resultval has the type token and is used to match the cleanuppad to corresponding cleanuprets. The parent argument is the token of the funclet that contains the cleanuppad instruction. If the cleanuppad is not inside a funclet, this operand may be the token none.
The instruction takes a list of arbitrary values which are interpreted by the personality function.
When the call stack is being unwound due to an exception being thrown, the personality function transfers control to the cleanuppad with the aid of the personality-specific arguments. As with calling conventions, how the personality function results are represented in LLVM IR is target specific.
The cleanuppad instruction has several restrictions:
When a cleanuppad has been “entered” but not yet “exited” (as described in the EH documentation), it is undefined behavior to execute a call or invoke that does not carry an appropriate “funclet” bundle.
LLVM supports the notion of an “intrinsic function”. These functions have well known names and semantics and are required to follow certain restrictions. Overall, these intrinsics represent an extension mechanism for the LLVM language that does not require changing all of the transformations in LLVM when adding to the language (or the bitcode reader/writer, the parser, etc...).
Intrinsic function names must all start with an “llvm.” prefix. This prefix is reserved in LLVM for intrinsic names; thus, function names may not begin with this prefix. Intrinsic functions must always be external functions: you cannot define the body of intrinsic functions. Intrinsic functions may only be used in call or invoke instructions: it is illegal to take the address of an intrinsic function. Additionally, because intrinsic functions are part of the LLVM language, it is required if any are added that they be documented here.
Some intrinsic functions can be overloaded, i.e., the intrinsic represents a family of functions that perform the same operation but on different data types. Because LLVM can represent over 8 million different integer types, overloading is used commonly to allow an intrinsic function to operate on any integer type. One or more of the argument types or the result type can be overloaded to accept any integer type. Argument types may also be defined as exactly matching a previous argument’s type or the result type. This allows an intrinsic function which accepts multiple arguments, but needs all of them to be of the same type, to only be overloaded with respect to a single argument or the result.
Overloaded intrinsics will have the names of its overloaded argument types encoded into its function name, each preceded by a period. Only those types which are overloaded result in a name suffix. Arguments whose type is matched against another type do not. For example, the llvm.ctpop function can take an integer of any width and returns an integer of exactly the same integer width. This leads to a family of functions such as i8 @llvm.ctpop.i8(i8 %val) and i29 @llvm.ctpop.i29(i29 %val). Only one type, the return type, is overloaded, and only one type suffix is required. Because the argument’s type is matched against the return type, it does not require its own name suffix.
To learn how to add an intrinsic function, please see the Extending LLVM Guide.
Variable argument support is defined in LLVM with the va_arg instruction and these three intrinsic functions. These functions are related to the similarly named macros defined in the <stdarg.h> header file.
All of these functions operate on arguments that use a target-specific value type “va_list”. The LLVM assembly language reference manual does not define what this type is, so all transformations should be prepared to handle these functions regardless of the type used.
This example shows how the va_arg instruction and the variable argument handling intrinsic functions are used.
; This struct is different for every platform. For most platforms,
; it is merely an i8*.
%struct.va_list = type { i8* }
; For Unix x86_64 platforms, va_list is the following struct:
; %struct.va_list = type { i32, i32, i8*, i8* }
define i32 @test(i32 %X, ...) {
; Initialize variable argument processing
%ap = alloca %struct.va_list
%ap2 = bitcast %struct.va_list* %ap to i8*
call void @llvm.va_start(i8* %ap2)
; Read a single integer argument
%tmp = va_arg i8* %ap2, i32
; Demonstrate usage of llvm.va_copy and llvm.va_end
%aq = alloca i8*
%aq2 = bitcast i8** %aq to i8*
call void @llvm.va_copy(i8* %aq2, i8* %ap2)
call void @llvm.va_end(i8* %aq2)
; Stop processing of arguments.
call void @llvm.va_end(i8* %ap2)
ret i32 %tmp
}
declare void @llvm.va_start(i8*)
declare void @llvm.va_copy(i8*, i8*)
declare void @llvm.va_end(i8*)
The argument is a pointer to a va_list element to initialize.
The ‘llvm.va_start‘ intrinsic works just like the va_start macro available in C. In a target-dependent way, it initializes the va_list element to which the argument points, so that the next call to va_arg will produce the first variable argument passed to the function. Unlike the C va_start macro, this intrinsic does not need to know the last argument of the function as the compiler can figure that out.
The ‘llvm.va_end‘ intrinsic destroys *<arglist>, which has been initialized previously with llvm.va_start or llvm.va_copy.
The argument is a pointer to a va_list to destroy.
The ‘llvm.va_end‘ intrinsic works just like the va_end macro available in C. In a target-dependent way, it destroys the va_list element to which the argument points. Calls to llvm.va_start and llvm.va_copy must be matched exactly with calls to llvm.va_end.
The ‘llvm.va_copy‘ intrinsic copies the current argument position from the source argument list to the destination argument list.
The first argument is a pointer to a va_list element to initialize. The second argument is a pointer to a va_list element to copy from.
The ‘llvm.va_copy‘ intrinsic works just like the va_copy macro available in C. In a target-dependent way, it copies the source va_list element into the destination va_list element. This intrinsic is necessary because the `` llvm.va_start`` intrinsic may be arbitrarily complex and require, for example, memory allocation.
LLVM’s support for Accurate Garbage Collection (GC) requires the frontend to generate code containing appropriate intrinsic calls and select an appropriate GC strategy which knows how to lower these intrinsics in a manner which is appropriate for the target collector.
These intrinsics allow identification of GC roots on the stack, as well as garbage collector implementations that require read and write barriers. Frontends for type-safe garbage collected languages should generate these intrinsics to make use of the LLVM garbage collectors. For more details, see Garbage Collection with LLVM.
LLVM provides an second experimental set of intrinsics for describing garbage collection safepoints in compiled code. These intrinsics are an alternative to the llvm.gcroot intrinsics, but are compatible with the ones for read and write barriers. The differences in approach are covered in the Garbage Collection with LLVM documentation. The intrinsics themselves are described in Garbage Collection Safepoints in LLVM.
The ‘llvm.gcroot‘ intrinsic declares the existence of a GC root to the code generator, and allows some metadata to be associated with it.
The first argument specifies the address of a stack object that contains the root pointer. The second pointer (which must be either a constant or a global value address) contains the meta-data to be associated with the root.
At runtime, a call to this intrinsic stores a null pointer into the “ptrloc” location. At compile-time, the code generator generates information to allow the runtime to find the pointer at GC safe points. The ‘llvm.gcroot‘ intrinsic may only be used in a function which specifies a GC algorithm.
The ‘llvm.gcread‘ intrinsic identifies reads of references from heap locations, allowing garbage collector implementations that require read barriers.
The second argument is the address to read from, which should be an address allocated from the garbage collector. The first object is a pointer to the start of the referenced object, if needed by the language runtime (otherwise null).
The ‘llvm.gcread‘ intrinsic has the same semantics as a load instruction, but may be replaced with substantially more complex code by the garbage collector runtime, as needed. The ‘llvm.gcread‘ intrinsic may only be used in a function which specifies a GC algorithm.
The ‘llvm.gcwrite‘ intrinsic identifies writes of references to heap locations, allowing garbage collector implementations that require write barriers (such as generational or reference counting collectors).
The first argument is the reference to store, the second is the start of the object to store it to, and the third is the address of the field of Obj to store to. If the runtime does not require a pointer to the object, Obj may be null.
The ‘llvm.gcwrite‘ intrinsic has the same semantics as a store instruction, but may be replaced with substantially more complex code by the garbage collector runtime, as needed. The ‘llvm.gcwrite‘ intrinsic may only be used in a function which specifies a GC algorithm.
These intrinsics are provided by LLVM to expose special features that may only be implemented with code generator support.
The ‘llvm.returnaddress‘ intrinsic attempts to compute a target-specific value indicating the return address of the current function or one of its callers.
The argument to this intrinsic indicates which function to return the address for. Zero indicates the calling function, one indicates its caller, etc. The argument is required to be a constant integer value.
The ‘llvm.returnaddress‘ intrinsic either returns a pointer indicating the return address of the specified call frame, or zero if it cannot be identified. The value returned by this intrinsic is likely to be incorrect or 0 for arguments other than zero, so it should only be used for debugging purposes.
Note that calling this intrinsic does not prevent function inlining or other aggressive transformations, so the value returned may not be that of the obvious source-language caller.
The ‘llvm.addressofreturnaddress‘ intrinsic returns a target-specific pointer to the place in the stack frame where the return address of the current function is stored.
Note that calling this intrinsic does not prevent function inlining or other aggressive transformations, so the value returned may not be that of the obvious source-language caller.
This intrinsic is only implemented for x86.
The ‘llvm.frameaddress‘ intrinsic attempts to return the target-specific frame pointer value for the specified stack frame.
The argument to this intrinsic indicates which function to return the frame pointer for. Zero indicates the calling function, one indicates its caller, etc. The argument is required to be a constant integer value.
The ‘llvm.frameaddress‘ intrinsic either returns a pointer indicating the frame address of the specified call frame, or zero if it cannot be identified. The value returned by this intrinsic is likely to be incorrect or 0 for arguments other than zero, so it should only be used for debugging purposes.
Note that calling this intrinsic does not prevent function inlining or other aggressive transformations, so the value returned may not be that of the obvious source-language caller.
declare void @llvm.localescape(...)
declare i8* @llvm.localrecover(i8* %func, i8* %fp, i32 %idx)
The ‘llvm.localescape‘ intrinsic escapes offsets of a collection of static allocas, and the ‘llvm.localrecover‘ intrinsic applies those offsets to a live frame pointer to recover the address of the allocation. The offset is computed during frame layout of the caller of llvm.localescape.
All arguments to ‘llvm.localescape‘ must be pointers to static allocas or casts of static allocas. Each function can only call ‘llvm.localescape‘ once, and it can only do so from the entry block.
The func argument to ‘llvm.localrecover‘ must be a constant bitcasted pointer to a function defined in the current module. The code generator cannot determine the frame allocation offset of functions defined in other modules.
The fp argument to ‘llvm.localrecover‘ must be a frame pointer of a call frame that is currently live. The return value of ‘llvm.localaddress‘ is one way to produce such a value, but various runtimes also expose a suitable pointer in platform-specific ways.
The idx argument to ‘llvm.localrecover‘ indicates which alloca passed to ‘llvm.localescape‘ to recover. It is zero-indexed.
These intrinsics allow a group of functions to share access to a set of local stack allocations of a one parent function. The parent function may call the ‘llvm.localescape‘ intrinsic once from the function entry block, and the child functions can use ‘llvm.localrecover‘ to access the escaped allocas. The ‘llvm.localescape‘ intrinsic blocks inlining, as inlining changes where the escaped allocas are allocated, which would break attempts to use ‘llvm.localrecover‘.
declare i32 @llvm.read_register.i32(metadata)
declare i64 @llvm.read_register.i64(metadata)
declare void @llvm.write_register.i32(metadata, i32 @value)
declare void @llvm.write_register.i64(metadata, i64 @value)
!0 = !{!"sp\00"}
The ‘llvm.read_register‘ and ‘llvm.write_register‘ intrinsics provides access to the named register. The register must be valid on the architecture being compiled to. The type needs to be compatible with the register being read.
The ‘llvm.read_register‘ intrinsic returns the current value of the register, where possible. The ‘llvm.write_register‘ intrinsic sets the current value of the register, where possible.
This is useful to implement named register global variables that need to always be mapped to a specific register, as is common practice on bare-metal programs including OS kernels.
The compiler doesn’t check for register availability or use of the used register in surrounding code, including inline assembly. Because of that, allocatable registers are not supported.
Warning: So far it only works with the stack pointer on selected architectures (ARM, AArch64, PowerPC and x86_64). Significant amount of work is needed to support other registers and even more so, allocatable registers.
The ‘llvm.stacksave‘ intrinsic is used to remember the current state of the function stack, for use with llvm.stackrestore. This is useful for implementing language features like scoped automatic variable sized arrays in C99.
This intrinsic returns a opaque pointer value that can be passed to llvm.stackrestore. When an llvm.stackrestore intrinsic is executed with a value saved from llvm.stacksave, it effectively restores the state of the stack to the state it was in when the llvm.stacksave intrinsic executed. In practice, this pops any alloca blocks from the stack that were allocated after the llvm.stacksave was executed.
The ‘llvm.stackrestore‘ intrinsic is used to restore the state of the function stack to the state it was in when the corresponding llvm.stacksave intrinsic executed. This is useful for implementing language features like scoped automatic variable sized arrays in C99.
See the description for llvm.stacksave.
declare i32 @llvm.get.dynamic.area.offset.i32()
declare i64 @llvm.get.dynamic.area.offset.i64()
The ‘llvm.get.dynamic.area.offset.*‘ intrinsic family is used to get the offset from native stack pointer to the address of the most recent dynamic alloca on the caller’s stack. These intrinsics are intendend for use in combination with llvm.stacksave to get a pointer to the most recent dynamic alloca. This is useful, for example, for AddressSanitizer’s stack unpoisoning routines.
These intrinsics return a non-negative integer value that can be used to get the address of the most recent dynamic alloca, allocated by alloca on the caller’s stack. In particular, for targets where stack grows downwards, adding this offset to the native stack pointer would get the address of the most recent dynamic alloca. For targets where stack grows upwards, the situation is a bit more complicated, because subtracting this value from stack pointer would get the address one past the end of the most recent dynamic alloca.
Although for most targets llvm.get.dynamic.area.offset <int_get_dynamic_area_offset> returns just a zero, for others, such as PowerPC and PowerPC64, it returns a compile-time-known constant value.
The return value type of llvm.get.dynamic.area.offset must match the target’s default address space’s (address space 0) pointer type.
The ‘llvm.prefetch‘ intrinsic is a hint to the code generator to insert a prefetch instruction if supported; otherwise, it is a noop. Prefetches have no effect on the behavior of the program but can change its performance characteristics.
address is the address to be prefetched, rw is the specifier determining if the fetch should be for a read (0) or write (1), and locality is a temporal locality specifier ranging from (0) - no locality, to (3) - extremely local keep in cache. The cache type specifies whether the prefetch is performed on the data (1) or instruction (0) cache. The rw, locality and cache type arguments must be constant integers.
This intrinsic does not modify the behavior of the program. In particular, prefetches cannot trap and do not produce a value. On targets that support this intrinsic, the prefetch can provide hints to the processor cache for better performance.
The ‘llvm.pcmarker‘ intrinsic is a method to export a Program Counter (PC) in a region of code to simulators and other tools. The method is target specific, but it is expected that the marker will use exported symbols to transmit the PC of the marker. The marker makes no guarantees that it will remain with any specific instruction after optimizations. It is possible that the presence of a marker will inhibit optimizations. The intended use is to be inserted after optimizations to allow correlations of simulation runs.
id is a numerical id identifying the marker.
This intrinsic does not modify the behavior of the program. Backends that do not support this intrinsic may ignore it.
The ‘llvm.readcyclecounter‘ intrinsic provides access to the cycle counter register (or similar low latency, high accuracy clocks) on those targets that support it. On X86, it should map to RDTSC. On Alpha, it should map to RPCC. As the backing counters overflow quickly (on the order of 9 seconds on alpha), this should only be used for small timings.
When directly supported, reading the cycle counter should not modify any memory. Implementations are allowed to either return a application specific value or a system wide value. On backends without support, this is lowered to a constant 0.
Note that runtime support may be conditional on the privilege-level code is running at and the host platform.
The ‘llvm.clear_cache‘ intrinsic ensures visibility of modifications in the specified range to the execution unit of the processor. On targets with non-unified instruction and data cache, the implementation flushes the instruction cache.
On platforms with coherent instruction and data caches (e.g. x86), this intrinsic is a nop. On platforms with non-coherent instruction and data cache (e.g. ARM, MIPS), the intrinsic is lowered either to appropriate instructions or a system call, if cache flushing requires special privileges.
The default behavior is to emit a call to __clear_cache from the run time library.
This instrinsic does not empty the instruction pipeline. Modifications of the current function are outside the scope of the intrinsic.
declare void @llvm.instrprof.increment(i8* <name>, i64 <hash>,
i32 <num-counters>, i32 <index>)
The ‘llvm.instrprof.increment‘ intrinsic can be emitted by a frontend for use with instrumentation based profiling. These will be lowered by the -instrprof pass to generate execution counts of a program at runtime.
The first argument is a pointer to a global variable containing the name of the entity being instrumented. This should generally be the (mangled) function name for a set of counters.
The second argument is a hash value that can be used by the consumer of the profile data to detect changes to the instrumented source, and the third is the number of counters associated with name. It is an error if hash or num-counters differ between two instances of instrprof.increment that refer to the same name.
The last argument refers to which of the counters for name should be incremented. It should be a value between 0 and num-counters.
This intrinsic represents an increment of a profiling counter. It will cause the -instrprof pass to generate the appropriate data structures and the code to increment the appropriate value, in a format that can be written out by a compiler runtime and consumed via the llvm-profdata tool.
declare void @llvm.instrprof.increment.step(i8* <name>, i64 <hash>,
i32 <num-counters>,
i32 <index>, i64 <step>)
The ‘llvm.instrprof.increment.step‘ intrinsic is an extension to the ‘llvm.instrprof.increment‘ intrinsic with an additional fifth argument to specify the step of the increment.
The first four arguments are the same as ‘llvm.instrprof.increment‘ intrinsic.
The last argument specifies the value of the increment of the counter variable.
See description of ‘llvm.instrprof.increment‘ instrinsic.
declare void @llvm.instrprof.value.profile(i8* <name>, i64 <hash>,
i64 <value>, i32 <value_kind>,
i32 <index>)
The ‘llvm.instrprof.value.profile‘ intrinsic can be emitted by a frontend for use with instrumentation based profiling. This will be lowered by the -instrprof pass to find out the target values, instrumented expressions take in a program at runtime.
The first argument is a pointer to a global variable containing the name of the entity being instrumented. name should generally be the (mangled) function name for a set of counters.
The second argument is a hash value that can be used by the consumer of the profile data to detect changes to the instrumented source. It is an error if hash differs between two instances of llvm.instrprof.* that refer to the same name.
The third argument is the value of the expression being profiled. The profiled expression’s value should be representable as an unsigned 64-bit value. The fourth argument represents the kind of value profiling that is being done. The supported value profiling kinds are enumerated through the InstrProfValueKind type declared in the <include/llvm/ProfileData/InstrProf.h> header file. The last argument is the index of the instrumented expression within name. It should be >= 0.
This intrinsic represents the point where a call to a runtime routine should be inserted for value profiling of target expressions. -instrprof pass will generate the appropriate data structures and replace the llvm.instrprof.value.profile intrinsic with the call to the profile runtime library with proper arguments.
The ‘llvm.thread.pointer‘ intrinsic returns a pointer to the TLS area for the current thread. The exact semantics of this value are target specific: it may point to the start of TLS area, to the end, or somewhere in the middle. Depending on the target, this intrinsic may read a register, call a helper function, read from an alternate memory space, or perform other operations necessary to locate the TLS area. Not all targets support this intrinsic.
LLVM provides intrinsics for a few important standard C library functions. These intrinsics allow source-language front-ends to pass information about the alignment of the pointer arguments to the code generator, providing opportunity for more efficient code generation.
This is an overloaded intrinsic. You can use llvm.memcpy on any integer bit width and for different address spaces. Not all targets support all bit widths however.
declare void @llvm.memcpy.p0i8.p0i8.i32(i8* <dest>, i8* <src>,
i32 <len>, i1 <isvolatile>)
declare void @llvm.memcpy.p0i8.p0i8.i64(i8* <dest>, i8* <src>,
i64 <len>, i1 <isvolatile>)
The ‘llvm.memcpy.*‘ intrinsics copy a block of memory from the source location to the destination location.
Note that, unlike the standard libc function, the llvm.memcpy.* intrinsics do not return a value, takes extra isvolatile arguments and the pointers can be in specified address spaces.
The first argument is a pointer to the destination, the second is a pointer to the source. The third argument is an integer argument specifying the number of bytes to copy, and the fourth is a boolean indicating a volatile access.
The align parameter attribute can be provided for the first and second arguments.
If the isvolatile parameter is true, the llvm.memcpy call is a volatile operation. The detailed access behavior is not very cleanly specified and it is unwise to depend on it.
The ‘llvm.memcpy.*‘ intrinsics copy a block of memory from the source location to the destination location, which are not allowed to overlap. It copies “len” bytes of memory over. If the argument is known to be aligned to some boundary, this can be specified as the fourth argument, otherwise it should be set to 0 or 1 (both meaning no alignment).
This is an overloaded intrinsic. You can use llvm.memmove on any integer bit width and for different address space. Not all targets support all bit widths however.
declare void @llvm.memmove.p0i8.p0i8.i32(i8* <dest>, i8* <src>,
i32 <len>, i1 <isvolatile>)
declare void @llvm.memmove.p0i8.p0i8.i64(i8* <dest>, i8* <src>,
i64 <len>, i1 <isvolatile>)
The ‘llvm.memmove.*‘ intrinsics move a block of memory from the source location to the destination location. It is similar to the ‘llvm.memcpy‘ intrinsic but allows the two memory locations to overlap.
Note that, unlike the standard libc function, the llvm.memmove.* intrinsics do not return a value, takes an extra isvolatile argument and the pointers can be in specified address spaces.
The first argument is a pointer to the destination, the second is a pointer to the source. The third argument is an integer argument specifying the number of bytes to copy, and the fourth is a boolean indicating a volatile access.
The align parameter attribute can be provided for the first and second arguments.
If the isvolatile parameter is true, the llvm.memmove call is a volatile operation. The detailed access behavior is not very cleanly specified and it is unwise to depend on it.
The ‘llvm.memmove.*‘ intrinsics copy a block of memory from the source location to the destination location, which may overlap. It copies “len” bytes of memory over. If the argument is known to be aligned to some boundary, this can be specified as the fourth argument, otherwise it should be set to 0 or 1 (both meaning no alignment).
This is an overloaded intrinsic. You can use llvm.memset on any integer bit width and for different address spaces. However, not all targets support all bit widths.
declare void @llvm.memset.p0i8.i32(i8* <dest>, i8 <val>,
i32 <len>, i1 <isvolatile>)
declare void @llvm.memset.p0i8.i64(i8* <dest>, i8 <val>,
i64 <len>, i1 <isvolatile>)
The ‘llvm.memset.*‘ intrinsics fill a block of memory with a particular byte value.
Note that, unlike the standard libc function, the llvm.memset intrinsic does not return a value and takes an extra volatile argument. Also, the destination can be in an arbitrary address space.
The first argument is a pointer to the destination to fill, the second is the byte value with which to fill it, the third argument is an integer argument specifying the number of bytes to fill, and the fourth is a boolean indicating a volatile access.
The align parameter attribute can be provided for the first arguments.
If the isvolatile parameter is true, the llvm.memset call is a volatile operation. The detailed access behavior is not very cleanly specified and it is unwise to depend on it.
The ‘llvm.memset.*‘ intrinsics fill “len” bytes of memory starting at the destination location.
This is an overloaded intrinsic. You can use llvm.sqrt on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.sqrt.f32(float %Val)
declare double @llvm.sqrt.f64(double %Val)
declare x86_fp80 @llvm.sqrt.f80(x86_fp80 %Val)
declare fp128 @llvm.sqrt.f128(fp128 %Val)
declare ppc_fp128 @llvm.sqrt.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘sqrt‘ function but without trapping or setting errno. For types specified by IEEE-754, the result matches a conforming libm implementation.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.powi on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.powi.f32(float %Val, i32 %power)
declare double @llvm.powi.f64(double %Val, i32 %power)
declare x86_fp80 @llvm.powi.f80(x86_fp80 %Val, i32 %power)
declare fp128 @llvm.powi.f128(fp128 %Val, i32 %power)
declare ppc_fp128 @llvm.powi.ppcf128(ppc_fp128 %Val, i32 %power)
The ‘llvm.powi.*‘ intrinsics return the first operand raised to the specified (positive or negative) power. The order of evaluation of multiplications is not defined. When a vector of floating-point type is used, the second argument remains a scalar integer value.
The second argument is an integer power, and the first is a value to raise to that power.
This function returns the first value raised to the second power with an unspecified sequence of rounding operations.
This is an overloaded intrinsic. You can use llvm.sin on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.sin.f32(float %Val)
declare double @llvm.sin.f64(double %Val)
declare x86_fp80 @llvm.sin.f80(x86_fp80 %Val)
declare fp128 @llvm.sin.f128(fp128 %Val)
declare ppc_fp128 @llvm.sin.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘sin‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.cos on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.cos.f32(float %Val)
declare double @llvm.cos.f64(double %Val)
declare x86_fp80 @llvm.cos.f80(x86_fp80 %Val)
declare fp128 @llvm.cos.f128(fp128 %Val)
declare ppc_fp128 @llvm.cos.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘cos‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.pow on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.pow.f32(float %Val, float %Power)
declare double @llvm.pow.f64(double %Val, double %Power)
declare x86_fp80 @llvm.pow.f80(x86_fp80 %Val, x86_fp80 %Power)
declare fp128 @llvm.pow.f128(fp128 %Val, fp128 %Power)
declare ppc_fp128 @llvm.pow.ppcf128(ppc_fp128 %Val, ppc_fp128 Power)
The ‘llvm.pow.*‘ intrinsics return the first operand raised to the specified (positive or negative) power.
The arguments and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘pow‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.exp on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.exp.f32(float %Val)
declare double @llvm.exp.f64(double %Val)
declare x86_fp80 @llvm.exp.f80(x86_fp80 %Val)
declare fp128 @llvm.exp.f128(fp128 %Val)
declare ppc_fp128 @llvm.exp.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘exp‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.exp2 on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.exp2.f32(float %Val)
declare double @llvm.exp2.f64(double %Val)
declare x86_fp80 @llvm.exp2.f80(x86_fp80 %Val)
declare fp128 @llvm.exp2.f128(fp128 %Val)
declare ppc_fp128 @llvm.exp2.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘exp2‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.log on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.log.f32(float %Val)
declare double @llvm.log.f64(double %Val)
declare x86_fp80 @llvm.log.f80(x86_fp80 %Val)
declare fp128 @llvm.log.f128(fp128 %Val)
declare ppc_fp128 @llvm.log.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘log‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.log10 on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.log10.f32(float %Val)
declare double @llvm.log10.f64(double %Val)
declare x86_fp80 @llvm.log10.f80(x86_fp80 %Val)
declare fp128 @llvm.log10.f128(fp128 %Val)
declare ppc_fp128 @llvm.log10.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘log10‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.log2 on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.log2.f32(float %Val)
declare double @llvm.log2.f64(double %Val)
declare x86_fp80 @llvm.log2.f80(x86_fp80 %Val)
declare fp128 @llvm.log2.f128(fp128 %Val)
declare ppc_fp128 @llvm.log2.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘log2‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.fma on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.fma.f32(float %a, float %b, float %c)
declare double @llvm.fma.f64(double %a, double %b, double %c)
declare x86_fp80 @llvm.fma.f80(x86_fp80 %a, x86_fp80 %b, x86_fp80 %c)
declare fp128 @llvm.fma.f128(fp128 %a, fp128 %b, fp128 %c)
declare ppc_fp128 @llvm.fma.ppcf128(ppc_fp128 %a, ppc_fp128 %b, ppc_fp128 %c)
The arguments and return value are floating-point numbers of the same type.
Return the same value as a corresponding libm ‘fma‘ function but without trapping or setting errno.
When specified with the fast-math-flag ‘afn’, the result may be approximated using a less accurate calculation.
This is an overloaded intrinsic. You can use llvm.fabs on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.fabs.f32(float %Val)
declare double @llvm.fabs.f64(double %Val)
declare x86_fp80 @llvm.fabs.f80(x86_fp80 %Val)
declare fp128 @llvm.fabs.f128(fp128 %Val)
declare ppc_fp128 @llvm.fabs.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
This function returns the same values as the libm fabs functions would, and handles error conditions in the same way.
This is an overloaded intrinsic. You can use llvm.minnum on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.minnum.f32(float %Val0, float %Val1)
declare double @llvm.minnum.f64(double %Val0, double %Val1)
declare x86_fp80 @llvm.minnum.f80(x86_fp80 %Val0, x86_fp80 %Val1)
declare fp128 @llvm.minnum.f128(fp128 %Val0, fp128 %Val1)
declare ppc_fp128 @llvm.minnum.ppcf128(ppc_fp128 %Val0, ppc_fp128 %Val1)
The arguments and return value are floating-point numbers of the same type.
Follows the IEEE-754 semantics for minNum, which also match for libm’s fmin.
If either operand is a NaN, returns the other non-NaN operand. Returns NaN only if both operands are NaN. If the operands compare equal, returns a value that compares equal to both operands. This means that fmin(+/-0.0, +/-0.0) could return either -0.0 or 0.0.
This is an overloaded intrinsic. You can use llvm.maxnum on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.maxnum.f32(float %Val0, float %Val1l)
declare double @llvm.maxnum.f64(double %Val0, double %Val1)
declare x86_fp80 @llvm.maxnum.f80(x86_fp80 %Val0, x86_fp80 %Val1)
declare fp128 @llvm.maxnum.f128(fp128 %Val0, fp128 %Val1)
declare ppc_fp128 @llvm.maxnum.ppcf128(ppc_fp128 %Val0, ppc_fp128 %Val1)
The arguments and return value are floating-point numbers of the same type.
Follows the IEEE-754 semantics for maxNum, which also match for libm’s fmax.
If either operand is a NaN, returns the other non-NaN operand. Returns NaN only if both operands are NaN. If the operands compare equal, returns a value that compares equal to both operands. This means that fmax(+/-0.0, +/-0.0) could return either -0.0 or 0.0.
This is an overloaded intrinsic. You can use llvm.copysign on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.copysign.f32(float %Mag, float %Sgn)
declare double @llvm.copysign.f64(double %Mag, double %Sgn)
declare x86_fp80 @llvm.copysign.f80(x86_fp80 %Mag, x86_fp80 %Sgn)
declare fp128 @llvm.copysign.f128(fp128 %Mag, fp128 %Sgn)
declare ppc_fp128 @llvm.copysign.ppcf128(ppc_fp128 %Mag, ppc_fp128 %Sgn)
The ‘llvm.copysign.*‘ intrinsics return a value with the magnitude of the first operand and the sign of the second operand.
The arguments and return value are floating-point numbers of the same type.
This function returns the same values as the libm copysign functions would, and handles error conditions in the same way.
This is an overloaded intrinsic. You can use llvm.floor on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.floor.f32(float %Val)
declare double @llvm.floor.f64(double %Val)
declare x86_fp80 @llvm.floor.f80(x86_fp80 %Val)
declare fp128 @llvm.floor.f128(fp128 %Val)
declare ppc_fp128 @llvm.floor.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
This function returns the same values as the libm floor functions would, and handles error conditions in the same way.
This is an overloaded intrinsic. You can use llvm.ceil on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.ceil.f32(float %Val)
declare double @llvm.ceil.f64(double %Val)
declare x86_fp80 @llvm.ceil.f80(x86_fp80 %Val)
declare fp128 @llvm.ceil.f128(fp128 %Val)
declare ppc_fp128 @llvm.ceil.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
This function returns the same values as the libm ceil functions would, and handles error conditions in the same way.
This is an overloaded intrinsic. You can use llvm.trunc on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.trunc.f32(float %Val)
declare double @llvm.trunc.f64(double %Val)
declare x86_fp80 @llvm.trunc.f80(x86_fp80 %Val)
declare fp128 @llvm.trunc.f128(fp128 %Val)
declare ppc_fp128 @llvm.trunc.ppcf128(ppc_fp128 %Val)
The ‘llvm.trunc.*‘ intrinsics returns the operand rounded to the nearest integer not larger in magnitude than the operand.
The argument and return value are floating-point numbers of the same type.
This function returns the same values as the libm trunc functions would, and handles error conditions in the same way.
This is an overloaded intrinsic. You can use llvm.rint on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.rint.f32(float %Val)
declare double @llvm.rint.f64(double %Val)
declare x86_fp80 @llvm.rint.f80(x86_fp80 %Val)
declare fp128 @llvm.rint.f128(fp128 %Val)
declare ppc_fp128 @llvm.rint.ppcf128(ppc_fp128 %Val)
The ‘llvm.rint.*‘ intrinsics returns the operand rounded to the nearest integer. It may raise an inexact floating-point exception if the operand isn’t an integer.
The argument and return value are floating-point numbers of the same type.
This function returns the same values as the libm rint functions would, and handles error conditions in the same way.
This is an overloaded intrinsic. You can use llvm.nearbyint on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.nearbyint.f32(float %Val)
declare double @llvm.nearbyint.f64(double %Val)
declare x86_fp80 @llvm.nearbyint.f80(x86_fp80 %Val)
declare fp128 @llvm.nearbyint.f128(fp128 %Val)
declare ppc_fp128 @llvm.nearbyint.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
This function returns the same values as the libm nearbyint functions would, and handles error conditions in the same way.
This is an overloaded intrinsic. You can use llvm.round on any floating-point or vector of floating-point type. Not all targets support all types however.
declare float @llvm.round.f32(float %Val)
declare double @llvm.round.f64(double %Val)
declare x86_fp80 @llvm.round.f80(x86_fp80 %Val)
declare fp128 @llvm.round.f128(fp128 %Val)
declare ppc_fp128 @llvm.round.ppcf128(ppc_fp128 %Val)
The argument and return value are floating-point numbers of the same type.
This function returns the same values as the libm round functions would, and handles error conditions in the same way.
LLVM provides intrinsics for a few important bit manipulation operations. These allow efficient code generation for some algorithms.
This is an overloaded intrinsic function. You can use bitreverse on any integer type.
declare i16 @llvm.bitreverse.i16(i16 <id>)
declare i32 @llvm.bitreverse.i32(i32 <id>)
declare i64 @llvm.bitreverse.i64(i64 <id>)
The ‘llvm.bitreverse‘ family of intrinsics is used to reverse the bitpattern of an integer value; for example 0b10110110 becomes 0b01101101.
The llvm.bitreverse.iN intrinsic returns an iN value that has bit M in the input moved to bit N-M in the output.
This is an overloaded intrinsic function. You can use bswap on any integer type that is an even number of bytes (i.e. BitWidth % 16 == 0).
declare i16 @llvm.bswap.i16(i16 <id>)
declare i32 @llvm.bswap.i32(i32 <id>)
declare i64 @llvm.bswap.i64(i64 <id>)
The ‘llvm.bswap‘ family of intrinsics is used to byte swap integer values with an even number of bytes (positive multiple of 16 bits). These are useful for performing operations on data that is not in the target’s native byte order.
The llvm.bswap.i16 intrinsic returns an i16 value that has the high and low byte of the input i16 swapped. Similarly, the llvm.bswap.i32 intrinsic returns an i32 value that has the four bytes of the input i32 swapped, so that if the input bytes are numbered 0, 1, 2, 3 then the returned i32 will have its bytes in 3, 2, 1, 0 order. The llvm.bswap.i48, llvm.bswap.i64 and other intrinsics extend this concept to additional even-byte lengths (6 bytes, 8 bytes and more, respectively).
This is an overloaded intrinsic. You can use llvm.ctpop on any integer bit width, or on any vector with integer elements. Not all targets support all bit widths or vector types, however.
declare i8 @llvm.ctpop.i8(i8 <src>)
declare i16 @llvm.ctpop.i16(i16 <src>)
declare i32 @llvm.ctpop.i32(i32 <src>)
declare i64 @llvm.ctpop.i64(i64 <src>)
declare i256 @llvm.ctpop.i256(i256 <src>)
declare <2 x i32> @llvm.ctpop.v2i32(<2 x i32> <src>)
The only argument is the value to be counted. The argument may be of any integer type, or a vector with integer elements. The return type must match the argument type.
The ‘llvm.ctpop‘ intrinsic counts the 1’s in a variable, or within each element of a vector.
This is an overloaded intrinsic. You can use llvm.ctlz on any integer bit width, or any vector whose elements are integers. Not all targets support all bit widths or vector types, however.
declare i8 @llvm.ctlz.i8 (i8 <src>, i1 <is_zero_undef>)
declare i16 @llvm.ctlz.i16 (i16 <src>, i1 <is_zero_undef>)
declare i32 @llvm.ctlz.i32 (i32 <src>, i1 <is_zero_undef>)
declare i64 @llvm.ctlz.i64 (i64 <src>, i1 <is_zero_undef>)
declare i256 @llvm.ctlz.i256(i256 <src>, i1 <is_zero_undef>)
declare <2 x i32> @llvm.ctlz.v2i32(<2 x i32> <src>, i1 <is_zero_undef>)
The ‘llvm.ctlz‘ family of intrinsic functions counts the number of leading zeros in a variable.
The first argument is the value to be counted. This argument may be of any integer type, or a vector with integer element type. The return type must match the first argument type.
The second argument must be a constant and is a flag to indicate whether the intrinsic should ensure that a zero as the first argument produces a defined result. Historically some architectures did not provide a defined result for zero values as efficiently, and many algorithms are now predicated on avoiding zero-value inputs.
The ‘llvm.ctlz‘ intrinsic counts the leading (most significant) zeros in a variable, or within each element of the vector. If src == 0 then the result is the size in bits of the type of src if is_zero_undef == 0 and undef otherwise. For example, llvm.ctlz(i32 2) = 30.
This is an overloaded intrinsic. You can use llvm.cttz on any integer bit width, or any vector of integer elements. Not all targets support all bit widths or vector types, however.
declare i8 @llvm.cttz.i8 (i8 <src>, i1 <is_zero_undef>)
declare i16 @llvm.cttz.i16 (i16 <src>, i1 <is_zero_undef>)
declare i32 @llvm.cttz.i32 (i32 <src>, i1 <is_zero_undef>)
declare i64 @llvm.cttz.i64 (i64 <src>, i1 <is_zero_undef>)
declare i256 @llvm.cttz.i256(i256 <src>, i1 <is_zero_undef>)
declare <2 x i32> @llvm.cttz.v2i32(<2 x i32> <src>, i1 <is_zero_undef>)
The first argument is the value to be counted. This argument may be of any integer type, or a vector with integer element type. The return type must match the first argument type.
The second argument must be a constant and is a flag to indicate whether the intrinsic should ensure that a zero as the first argument produces a defined result. Historically some architectures did not provide a defined result for zero values as efficiently, and many algorithms are now predicated on avoiding zero-value inputs.
The ‘llvm.cttz‘ intrinsic counts the trailing (least significant) zeros in a variable, or within each element of a vector. If src == 0 then the result is the size in bits of the type of src if is_zero_undef == 0 and undef otherwise. For example, llvm.cttz(2) = 1.
This is an overloaded intrinsic. You can use llvm.fshl on any integer bit width or any vector of integer elements. Not all targets support all bit widths or vector types, however.
declare i8 @llvm.fshl.i8 (i8 %a, i8 %b, i8 %c)
declare i67 @llvm.fshl.i67(i67 %a, i67 %b, i67 %c)
declare <2 x i32> @llvm.fshl.v2i32(<2 x i32> %a, <2 x i32> %b, <2 x i32> %c)
The ‘llvm.fshl‘ family of intrinsic functions performs a funnel shift left: the first two values are concatenated as { %a : %b } (%a is the most significant bits of the wide value), the combined value is shifted left, and the most significant bits are extracted to produce a result that is the same size as the original arguments. If the first 2 arguments are identical, this is equivalent to a rotate left operation. For vector types, the operation occurs for each element of the vector. The shift argument is treated as an unsigned amount modulo the element size of the arguments.
The first two arguments are the values to be concatenated. The third argument is the shift amount. The arguments may be any integer type or a vector with integer element type. All arguments and the return value must have the same type.
%r = call i8 @llvm.fshl.i8(i8 %x, i8 %y, i8 %z) ; %r = i8: msb_extract((concat(x, y) << (z % 8)), 8)
%r = call i8 @llvm.fshl.i8(i8 255, i8 0, i8 15) ; %r = i8: 128 (0b10000000)
%r = call i8 @llvm.fshl.i8(i8 15, i8 15, i8 11) ; %r = i8: 120 (0b01111000)
%r = call i8 @llvm.fshl.i8(i8 0, i8 255, i8 8) ; %r = i8: 0 (0b00000000)
This is an overloaded intrinsic. You can use llvm.fshr on any integer bit width or any vector of integer elements. Not all targets support all bit widths or vector types, however.
declare i8 @llvm.fshr.i8 (i8 %a, i8 %b, i8 %c)
declare i67 @llvm.fshr.i67(i67 %a, i67 %b, i67 %c)
declare <2 x i32> @llvm.fshr.v2i32(<2 x i32> %a, <2 x i32> %b, <2 x i32> %c)
The ‘llvm.fshr‘ family of intrinsic functions performs a funnel shift right: the first two values are concatenated as { %a : %b } (%a is the most significant bits of the wide value), the combined value is shifted right, and the least significant bits are extracted to produce a result that is the same size as the original arguments. If the first 2 arguments are identical, this is equivalent to a rotate right operation. For vector types, the operation occurs for each element of the vector. The shift argument is treated as an unsigned amount modulo the element size of the arguments.
The first two arguments are the values to be concatenated. The third argument is the shift amount. The arguments may be any integer type or a vector with integer element type. All arguments and the return value must have the same type.
%r = call i8 @llvm.fshr.i8(i8 %x, i8 %y, i8 %z) ; %r = i8: lsb_extract((concat(x, y) >> (z % 8)), 8)
%r = call i8 @llvm.fshr.i8(i8 255, i8 0, i8 15) ; %r = i8: 254 (0b11111110)
%r = call i8 @llvm.fshr.i8(i8 15, i8 15, i8 11) ; %r = i8: 225 (0b11100001)
%r = call i8 @llvm.fshr.i8(i8 0, i8 255, i8 8) ; %r = i8: 255 (0b11111111)
LLVM provides intrinsics for fast arithmetic overflow checking.
Each of these intrinsics returns a two-element struct. The first element of this struct contains the result of the corresponding arithmetic operation modulo 2n, where n is the bit width of the result. Therefore, for example, the first element of the struct returned by llvm.sadd.with.overflow.i32 is always the same as the result of a 32-bit add instruction with the same operands, where the add is not modified by an nsw or nuw flag.
The second element of the result is an i1 that is 1 if the arithmetic operation overflowed and 0 otherwise. An operation overflows if, for any values of its operands A and B and for any N larger than the operands’ width, ext(A op B) to iN is not equal to (ext(A) to iN) op (ext(B) to iN) where ext is sext for signed overflow and zext for unsigned overflow, and op is the underlying arithmetic operation.
The behavior of these intrinsics is well-defined for all argument values.
This is an overloaded intrinsic. You can use llvm.sadd.with.overflow on any integer bit width.
declare {i16, i1} @llvm.sadd.with.overflow.i16(i16 %a, i16 %b)
declare {i32, i1} @llvm.sadd.with.overflow.i32(i32 %a, i32 %b)
declare {i64, i1} @llvm.sadd.with.overflow.i64(i64 %a, i64 %b)
The ‘llvm.sadd.with.overflow‘ family of intrinsic functions perform a signed addition of the two arguments, and indicate whether an overflow occurred during the signed summation.
The arguments (%a and %b) and the first element of the result structure may be of integer types of any bit width, but they must have the same bit width. The second element of the result structure must be of type i1. %a and %b are the two values that will undergo signed addition.
The ‘llvm.sadd.with.overflow‘ family of intrinsic functions perform a signed addition of the two variables. They return a structure — the first element of which is the signed summation, and the second element of which is a bit specifying if the signed summation resulted in an overflow.
This is an overloaded intrinsic. You can use llvm.uadd.with.overflow on any integer bit width.
declare {i16, i1} @llvm.uadd.with.overflow.i16(i16 %a, i16 %b)
declare {i32, i1} @llvm.uadd.with.overflow.i32(i32 %a, i32 %b)
declare {i64, i1} @llvm.uadd.with.overflow.i64(i64 %a, i64 %b)
The ‘llvm.uadd.with.overflow‘ family of intrinsic functions perform an unsigned addition of the two arguments, and indicate whether a carry occurred during the unsigned summation.
The arguments (%a and %b) and the first element of the result structure may be of integer types of any bit width, but they must have the same bit width. The second element of the result structure must be of type i1. %a and %b are the two values that will undergo unsigned addition.
The ‘llvm.uadd.with.overflow‘ family of intrinsic functions perform an unsigned addition of the two arguments. They return a structure — the first element of which is the sum, and the second element of which is a bit specifying if the unsigned summation resulted in a carry.
This is an overloaded intrinsic. You can use llvm.ssub.with.overflow on any integer bit width.
declare {i16, i1} @llvm.ssub.with.overflow.i16(i16 %a, i16 %b)
declare {i32, i1} @llvm.ssub.with.overflow.i32(i32 %a, i32 %b)
declare {i64, i1} @llvm.ssub.with.overflow.i64(i64 %a, i64 %b)
The ‘llvm.ssub.with.overflow‘ family of intrinsic functions perform a signed subtraction of the two arguments, and indicate whether an overflow occurred during the signed subtraction.
The arguments (%a and %b) and the first element of the result structure may be of integer types of any bit width, but they must have the same bit width. The second element of the result structure must be of type i1. %a and %b are the two values that will undergo signed subtraction.
The ‘llvm.ssub.with.overflow‘ family of intrinsic functions perform a signed subtraction of the two arguments. They return a structure — the first element of which is the subtraction, and the second element of which is a bit specifying if the signed subtraction resulted in an overflow.
This is an overloaded intrinsic. You can use llvm.usub.with.overflow on any integer bit width.
declare {i16, i1} @llvm.usub.with.overflow.i16(i16 %a, i16 %b)
declare {i32, i1} @llvm.usub.with.overflow.i32(i32 %a, i32 %b)
declare {i64, i1} @llvm.usub.with.overflow.i64(i64 %a, i64 %b)
The ‘llvm.usub.with.overflow‘ family of intrinsic functions perform an unsigned subtraction of the two arguments, and indicate whether an overflow occurred during the unsigned subtraction.
The arguments (%a and %b) and the first element of the result structure may be of integer types of any bit width, but they must have the same bit width. The second element of the result structure must be of type i1. %a and %b are the two values that will undergo unsigned subtraction.
The ‘llvm.usub.with.overflow‘ family of intrinsic functions perform an unsigned subtraction of the two arguments. They return a structure — the first element of which is the subtraction, and the second element of which is a bit specifying if the unsigned subtraction resulted in an overflow.
This is an overloaded intrinsic. You can use llvm.smul.with.overflow on any integer bit width.
declare {i16, i1} @llvm.smul.with.overflow.i16(i16 %a, i16 %b)
declare {i32, i1} @llvm.smul.with.overflow.i32(i32 %a, i32 %b)
declare {i64, i1} @llvm.smul.with.overflow.i64(i64 %a, i64 %b)
The ‘llvm.smul.with.overflow‘ family of intrinsic functions perform a signed multiplication of the two arguments, and indicate whether an overflow occurred during the signed multiplication.
The arguments (%a and %b) and the first element of the result structure may be of integer types of any bit width, but they must have the same bit width. The second element of the result structure must be of type i1. %a and %b are the two values that will undergo signed multiplication.
The ‘llvm.smul.with.overflow‘ family of intrinsic functions perform a signed multiplication of the two arguments. They return a structure — the first element of which is the multiplication, and the second element of which is a bit specifying if the signed multiplication resulted in an overflow.
This is an overloaded intrinsic. You can use llvm.umul.with.overflow on any integer bit width.
declare {i16, i1} @llvm.umul.with.overflow.i16(i16 %a, i16 %b)
declare {i32, i1} @llvm.umul.with.overflow.i32(i32 %a, i32 %b)
declare {i64, i1} @llvm.umul.with.overflow.i64(i64 %a, i64 %b)
The ‘llvm.umul.with.overflow‘ family of intrinsic functions perform a unsigned multiplication of the two arguments, and indicate whether an overflow occurred during the unsigned multiplication.
The arguments (%a and %b) and the first element of the result structure may be of integer types of any bit width, but they must have the same bit width. The second element of the result structure must be of type i1. %a and %b are the two values that will undergo unsigned multiplication.
The ‘llvm.umul.with.overflow‘ family of intrinsic functions perform an unsigned multiplication of the two arguments. They return a structure — the first element of which is the multiplication, and the second element of which is a bit specifying if the unsigned multiplication resulted in an overflow.
declare float @llvm.canonicalize.f32(float %a)
declare double @llvm.canonicalize.f64(double %b)
The ‘llvm.canonicalize.*‘ intrinsic returns the platform specific canonical encoding of a floating-point number. This canonicalization is useful for implementing certain numeric primitives such as frexp. The canonical encoding is defined by IEEE-754-2008 to be:
2.1.8 canonical encoding: The preferred encoding of a floating-point
representation in a format. Applied to declets, significands of finite
numbers, infinities, and NaNs, especially in decimal formats.
This operation can also be considered equivalent to the IEEE-754-2008 conversion of a floating-point value to the same format. NaNs are handled according to section 6.2.
Examples of non-canonical encodings:
Note that per IEEE-754-2008 6.2, systems that support signaling NaNs with default exception handling must signal an invalid exception, and produce a quiet NaN result.
This function should always be implementable as multiplication by 1.0, provided that the compiler does not constant fold the operation. Likewise, division by 1.0 and llvm.minnum(x, x) are possible implementations. Addition with -0.0 is also sufficient provided that the rounding mode is not -Infinity.
@llvm.canonicalize must preserve the equality relation. That is:
Additionally, the sign of zero must be conserved: @llvm.canonicalize(-0.0) = -0.0 and @llvm.canonicalize(+0.0) = +0.0
The payload bits of a NaN must be conserved, with two exceptions. First, environments which use only a single canonical representation of NaN must perform said canonicalization. Second, SNaNs must be quieted per the usual methods.
The canonicalization operation may be optimized away if:
declare float @llvm.fmuladd.f32(float %a, float %b, float %c)
declare double @llvm.fmuladd.f64(double %a, double %b, double %c)
The ‘llvm.fmuladd.*‘ intrinsic functions represent multiply-add expressions that can be fused if the code generator determines that (a) the target instruction set has support for a fused operation, and (b) that the fused operation is more efficient than the equivalent, separate pair of mul and add instructions.
The ‘llvm.fmuladd.*‘ intrinsics each take three arguments: two multiplicands, a and b, and an addend c.
The expression:
%0 = call float @llvm.fmuladd.f32(%a, %b, %c)
is equivalent to the expression a * b + c, except that rounding will not be performed between the multiplication and addition steps if the code generator fuses the operations. Fusion is not guaranteed, even if the target platform supports it. If a fused multiply-add is required the corresponding llvm.fma.* intrinsic function should be used instead. This never sets errno, just as ‘llvm.fma.*‘.
Horizontal reductions of vectors can be expressed using the following intrinsics. Each one takes a vector operand as an input and applies its respective operation across all elements of the vector, returning a single scalar result of the same element type.
declare i32 @llvm.experimental.vector.reduce.add.i32.v4i32(<4 x i32> %a)
declare i64 @llvm.experimental.vector.reduce.add.i64.v2i64(<2 x i64> %a)
The ‘llvm.experimental.vector.reduce.add.*‘ intrinsics do an integer ADD reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
declare float @llvm.experimental.vector.reduce.fadd.f32.v4f32(float %acc, <4 x float> %a)
declare double @llvm.experimental.vector.reduce.fadd.f64.v2f64(double %acc, <2 x double> %a)
The ‘llvm.experimental.vector.reduce.fadd.*‘ intrinsics do a floating-point ADD reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
If the intrinsic call has fast-math flags, then the reduction will not preserve the associativity of an equivalent scalarized counterpart. If it does not have fast-math flags, then the reduction will be ordered, implying that the operation respects the associativity of a scalarized reduction.
The first argument to this intrinsic is a scalar accumulator value, which is only used when there are no fast-math flags attached. This argument may be undef when fast-math flags are used.
The second argument must be a vector of floating-point values.
declare i32 @llvm.experimental.vector.reduce.mul.i32.v4i32(<4 x i32> %a)
declare i64 @llvm.experimental.vector.reduce.mul.i64.v2i64(<2 x i64> %a)
The ‘llvm.experimental.vector.reduce.mul.*‘ intrinsics do an integer MUL reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
declare float @llvm.experimental.vector.reduce.fmul.f32.v4f32(float %acc, <4 x float> %a)
declare double @llvm.experimental.vector.reduce.fmul.f64.v2f64(double %acc, <2 x double> %a)
The ‘llvm.experimental.vector.reduce.fmul.*‘ intrinsics do a floating-point MUL reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
If the intrinsic call has fast-math flags, then the reduction will not preserve the associativity of an equivalent scalarized counterpart. If it does not have fast-math flags, then the reduction will be ordered, implying that the operation respects the associativity of a scalarized reduction.
The first argument to this intrinsic is a scalar accumulator value, which is only used when there are no fast-math flags attached. This argument may be undef when fast-math flags are used.
The second argument must be a vector of floating-point values.
The ‘llvm.experimental.vector.reduce.and.*‘ intrinsics do a bitwise AND reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
The ‘llvm.experimental.vector.reduce.or.*‘ intrinsics do a bitwise OR reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
The ‘llvm.experimental.vector.reduce.xor.*‘ intrinsics do a bitwise XOR reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
The ‘llvm.experimental.vector.reduce.smax.*‘ intrinsics do a signed integer MAX reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
The ‘llvm.experimental.vector.reduce.smin.*‘ intrinsics do a signed integer MIN reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
The ‘llvm.experimental.vector.reduce.umax.*‘ intrinsics do an unsigned integer MAX reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
The ‘llvm.experimental.vector.reduce.umin.*‘ intrinsics do an unsigned integer MIN reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
The argument to this intrinsic must be a vector of integer values.
declare float @llvm.experimental.vector.reduce.fmax.f32.v4f32(<4 x float> %a)
declare double @llvm.experimental.vector.reduce.fmax.f64.v2f64(<2 x double> %a)
The ‘llvm.experimental.vector.reduce.fmax.*‘ intrinsics do a floating-point MAX reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
If the intrinsic call has the nnan fast-math flag then the operation can assume that NaNs are not present in the input vector.
The argument to this intrinsic must be a vector of floating-point values.
declare float @llvm.experimental.vector.reduce.fmin.f32.v4f32(<4 x float> %a)
declare double @llvm.experimental.vector.reduce.fmin.f64.v2f64(<2 x double> %a)
The ‘llvm.experimental.vector.reduce.fmin.*‘ intrinsics do a floating-point MIN reduction of a vector, returning the result as a scalar. The return type matches the element-type of the vector input.
If the intrinsic call has the nnan fast-math flag then the operation can assume that NaNs are not present in the input vector.
The argument to this intrinsic must be a vector of floating-point values.
For most target platforms, half precision floating-point is a storage-only format. This means that it is a dense encoding (in memory) but does not support computation in the format.
This means that code must first load the half-precision floating-point value as an i16, then convert it to float with llvm.convert.from.fp16. Computation can then be performed on the float value (including extending to double etc). To store the value back to memory, it is first converted to float if needed, then converted to i16 with llvm.convert.to.fp16, then storing as an i16 value.
declare i16 @llvm.convert.to.fp16.f32(float %a)
declare i16 @llvm.convert.to.fp16.f64(double %a)
The ‘llvm.convert.to.fp16‘ intrinsic function performs a conversion from a conventional floating-point type to half precision floating-point format.
The intrinsic function contains single argument - the value to be converted.
The ‘llvm.convert.to.fp16‘ intrinsic function performs a conversion from a conventional floating-point format to half precision floating-point format. The return value is an i16 which contains the converted number.
declare float @llvm.convert.from.fp16.f32(i16 %a)
declare double @llvm.convert.from.fp16.f64(i16 %a)
The ‘llvm.convert.from.fp16‘ intrinsic function performs a conversion from half precision floating-point format to single precision floating-point format.
The intrinsic function contains single argument - the value to be converted.
The ‘llvm.convert.from.fp16‘ intrinsic function performs a conversion from half single precision floating-point format to single precision floating-point format. The input half-float value is represented by an i16 value.
The LLVM debugger intrinsics (which all start with llvm.dbg. prefix), are described in the LLVM Source Level Debugging document.
The LLVM exception handling intrinsics (which all start with llvm.eh. prefix), are described in the LLVM Exception Handling document.
These intrinsics make it possible to excise one parameter, marked with the nest attribute, from a function. The result is a callable function pointer lacking the nest parameter - the caller does not need to provide a value for it. Instead, the value to use is stored in advance in a “trampoline”, a block of memory usually allocated on the stack, which also contains code to splice the nest value into the argument list. This is used to implement the GCC nested function address extension.
For example, if the function is i32 f(i8* nest %c, i32 %x, i32 %y) then the resulting function pointer has signature i32 (i32, i32)*. It can be created as follows:
%tramp = alloca [10 x i8], align 4 ; size and alignment only correct for X86
%tramp1 = getelementptr [10 x i8], [10 x i8]* %tramp, i32 0, i32 0
call i8* @llvm.init.trampoline(i8* %tramp1, i8* bitcast (i32 (i8*, i32, i32)* @f to i8*), i8* %nval)
%p = call i8* @llvm.adjust.trampoline(i8* %tramp1)
%fp = bitcast i8* %p to i32 (i32, i32)*
The call %val = call i32 %fp(i32 %x, i32 %y) is then equivalent to %val = call i32 %f(i8* %nval, i32 %x, i32 %y).
This fills the memory pointed to by tramp with executable code, turning it into a trampoline.
The llvm.init.trampoline intrinsic takes three arguments, all pointers. The tramp argument must point to a sufficiently large and sufficiently aligned block of memory; this memory is written to by the intrinsic. Note that the size and the alignment are target-specific - LLVM currently provides no portable way of determining them, so a front-end that generates this intrinsic needs to have some target-specific knowledge. The func argument must hold a function bitcast to an i8*.
The block of memory pointed to by tramp is filled with target dependent code, turning it into a function. Then tramp needs to be passed to llvm.adjust.trampoline to get a pointer which can be bitcast (to a new function) and called. The new function’s signature is the same as that of func with any arguments marked with the nest attribute removed. At most one such nest argument is allowed, and it must be of pointer type. Calling the new function is equivalent to calling func with the same argument list, but with nval used for the missing nest argument. If, after calling llvm.init.trampoline, the memory pointed to by tramp is modified, then the effect of any later call to the returned function pointer is undefined.
This performs any required machine-specific adjustment to the address of a trampoline (passed as tramp).
tramp must point to a block of memory which already has trampoline code filled in by a previous call to llvm.init.trampoline.
On some architectures the address of the code to be executed needs to be different than the address where the trampoline is actually stored. This intrinsic returns the executable address corresponding to tramp after performing the required machine specific adjustments. The pointer returned can then be bitcast and executed.
LLVM provides intrinsics for predicated vector load and store operations. The predicate is specified by a mask operand, which holds one bit per vector element, switching the associated vector lane on or off. The memory addresses corresponding to the “off” lanes are not accessed. When all bits of the mask are on, the intrinsic is identical to a regular vector load or store. When all bits are off, no memory is accessed.
This is an overloaded intrinsic. The loaded data is a vector of any integer, floating-point or pointer data type.
declare <16 x float> @llvm.masked.load.v16f32.p0v16f32 (<16 x float>* <ptr>, i32 <alignment>, <16 x i1> <mask>, <16 x float> <passthru>)
declare <2 x double> @llvm.masked.load.v2f64.p0v2f64 (<2 x double>* <ptr>, i32 <alignment>, <2 x i1> <mask>, <2 x double> <passthru>)
;; The data is a vector of pointers to double
declare <8 x double*> @llvm.masked.load.v8p0f64.p0v8p0f64 (<8 x double*>* <ptr>, i32 <alignment>, <8 x i1> <mask>, <8 x double*> <passthru>)
;; The data is a vector of function pointers
declare <8 x i32 ()*> @llvm.masked.load.v8p0f_i32f.p0v8p0f_i32f (<8 x i32 ()*>* <ptr>, i32 <alignment>, <8 x i1> <mask>, <8 x i32 ()*> <passthru>)
Reads a vector from memory according to the provided mask. The mask holds a bit for each vector lane, and is used to prevent memory accesses to the masked-off lanes. The masked-off lanes in the result vector are taken from the corresponding lanes of the ‘passthru‘ operand.
The first operand is the base pointer for the load. The second operand is the alignment of the source location. It must be a constant integer value. The third operand, mask, is a vector of boolean values with the same number of elements as the return type. The fourth is a pass-through value that is used to fill the masked-off lanes of the result. The return type, underlying type of the base pointer and the type of the ‘passthru‘ operand are the same vector types.
The ‘llvm.masked.load‘ intrinsic is designed for conditional reading of selected vector elements in a single IR operation. It is useful for targets that support vector masked loads and allows vectorizing predicated basic blocks on these targets. Other targets may support this intrinsic differently, for example by lowering it into a sequence of branches that guard scalar load operations. The result of this operation is equivalent to a regular vector load instruction followed by a ‘select’ between the loaded and the passthru values, predicated on the same mask. However, using this intrinsic prevents exceptions on memory access to masked-off lanes.
%res = call <16 x float> @llvm.masked.load.v16f32.p0v16f32 (<16 x float>* %ptr, i32 4, <16 x i1>%mask, <16 x float> %passthru)
;; The result of the two following instructions is identical aside from potential memory access exception
%loadlal = load <16 x float>, <16 x float>* %ptr, align 4
%res = select <16 x i1> %mask, <16 x float> %loadlal, <16 x float> %passthru
This is an overloaded intrinsic. The data stored in memory is a vector of any integer, floating-point or pointer data type.
declare void @llvm.masked.store.v8i32.p0v8i32 (<8 x i32> <value>, <8 x i32>* <ptr>, i32 <alignment>, <8 x i1> <mask>)
declare void @llvm.masked.store.v16f32.p0v16f32 (<16 x float> <value>, <16 x float>* <ptr>, i32 <alignment>, <16 x i1> <mask>)
;; The data is a vector of pointers to double
declare void @llvm.masked.store.v8p0f64.p0v8p0f64 (<8 x double*> <value>, <8 x double*>* <ptr>, i32 <alignment>, <8 x i1> <mask>)
;; The data is a vector of function pointers
declare void @llvm.masked.store.v4p0f_i32f.p0v4p0f_i32f (<4 x i32 ()*> <value>, <4 x i32 ()*>* <ptr>, i32 <alignment>, <4 x i1> <mask>)
Writes a vector to memory according to the provided mask. The mask holds a bit for each vector lane, and is used to prevent memory accesses to the masked-off lanes.
The first operand is the vector value to be written to memory. The second operand is the base pointer for the store, it has the same underlying type as the value operand. The third operand is the alignment of the destination location. The fourth operand, mask, is a vector of boolean values. The types of the mask and the value operand must have the same number of vector elements.
The ‘llvm.masked.store‘ intrinsics is designed for conditional writing of selected vector elements in a single IR operation. It is useful for targets that support vector masked store and allows vectorizing predicated basic blocks on these targets. Other targets may support this intrinsic differently, for example by lowering it into a sequence of branches that guard scalar store operations. The result of this operation is equivalent to a load-modify-store sequence. However, using this intrinsic prevents exceptions and data races on memory access to masked-off lanes.
call void @llvm.masked.store.v16f32.p0v16f32(<16 x float> %value, <16 x float>* %ptr, i32 4, <16 x i1> %mask)
;; The result of the following instructions is identical aside from potential data races and memory access exceptions
%oldval = load <16 x float>, <16 x float>* %ptr, align 4
%res = select <16 x i1> %mask, <16 x float> %value, <16 x float> %oldval
store <16 x float> %res, <16 x float>* %ptr, align 4
LLVM provides intrinsics for vector gather and scatter operations. They are similar to Masked Vector Load and Store, except they are designed for arbitrary memory accesses, rather than sequential memory accesses. Gather and scatter also employ a mask operand, which holds one bit per vector element, switching the associated vector lane on or off. The memory addresses corresponding to the “off” lanes are not accessed. When all bits are off, no memory is accessed.
This is an overloaded intrinsic. The loaded data are multiple scalar values of any integer, floating-point or pointer data type gathered together into one vector.
declare <16 x float> @llvm.masked.gather.v16f32.v16p0f32 (<16 x float*> <ptrs>, i32 <alignment>, <16 x i1> <mask>, <16 x float> <passthru>)
declare <2 x double> @llvm.masked.gather.v2f64.v2p1f64 (<2 x double addrspace(1)*> <ptrs>, i32 <alignment>, <2 x i1> <mask>, <2 x double> <passthru>)
declare <8 x float*> @llvm.masked.gather.v8p0f32.v8p0p0f32 (<8 x float**> <ptrs>, i32 <alignment>, <8 x i1> <mask>, <8 x float*> <passthru>)
Reads scalar values from arbitrary memory locations and gathers them into one vector. The memory locations are provided in the vector of pointers ‘ptrs‘. The memory is accessed according to the provided mask. The mask holds a bit for each vector lane, and is used to prevent memory accesses to the masked-off lanes. The masked-off lanes in the result vector are taken from the corresponding lanes of the ‘passthru‘ operand.
The first operand is a vector of pointers which holds all memory addresses to read. The second operand is an alignment of the source addresses. It must be a constant integer value. The third operand, mask, is a vector of boolean values with the same number of elements as the return type. The fourth is a pass-through value that is used to fill the masked-off lanes of the result. The return type, underlying type of the vector of pointers and the type of the ‘passthru‘ operand are the same vector types.
The ‘llvm.masked.gather‘ intrinsic is designed for conditional reading of multiple scalar values from arbitrary memory locations in a single IR operation. It is useful for targets that support vector masked gathers and allows vectorizing basic blocks with data and control divergence. Other targets may support this intrinsic differently, for example by lowering it into a sequence of scalar load operations. The semantics of this operation are equivalent to a sequence of conditional scalar loads with subsequent gathering all loaded values into a single vector. The mask restricts memory access to certain lanes and facilitates vectorization of predicated basic blocks.
%res = call <4 x double> @llvm.masked.gather.v4f64.v4p0f64 (<4 x double*> %ptrs, i32 8, <4 x i1> <i1 true, i1 true, i1 true, i1 true>, <4 x double> undef)
;; The gather with all-true mask is equivalent to the following instruction sequence
%ptr0 = extractelement <4 x double*> %ptrs, i32 0
%ptr1 = extractelement <4 x double*> %ptrs, i32 1
%ptr2 = extractelement <4 x double*> %ptrs, i32 2
%ptr3 = extractelement <4 x double*> %ptrs, i32 3
%val0 = load double, double* %ptr0, align 8
%val1 = load double, double* %ptr1, align 8
%val2 = load double, double* %ptr2, align 8
%val3 = load double, double* %ptr3, align 8
%vec0 = insertelement <4 x double>undef, %val0, 0
%vec01 = insertelement <4 x double>%vec0, %val1, 1
%vec012 = insertelement <4 x double>%vec01, %val2, 2
%vec0123 = insertelement <4 x double>%vec012, %val3, 3
This is an overloaded intrinsic. The data stored in memory is a vector of any integer, floating-point or pointer data type. Each vector element is stored in an arbitrary memory address. Scatter with overlapping addresses is guaranteed to be ordered from least-significant to most-significant element.
declare void @llvm.masked.scatter.v8i32.v8p0i32 (<8 x i32> <value>, <8 x i32*> <ptrs>, i32 <alignment>, <8 x i1> <mask>)
declare void @llvm.masked.scatter.v16f32.v16p1f32 (<16 x float> <value>, <16 x float addrspace(1)*> <ptrs>, i32 <alignment>, <16 x i1> <mask>)
declare void @llvm.masked.scatter.v4p0f64.v4p0p0f64 (<4 x double*> <value>, <4 x double**> <ptrs>, i32 <alignment>, <4 x i1> <mask>)
Writes each element from the value vector to the corresponding memory address. The memory addresses are represented as a vector of pointers. Writing is done according to the provided mask. The mask holds a bit for each vector lane, and is used to prevent memory accesses to the masked-off lanes.
The first operand is a vector value to be written to memory. The second operand is a vector of pointers, pointing to where the value elements should be stored. It has the same underlying type as the value operand. The third operand is an alignment of the destination addresses. The fourth operand, mask, is a vector of boolean values. The types of the mask and the value operand must have the same number of vector elements.
The ‘llvm.masked.scatter‘ intrinsics is designed for writing selected vector elements to arbitrary memory addresses in a single IR operation. The operation may be conditional, when not all bits in the mask are switched on. It is useful for targets that support vector masked scatter and allows vectorizing basic blocks with data and control divergence. Other targets may support this intrinsic differently, for example by lowering it into a sequence of branches that guard scalar store operations.
;; This instruction unconditionally stores data vector in multiple addresses
call @llvm.masked.scatter.v8i32.v8p0i32 (<8 x i32> %value, <8 x i32*> %ptrs, i32 4, <8 x i1> <true, true, .. true>)
;; It is equivalent to a list of scalar stores
%val0 = extractelement <8 x i32> %value, i32 0
%val1 = extractelement <8 x i32> %value, i32 1
..
%val7 = extractelement <8 x i32> %value, i32 7
%ptr0 = extractelement <8 x i32*> %ptrs, i32 0
%ptr1 = extractelement <8 x i32*> %ptrs, i32 1
..
%ptr7 = extractelement <8 x i32*> %ptrs, i32 7
;; Note: the order of the following stores is important when they overlap:
store i32 %val0, i32* %ptr0, align 4
store i32 %val1, i32* %ptr1, align 4
..
store i32 %val7, i32* %ptr7, align 4
LLVM provides intrinsics for expanding load and compressing store operations. Data selected from a vector according to a mask is stored in consecutive memory addresses (compressed store), and vice-versa (expanding load). These operations effective map to “if (cond.i) a[j++] = v.i” and “if (cond.i) v.i = a[j++]” patterns, respectively. Note that when the mask starts with ‘1’ bits followed by ‘0’ bits, these operations are identical to llvm.masked.store and llvm.masked.load.
This is an overloaded intrinsic. Several values of integer, floating point or pointer data type are loaded from consecutive memory addresses and stored into the elements of a vector according to the mask.
declare <16 x float> @llvm.masked.expandload.v16f32 (float* <ptr>, <16 x i1> <mask>, <16 x float> <passthru>)
declare <2 x i64> @llvm.masked.expandload.v2i64 (i64* <ptr>, <2 x i1> <mask>, <2 x i64> <passthru>)
Reads a number of scalar values sequentially from memory location provided in ‘ptr‘ and spreads them in a vector. The ‘mask‘ holds a bit for each vector lane. The number of elements read from memory is equal to the number of ‘1’ bits in the mask. The loaded elements are positioned in the destination vector according to the sequence of ‘1’ and ‘0’ bits in the mask. E.g., if the mask vector is ‘10010001’, “explandload” reads 3 values from memory addresses ptr, ptr+1, ptr+2 and places them in lanes 0, 3 and 7 accordingly. The masked-off lanes are filled by elements from the corresponding lanes of the ‘passthru‘ operand.
The first operand is the base pointer for the load. It has the same underlying type as the element of the returned vector. The second operand, mask, is a vector of boolean values with the same number of elements as the return type. The third is a pass-through value that is used to fill the masked-off lanes of the result. The return type and the type of the ‘passthru‘ operand have the same vector type.
The ‘llvm.masked.expandload‘ intrinsic is designed for reading multiple scalar values from adjacent memory addresses into possibly non-adjacent vector lanes. It is useful for targets that support vector expanding loads and allows vectorizing loop with cross-iteration dependency like in the following example:
// In this loop we load from B and spread the elements into array A.
double *A, B; int *C;
for (int i = 0; i < size; ++i) {
if (C[i] != 0)
A[i] = B[j++];
}
; Load several elements from array B and expand them in a vector.
; The number of loaded elements is equal to the number of '1' elements in the Mask.
%Tmp = call <8 x double> @llvm.masked.expandload.v8f64(double* %Bptr, <8 x i1> %Mask, <8 x double> undef)
; Store the result in A
call void @llvm.masked.store.v8f64.p0v8f64(<8 x double> %Tmp, <8 x double>* %Aptr, i32 8, <8 x i1> %Mask)
; %Bptr should be increased on each iteration according to the number of '1' elements in the Mask.
%MaskI = bitcast <8 x i1> %Mask to i8
%MaskIPopcnt = call i8 @llvm.ctpop.i8(i8 %MaskI)
%MaskI64 = zext i8 %MaskIPopcnt to i64
%BNextInd = add i64 %BInd, %MaskI64
Other targets may support this intrinsic differently, for example, by lowering it into a sequence of conditional scalar load operations and shuffles. If all mask elements are ‘1’, the intrinsic behavior is equivalent to the regular unmasked vector load.
This is an overloaded intrinsic. A number of scalar values of integer, floating point or pointer data type are collected from an input vector and stored into adjacent memory addresses. A mask defines which elements to collect from the vector.
declare void @llvm.masked.compressstore.v8i32 (<8 x i32> <value>, i32* <ptr>, <8 x i1> <mask>)
declare void @llvm.masked.compressstore.v16f32 (<16 x float> <value>, float* <ptr>, <16 x i1> <mask>)
Selects elements from input vector ‘value‘ according to the ‘mask‘. All selected elements are written into adjacent memory addresses starting at address ‘ptr‘, from lower to higher. The mask holds a bit for each vector lane, and is used to select elements to be stored. The number of elements to be stored is equal to the number of active bits in the mask.
The first operand is the input vector, from which elements are collected and written to memory. The second operand is the base pointer for the store, it has the same underlying type as the element of the input vector operand. The third operand is the mask, a vector of boolean values. The mask and the input vector must have the same number of vector elements.
The ‘llvm.masked.compressstore‘ intrinsic is designed for compressing data in memory. It allows to collect elements from possibly non-adjacent lanes of a vector and store them contiguously in memory in one IR operation. It is useful for targets that support compressing store operations and allows vectorizing loops with cross-iteration dependences like in the following example:
// In this loop we load elements from A and store them consecutively in B
double *A, B; int *C;
for (int i = 0; i < size; ++i) {
if (C[i] != 0)
B[j++] = A[i]
}
; Load elements from A.
%Tmp = call <8 x double> @llvm.masked.load.v8f64.p0v8f64(<8 x double>* %Aptr, i32 8, <8 x i1> %Mask, <8 x double> undef)
; Store all selected elements consecutively in array B
call <void> @llvm.masked.compressstore.v8f64(<8 x double> %Tmp, double* %Bptr, <8 x i1> %Mask)
; %Bptr should be increased on each iteration according to the number of '1' elements in the Mask.
%MaskI = bitcast <8 x i1> %Mask to i8
%MaskIPopcnt = call i8 @llvm.ctpop.i8(i8 %MaskI)
%MaskI64 = zext i8 %MaskIPopcnt to i64
%BNextInd = add i64 %BInd, %MaskI64
Other targets may support this intrinsic differently, for example, by lowering it into a sequence of branches that guard scalar store operations.
This class of intrinsics provides information about the lifetime of memory objects and ranges where variables are immutable.
The first argument is a constant integer representing the size of the object, or -1 if it is variable sized. The second argument is a pointer to the object.
This intrinsic indicates that before this point in the code, the value of the memory pointed to by ptr is dead. This means that it is known to never be used and has an undefined value. A load from the pointer that precedes this intrinsic can be replaced with 'undef'.
The first argument is a constant integer representing the size of the object, or -1 if it is variable sized. The second argument is a pointer to the object.
This intrinsic indicates that after this point in the code, the value of the memory pointed to by ptr is dead. This means that it is known to never be used and has an undefined value. Any stores into the memory object following this intrinsic may be removed as dead.
This is an overloaded intrinsic. The memory object can belong to any address space.
declare {}* @llvm.invariant.start.p0i8(i64 <size>, i8* nocapture <ptr>)
The ‘llvm.invariant.start‘ intrinsic specifies that the contents of a memory object will not change.
The first argument is a constant integer representing the size of the object, or -1 if it is variable sized. The second argument is a pointer to the object.
This intrinsic indicates that until an llvm.invariant.end that uses the return value, the referenced memory location is constant and unchanging.
This is an overloaded intrinsic. The memory object can belong to any address space.
declare void @llvm.invariant.end.p0i8({}* <start>, i64 <size>, i8* nocapture <ptr>)
The ‘llvm.invariant.end‘ intrinsic specifies that the contents of a memory object are mutable.
The first argument is the matching llvm.invariant.start intrinsic. The second argument is a constant integer representing the size of the object, or -1 if it is variable sized and the third argument is a pointer to the object.
This intrinsic indicates that the memory is mutable again.
This is an overloaded intrinsic. The memory object can belong to any address space. The returned pointer must belong to the same address space as the argument.
declare i8* @llvm.launder.invariant.group.p0i8(i8* <ptr>)
The ‘llvm.launder.invariant.group‘ intrinsic can be used when an invariant established by invariant.group metadata no longer holds, to obtain a new pointer value that carries fresh invariant group information. It is an experimental intrinsic, which means that its semantics might change in the future.
The llvm.launder.invariant.group takes only one argument, which is a pointer to the memory.
Returns another pointer that aliases its argument but which is considered different for the purposes of load/store invariant.group metadata. It does not read any accessible memory and the execution can be speculated.
This is an overloaded intrinsic. The memory object can belong to any address space. The returned pointer must belong to the same address space as the argument.
declare i8* @llvm.strip.invariant.group.p0i8(i8* <ptr>)
The ‘llvm.strip.invariant.group‘ intrinsic can be used when an invariant established by invariant.group metadata no longer holds, to obtain a new pointer value that does not carry the invariant information. It is an experimental intrinsic, which means that its semantics might change in the future.
The llvm.strip.invariant.group takes only one argument, which is a pointer to the memory.
Returns another pointer that aliases its argument but which has no associated invariant.group metadata. It does not read any memory and can be speculated.
These intrinsics are used to provide special handling of floating-point operations when specific rounding mode or floating-point exception behavior is required. By default, LLVM optimization passes assume that the rounding mode is round-to-nearest and that floating-point exceptions will not be monitored. Constrained FP intrinsics are used to support non-default rounding modes and accurately preserve exception behavior without compromising LLVM’s ability to optimize FP code when the default behavior is used.
Each of these intrinsics corresponds to a normal floating-point operation. The first two arguments and the return value are the same as the corresponding FP operation.
The third argument is a metadata argument specifying the rounding mode to be assumed. This argument must be one of the following strings:
"round.dynamic"
"round.tonearest"
"round.downward"
"round.upward"
"round.towardzero"
If this argument is “round.dynamic” optimization passes must assume that the rounding mode is unknown and may change at runtime. No transformations that depend on rounding mode may be performed in this case.
The other possible values for the rounding mode argument correspond to the similarly named IEEE rounding modes. If the argument is any of these values optimization passes may perform transformations as long as they are consistent with the specified rounding mode.
For example, ‘x-0’->’x’ is not a valid transformation if the rounding mode is “round.downward” or “round.dynamic” because if the value of ‘x’ is +0 then ‘x-0’ should evaluate to ‘-0’ when rounding downward. However, this transformation is legal for all other rounding modes.
For values other than “round.dynamic” optimization passes may assume that the actual runtime rounding mode (as defined in a target-specific manner) matches the specified rounding mode, but this is not guaranteed. Using a specific non-dynamic rounding mode which does not match the actual rounding mode at runtime results in undefined behavior.
The fourth argument to the constrained floating-point intrinsics specifies the required exception behavior. This argument must be one of the following strings:
"fpexcept.ignore"
"fpexcept.maytrap"
"fpexcept.strict"
If this argument is “fpexcept.ignore” optimization passes may assume that the exception status flags will not be read and that floating-point exceptions will be masked. This allows transformations to be performed that may change the exception semantics of the original code. For example, FP operations may be speculatively executed in this case whereas they must not be for either of the other possible values of this argument.
If the exception behavior argument is “fpexcept.maytrap” optimization passes must avoid transformations that may raise exceptions that would not have been raised by the original code (such as speculatively executing FP operations), but passes are not required to preserve all exceptions that are implied by the original code. For example, exceptions may be potentially hidden by constant folding.
If the exception behavior argument is “fpexcept.strict” all transformations must strictly preserve the floating-point exception semantics of the original code. Any FP exception that would have been raised by the original code must be raised by the transformed code, and the transformed code must not raise any FP exceptions that would not have been raised by the original code. This is the exception behavior argument that will be used if the code being compiled reads the FP exception status flags, but this mode can also be used with code that unmasks FP exceptions.
The number and order of floating-point exceptions is NOT guaranteed. For example, a series of FP operations that each may raise exceptions may be vectorized into a single instruction that raises each unique exception a single time.
declare <type>
@llvm.experimental.constrained.fadd(<type> <op1>, <type> <op2>,
metadata <rounding mode>,
metadata <exception behavior>)
The first two arguments to the ‘llvm.experimental.constrained.fadd‘ intrinsic must be floating-point or vector of floating-point values. Both arguments must have identical types.
The third and fourth arguments specify the rounding mode and exception behavior as described above.
The value produced is the floating-point sum of the two value operands and has the same type as the operands.
declare <type>
@llvm.experimental.constrained.fsub(<type> <op1>, <type> <op2>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.fsub‘ intrinsic returns the difference of its two operands.
The first two arguments to the ‘llvm.experimental.constrained.fsub‘ intrinsic must be floating-point or vector of floating-point values. Both arguments must have identical types.
The third and fourth arguments specify the rounding mode and exception behavior as described above.
The value produced is the floating-point difference of the two value operands and has the same type as the operands.
declare <type>
@llvm.experimental.constrained.fmul(<type> <op1>, <type> <op2>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.fmul‘ intrinsic returns the product of its two operands.
The first two arguments to the ‘llvm.experimental.constrained.fmul‘ intrinsic must be floating-point or vector of floating-point values. Both arguments must have identical types.
The third and fourth arguments specify the rounding mode and exception behavior as described above.
The value produced is the floating-point product of the two value operands and has the same type as the operands.
declare <type>
@llvm.experimental.constrained.fdiv(<type> <op1>, <type> <op2>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.fdiv‘ intrinsic returns the quotient of its two operands.
The first two arguments to the ‘llvm.experimental.constrained.fdiv‘ intrinsic must be floating-point or vector of floating-point values. Both arguments must have identical types.
The third and fourth arguments specify the rounding mode and exception behavior as described above.
The value produced is the floating-point quotient of the two value operands and has the same type as the operands.
declare <type>
@llvm.experimental.constrained.frem(<type> <op1>, <type> <op2>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.frem‘ intrinsic returns the remainder from the division of its two operands.
The first two arguments to the ‘llvm.experimental.constrained.frem‘ intrinsic must be floating-point or vector of floating-point values. Both arguments must have identical types.
The third and fourth arguments specify the rounding mode and exception behavior as described above. The rounding mode argument has no effect, since the result of frem is never rounded, but the argument is included for consistency with the other constrained floating-point intrinsics.
The value produced is the floating-point remainder from the division of the two value operands and has the same type as the operands. The remainder has the same sign as the dividend.
declare <type>
@llvm.experimental.constrained.fma(<type> <op1>, <type> <op2>, <type> <op3>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.fma‘ intrinsic returns the result of a fused-multiply-add operation on its operands.
The first three arguments to the ‘llvm.experimental.constrained.fma‘ intrinsic must be floating-point or vector of floating-point values. All arguments must have identical types.
The fourth and fifth arguments specify the rounding mode and exception behavior as described above.
The result produced is the product of the first two operands added to the third operand computed with infinite precision, and then rounded to the target precision.
In addition to the basic floating-point operations for which constrained intrinsics are described above, there are constrained versions of various operations which provide equivalent behavior to a corresponding libm function. These intrinsics allow the precise behavior of these operations with respect to rounding mode and exception behavior to be controlled.
As with the basic constrained floating-point intrinsics, the rounding mode and exception behavior arguments only control the behavior of the optimizer. They do not change the runtime floating-point environment.
declare <type>
@llvm.experimental.constrained.sqrt(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.sqrt‘ intrinsic returns the square root of the specified value, returning the same value as the libm ‘sqrt‘ functions would, but without setting errno.
The first argument and the return type are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the nonnegative square root of the specified value. If the value is less than negative zero, a floating-point exception occurs and the return value is architecture specific.
declare <type>
@llvm.experimental.constrained.pow(<type> <op1>, <type> <op2>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.pow‘ intrinsic returns the first operand raised to the (positive or negative) power specified by the second operand.
The first two arguments and the return value are floating-point numbers of the same type. The second argument specifies the power to which the first argument should be raised.
The third and fourth arguments specify the rounding mode and exception behavior as described above.
This function returns the first value raised to the second power, returning the same values as the libm pow functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.powi(<type> <op1>, i32 <op2>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.powi‘ intrinsic returns the first operand raised to the (positive or negative) power specified by the second operand. The order of evaluation of multiplications is not defined. When a vector of floating-point type is used, the second argument remains a scalar integer value.
The first argument and the return value are floating-point numbers of the same type. The second argument is a 32-bit signed integer specifying the power to which the first argument should be raised.
The third and fourth arguments specify the rounding mode and exception behavior as described above.
This function returns the first value raised to the second power with an unspecified sequence of rounding operations.
declare <type>
@llvm.experimental.constrained.sin(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The first argument and the return type are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the sine of the specified operand, returning the same values as the libm sin functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.cos(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.cos‘ intrinsic returns the cosine of the first operand.
The first argument and the return type are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the cosine of the specified operand, returning the same values as the libm cos functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.exp(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.exp‘ intrinsic computes the base-e exponential of the specified value.
The first argument and the return value are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the same values as the libm exp functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.exp2(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.exp2‘ intrinsic computes the base-2 exponential of the specified value.
The first argument and the return value are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the same values as the libm exp2 functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.log(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.log‘ intrinsic computes the base-e logarithm of the specified value.
The first argument and the return value are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the same values as the libm log functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.log10(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.log10‘ intrinsic computes the base-10 logarithm of the specified value.
The first argument and the return value are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the same values as the libm log10 functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.log2(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.log2‘ intrinsic computes the base-2 logarithm of the specified value.
The first argument and the return value are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the same values as the libm log2 functions would, and handles error conditions in the same way.
declare <type>
@llvm.experimental.constrained.rint(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.rint‘ intrinsic returns the first operand rounded to the nearest integer. It may raise an inexact floating-point exception if the operand is not an integer.
The first argument and the return value are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the same values as the libm rint functions would, and handles error conditions in the same way. The rounding mode is described, not determined, by the rounding mode argument. The actual rounding mode is determined by the runtime floating-point environment. The rounding mode argument is only intended as information to the compiler.
declare <type>
@llvm.experimental.constrained.nearbyint(<type> <op1>,
metadata <rounding mode>,
metadata <exception behavior>)
The ‘llvm.experimental.constrained.nearbyint‘ intrinsic returns the first operand rounded to the nearest integer. It will not raise an inexact floating-point exception if the operand is not an integer.
The first argument and the return value are floating-point numbers of the same type.
The second and third arguments specify the rounding mode and exception behavior as described above.
This function returns the same values as the libm nearbyint functions would, and handles error conditions in the same way. The rounding mode is described, not determined, by the rounding mode argument. The actual rounding mode is determined by the runtime floating-point environment. The rounding mode argument is only intended as information to the compiler.
This class of intrinsics is designed to be generic and has no specific purpose.
The first argument is a pointer to a value, the second is a pointer to a global string, the third is a pointer to a global string which is the source file name, and the last argument is the line number.
This intrinsic allows annotation of local variables with arbitrary strings. This can be useful for special purpose optimizations that want to look for these annotations. These have no other defined use; they are ignored by code generation and optimization.
This is an overloaded intrinsic. You can use ‘llvm.ptr.annotation‘ on a pointer to an integer of any width. NOTE you must specify an address space for the pointer. The identifier for the default address space is the integer ‘0‘.
declare i8* @llvm.ptr.annotation.p<address space>i8(i8* <val>, i8* <str>, i8* <str>, i32 <int>)
declare i16* @llvm.ptr.annotation.p<address space>i16(i16* <val>, i8* <str>, i8* <str>, i32 <int>)
declare i32* @llvm.ptr.annotation.p<address space>i32(i32* <val>, i8* <str>, i8* <str>, i32 <int>)
declare i64* @llvm.ptr.annotation.p<address space>i64(i64* <val>, i8* <str>, i8* <str>, i32 <int>)
declare i256* @llvm.ptr.annotation.p<address space>i256(i256* <val>, i8* <str>, i8* <str>, i32 <int>)
The first argument is a pointer to an integer value of arbitrary bitwidth (result of some expression), the second is a pointer to a global string, the third is a pointer to a global string which is the source file name, and the last argument is the line number. It returns the value of the first argument.
This intrinsic allows annotation of a pointer to an integer with arbitrary strings. This can be useful for special purpose optimizations that want to look for these annotations. These have no other defined use; they are ignored by code generation and optimization.
This is an overloaded intrinsic. You can use ‘llvm.annotation‘ on any integer bit width.
declare i8 @llvm.annotation.i8(i8 <val>, i8* <str>, i8* <str>, i32 <int>)
declare i16 @llvm.annotation.i16(i16 <val>, i8* <str>, i8* <str>, i32 <int>)
declare i32 @llvm.annotation.i32(i32 <val>, i8* <str>, i8* <str>, i32 <int>)
declare i64 @llvm.annotation.i64(i64 <val>, i8* <str>, i8* <str>, i32 <int>)
declare i256 @llvm.annotation.i256(i256 <val>, i8* <str>, i8* <str>, i32 <int>)
The first argument is an integer value (result of some expression), the second is a pointer to a global string, the third is a pointer to a global string which is the source file name, and the last argument is the line number. It returns the value of the first argument.
This intrinsic allows annotations to be put on arbitrary expressions with arbitrary strings. This can be useful for special purpose optimizations that want to look for these annotations. These have no other defined use; they are ignored by code generation and optimization.
This annotation emits a label at its program point and an associated S_ANNOTATION codeview record with some additional string metadata. This is used to implement MSVC’s __annotation intrinsic. It is marked noduplicate, so calls to this intrinsic prevent inlining and should be considered expensive.
declare void @llvm.codeview.annotation(metadata)
The argument should be an MDTuple containing any number of MDStrings.
None.
This intrinsic is lowered to the target dependent trap instruction. If the target does not have a trap instruction, this intrinsic will be lowered to a call of the abort() function.
None.
This intrinsic is lowered to code which is intended to cause an execution trap with the intention of requesting the attention of a debugger.
The llvm.stackprotector intrinsic takes the guard and stores it onto the stack at slot. The stack slot is adjusted to ensure that it is placed on the stack before local variables.
The llvm.stackprotector intrinsic requires two pointer arguments. The first argument is the value loaded from the stack guard @__stack_chk_guard. The second variable is an alloca that has enough space to hold the value of the guard.
This intrinsic causes the prologue/epilogue inserter to force the position of the AllocaInst stack slot to be before local variables on the stack. This is to ensure that if a local variable on the stack is overwritten, it will destroy the value of the guard. When the function exits, the guard on the stack is checked against the original guard by llvm.stackprotectorcheck. If they are different, then llvm.stackprotectorcheck causes the program to abort by calling the __stack_chk_fail() function.
The llvm.stackguard intrinsic returns the system stack guard value.
It should not be generated by frontends, since it is only for internal usage. The reason why we create this intrinsic is that we still support IR form Stack Protector in FastISel.
None.
On some platforms, the value returned by this intrinsic remains unchanged between loads in the same thread. On other platforms, it returns the same global variable value, if any, e.g. @__stack_chk_guard.
Currently some platforms have IR-level customized stack guard loading (e.g. X86 Linux) that is not handled by llvm.stackguard(), while they should be in the future.
declare i32 @llvm.objectsize.i32(i8* <object>, i1 <min>, i1 <nullunknown>)
declare i64 @llvm.objectsize.i64(i8* <object>, i1 <min>, i1 <nullunknown>)
The llvm.objectsize intrinsic is designed to provide information to the optimizers to determine at compile time whether a) an operation (like memcpy) will overflow a buffer that corresponds to an object, or b) that a runtime check for overflow isn’t necessary. An object in this context means an allocation of a specific class, structure, array, or other object.
The llvm.objectsize intrinsic takes three arguments. The first argument is a pointer to or into the object. The second argument determines whether llvm.objectsize returns 0 (if true) or -1 (if false) when the object size is unknown. The third argument controls how llvm.objectsize acts when null in address space 0 is used as its pointer argument. If it’s false, llvm.objectsize reports 0 bytes available when given null. Otherwise, if the null is in a non-zero address space or if true is given for the third argument of llvm.objectsize, we assume its size is unknown.
The second and third arguments only accept constants.
The llvm.objectsize intrinsic is lowered to a constant representing the size of the object concerned. If the size cannot be determined at compile time, llvm.objectsize returns i32/i64 -1 or 0 (depending on the min argument).
This is an overloaded intrinsic. You can use llvm.expect on any integer bit width.
declare i1 @llvm.expect.i1(i1 <val>, i1 <expected_val>)
declare i32 @llvm.expect.i32(i32 <val>, i32 <expected_val>)
declare i64 @llvm.expect.i64(i64 <val>, i64 <expected_val>)
The llvm.expect intrinsic provides information about expected (the most probable) value of val, which can be used by optimizers.
The llvm.expect intrinsic takes two arguments. The first argument is a value. The second argument is an expected value, this needs to be a constant value, variables are not allowed.
This intrinsic is lowered to the val.
The llvm.assume allows the optimizer to assume that the provided condition is true. This information can then be used in simplifying other parts of the code.
The condition which the optimizer may assume is always true.
The intrinsic allows the optimizer to assume that the provided condition is always true whenever the control flow reaches the intrinsic call. No code is generated for this intrinsic, and instructions that contribute only to the provided condition are not used for code generation. If the condition is violated during execution, the behavior is undefined.
Note that the optimizer might limit the transformations performed on values used by the llvm.assume intrinsic in order to preserve the instructions only used to form the intrinsic’s input argument. This might prove undesirable if the extra information provided by the llvm.assume intrinsic does not cause sufficient overall improvement in code quality. For this reason, llvm.assume should not be used to document basic mathematical invariants that the optimizer can otherwise deduce or facts that are of little use to the optimizer.
The first argument is an operand which is used as the returned value.
The llvm.ssa_copy intrinsic can be used to attach information to operations by copying them and giving them new names. For example, the PredicateInfo utility uses it to build Extended SSA form, and attach various forms of information to operands that dominate specific uses. It is not meant for general use, only for building temporary renaming forms that require value splits at certain points.
The first argument is a pointer to be tested. The second argument is a metadata object representing a type identifier.
declare {i8*, i1} @llvm.type.checked.load(i8* %ptr, i32 %offset, metadata %type) argmemonly nounwind readonly
The first argument is a pointer from which to load a function pointer. The second argument is the byte offset from which to load the function pointer. The third argument is a metadata object representing a type identifier.
The llvm.type.checked.load intrinsic safely loads a function pointer from a virtual table pointer using type metadata. This intrinsic is used to implement control flow integrity in conjunction with virtual call optimization. The virtual call optimization pass will optimize away llvm.type.checked.load intrinsics associated with devirtualized calls, thereby removing the type check in cases where it is not needed to enforce the control flow integrity constraint.
If the given pointer is associated with a type metadata identifier, this function returns true as the second element of its return value. (Note that the function may also return true if the given pointer is not associated with a type metadata identifier.) If the function’s return value’s second element is true, the following rules apply to the first element:
If the function’s return value’s second element is false, the value of the first element is undefined.
The llvm.donothing intrinsic doesn’t perform any operation. It’s one of only three intrinsics (besides llvm.experimental.patchpoint and llvm.experimental.gc.statepoint) that can be called with an invoke instruction.
None.
This intrinsic does nothing, and it’s removed by optimizers and ignored by codegen.
This intrinsic, together with deoptimization operand bundles, allow frontends to express transfer of control and frame-local state from the currently executing (typically more specialized, hence faster) version of a function into another (typically more generic, hence slower) version.
In languages with a fully integrated managed runtime like Java and JavaScript this intrinsic can be used to implement “uncommon trap” or “side exit” like functionality. In unmanaged languages like C and C++, this intrinsic can be used to represent the slow paths of specialized functions.
The intrinsic takes an arbitrary number of arguments, whose meaning is decided by the lowering strategy.
The @llvm.experimental.deoptimize intrinsic executes an attached deoptimization continuation (denoted using a deoptimization operand bundle) and returns the value returned by the deoptimization continuation. Defining the semantic properties of the continuation itself is out of scope of the language reference – as far as LLVM is concerned, the deoptimization continuation can invoke arbitrary side effects, including reading from and writing to the entire heap.
Deoptimization continuations expressed using "deopt" operand bundles always continue execution to the end of the physical frame containing them, so all calls to @llvm.experimental.deoptimize must be in “tail position”:
- @llvm.experimental.deoptimize cannot be invoked.
- The call must immediately precede a ret instruction.
- The ret instruction must return the value produced by the @llvm.experimental.deoptimize call if there is one, or void.
Note that the above restrictions imply that the return type for a call to @llvm.experimental.deoptimize will match the return type of its immediate caller.
The inliner composes the "deopt" continuations of the caller into the "deopt" continuations present in the inlinee, and also updates calls to this intrinsic to return directly from the frame of the function it inlined into.
All declarations of @llvm.experimental.deoptimize must share the same calling convention.
Calls to @llvm.experimental.deoptimize are lowered to calls to the symbol __llvm_deoptimize (it is the frontend’s responsibility to ensure that this symbol is defined). The call arguments to @llvm.experimental.deoptimize are lowered as if they were formal arguments of the specified types, and not as varargs.
This intrinsic, together with deoptimization operand bundles, allows frontends to express guards or checks on optimistic assumptions made during compilation. The semantics of @llvm.experimental.guard is defined in terms of @llvm.experimental.deoptimize – its body is defined to be equivalent to:
define void @llvm.experimental.guard(i1 %pred, <args...>) {
%realPred = and i1 %pred, undef
br i1 %realPred, label %continue, label %leave [, !make.implicit !{}]
leave:
call void @llvm.experimental.deoptimize(<args...>) [ "deopt"() ]
ret void
continue:
ret void
}
with the optional [, !make.implicit !{}] present if and only if it is present on the call site. For more details on !make.implicit, see FaultMaps and implicit checks.
In words, @llvm.experimental.guard executes the attached "deopt" continuation if (but not only if) its first argument is false. Since the optimizer is allowed to replace the undef with an arbitrary value, it can optimize guard to fail “spuriously”, i.e. without the original condition being false (hence the “not only if”); and this allows for “check widening” type optimizations.
@llvm.experimental.guard cannot be invoked.
This intrinsic loads a 32-bit value from the address %ptr + %offset, adds %ptr to that value and returns it. The constant folder specifically recognizes the form of this intrinsic and the constant initializers it may load from; if a loaded constant initializer is known to have the form i32 trunc(x - %ptr), the intrinsic call is folded to x.
LLVM provides that the calculation of such a constant initializer will not overflow at link time under the medium code model if x is an unnamed_addr function. However, it does not provide this guarantee for a constant initializer folded into a function body. This intrinsic can be used to avoid the possibility of overflows when loading from such a constant.
The llvm.sideeffect intrinsic doesn’t perform any operation. Optimizers treat it as having side effects, so it can be inserted into a loop to indicate that the loop shouldn’t be assumed to terminate (which could potentially lead to the loop being optimized away entirely), even if it’s an infinite loop with no other side effects.
None.
This intrinsic actually does nothing, but optimizers must assume that it has externally observable side effects.
LLVM provides experimental intrinsics to support runtime patching mechanisms commonly desired in dynamic language JITs. These intrinsics are described in Stack maps and patch points in LLVM.
These intrinsics are similar to the standard library memory intrinsics except that they perform memory transfer as a sequence of atomic memory accesses.
This is an overloaded intrinsic. You can use llvm.memcpy.element.unordered.atomic on any integer bit width and for different address spaces. Not all targets support all bit widths however.
declare void @llvm.memcpy.element.unordered.atomic.p0i8.p0i8.i32(i8* <dest>,
i8* <src>,
i32 <len>,
i32 <element_size>)
declare void @llvm.memcpy.element.unordered.atomic.p0i8.p0i8.i64(i8* <dest>,
i8* <src>,
i64 <len>,
i32 <element_size>)
The ‘llvm.memcpy.element.unordered.atomic.*‘ intrinsic is a specialization of the ‘llvm.memcpy.*‘ intrinsic. It differs in that the dest and src are treated as arrays with elements that are exactly element_size bytes, and the copy between buffers uses a sequence of unordered atomic load/store operations that are a positive integer multiple of the element_size in size.
The first three arguments are the same as they are in the @llvm.memcpy intrinsic, with the added constraint that len is required to be a positive integer multiple of the element_size. If len is not a positive integer multiple of element_size, then the behaviour of the intrinsic is undefined.
element_size must be a compile-time constant positive power of two no greater than target-specific atomic access size limit.
For each of the input pointers align parameter attribute must be specified. It must be a power of two no less than the element_size. Caller guarantees that both the source and destination pointers are aligned to that boundary.
The ‘llvm.memcpy.element.unordered.atomic.*‘ intrinsic copies len bytes of memory from the source location to the destination location. These locations are not allowed to overlap. The memory copy is performed as a sequence of load/store operations where each access is guaranteed to be a multiple of element_size bytes wide and aligned at an element_size boundary.
The order of the copy is unspecified. The same value may be read from the source buffer many times, but only one write is issued to the destination buffer per element. It is well defined to have concurrent reads and writes to both source and destination provided those reads and writes are unordered atomic when specified.
This intrinsic does not provide any additional ordering guarantees over those provided by a set of unordered loads from the source location and stores to the destination.
This is an overloaded intrinsic. You can use llvm.memmove.element.unordered.atomic on any integer bit width and for different address spaces. Not all targets support all bit widths however.
declare void @llvm.memmove.element.unordered.atomic.p0i8.p0i8.i32(i8* <dest>,
i8* <src>,
i32 <len>,
i32 <element_size>)
declare void @llvm.memmove.element.unordered.atomic.p0i8.p0i8.i64(i8* <dest>,
i8* <src>,
i64 <len>,
i32 <element_size>)
The ‘llvm.memmove.element.unordered.atomic.*‘ intrinsic is a specialization of the ‘llvm.memmove.*‘ intrinsic. It differs in that the dest and src are treated as arrays with elements that are exactly element_size bytes, and the copy between buffers uses a sequence of unordered atomic load/store operations that are a positive integer multiple of the element_size in size.
The first three arguments are the same as they are in the @llvm.memmove intrinsic, with the added constraint that len is required to be a positive integer multiple of the element_size. If len is not a positive integer multiple of element_size, then the behaviour of the intrinsic is undefined.
element_size must be a compile-time constant positive power of two no greater than a target-specific atomic access size limit.
For each of the input pointers the align parameter attribute must be specified. It must be a power of two no less than the element_size. Caller guarantees that both the source and destination pointers are aligned to that boundary.
The ‘llvm.memmove.element.unordered.atomic.*‘ intrinsic copies len bytes of memory from the source location to the destination location. These locations are allowed to overlap. The memory copy is performed as a sequence of load/store operations where each access is guaranteed to be a multiple of element_size bytes wide and aligned at an element_size boundary.
The order of the copy is unspecified. The same value may be read from the source buffer many times, but only one write is issued to the destination buffer per element. It is well defined to have concurrent reads and writes to both source and destination provided those reads and writes are unordered atomic when specified.
This intrinsic does not provide any additional ordering guarantees over those provided by a set of unordered loads from the source location and stores to the destination.
In the most general case call to the ‘llvm.memmove.element.unordered.atomic.*‘ is lowered to a call to the symbol __llvm_memmove_element_unordered_atomic_*. Where ‘*’ is replaced with an actual element size.
The optimizer is allowed to inline the memory copy when it’s profitable to do so.
This is an overloaded intrinsic. You can use llvm.memset.element.unordered.atomic on any integer bit width and for different address spaces. Not all targets support all bit widths however.
declare void @llvm.memset.element.unordered.atomic.p0i8.i32(i8* <dest>,
i8 <value>,
i32 <len>,
i32 <element_size>)
declare void @llvm.memset.element.unordered.atomic.p0i8.i64(i8* <dest>,
i8 <value>,
i64 <len>,
i32 <element_size>)
The ‘llvm.memset.element.unordered.atomic.*‘ intrinsic is a specialization of the ‘llvm.memset.*‘ intrinsic. It differs in that the dest is treated as an array with elements that are exactly element_size bytes, and the assignment to that array uses uses a sequence of unordered atomic store operations that are a positive integer multiple of the element_size in size.
The first three arguments are the same as they are in the @llvm.memset intrinsic, with the added constraint that len is required to be a positive integer multiple of the element_size. If len is not a positive integer multiple of element_size, then the behaviour of the intrinsic is undefined.
element_size must be a compile-time constant positive power of two no greater than target-specific atomic access size limit.
The dest input pointer must have the align parameter attribute specified. It must be a power of two no less than the element_size. Caller guarantees that the destination pointer is aligned to that boundary.
The ‘llvm.memset.element.unordered.atomic.*‘ intrinsic sets the len bytes of memory starting at the destination location to the given value. The memory is set with a sequence of store operations where each access is guaranteed to be a multiple of element_size bytes wide and aligned at an element_size boundary.
The order of the assignment is unspecified. Only one write is issued to the destination buffer per element. It is well defined to have concurrent reads and writes to the destination provided those reads and writes are unordered atomic when specified.
This intrinsic does not provide any additional ordering guarantees over those provided by a set of unordered stores to the destination.
In the most general case call to the ‘llvm.memset.element.unordered.atomic.*‘ is lowered to a call to the symbol __llvm_memset_element_unordered_atomic_*. Where ‘*’ is replaced with an actual element size.
The optimizer is allowed to inline the memory assignment when it’s profitable to do so.