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ec3618d58d
llvm-mirror/bindings/ocaml/llvm/llvm.mli
Peter Zotov ec3618d58d [OCaml] Introduce an llmdkind abstract type. 
Patch by Gabriel Radanne.

While this commit technically breaks API, no code should have supplied
the integer IDs directly, and thus no code should break.

llvm-svn: 210395
2014-06-07 15:15:10 +00:00

2469 lines
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OCaml
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(*===-- llvm/llvm.mli - LLVM OCaml Interface ------------------------------===*
*
* The LLVM Compiler Infrastructure
*
* This file is distributed under the University of Illinois Open Source
* License. See LICENSE.TXT for details.
*
*===----------------------------------------------------------------------===*)
(** Core API.
This interface provides an OCaml API for the LLVM intermediate
representation, the classes in the VMCore library. *)
(** {6 Abstract types}
These abstract types correlate directly to the LLVM VMCore classes. *)
(** The top-level container for all LLVM global data. See the
[llvm::LLVMContext] class. *)
type llcontext
(** The top-level container for all other LLVM Intermediate Representation (IR)
objects. See the [llvm::Module] class. *)
type llmodule
(** Each value in the LLVM IR has a type, an instance of [lltype]. See the
[llvm::Type] class. *)
type lltype
(** Any value in the LLVM IR. Functions, instructions, global variables,
constants, and much more are all [llvalues]. See the [llvm::Value] class.
This type covers a wide range of subclasses. *)
type llvalue
(** Used to store users and usees of values. See the [llvm::Use] class. *)
type lluse
(** A basic block in LLVM IR. See the [llvm::BasicBlock] class. *)
type llbasicblock
(** Used to generate instructions in the LLVM IR. See the [llvm::LLVMBuilder]
class. *)
type llbuilder
(** Used to efficiently handle large buffers of read-only binary data.
See the [llvm::MemoryBuffer] class. *)
type llmemorybuffer
(** The kind id of metadata attached to an instruction. *)
type llmdkind
(** The kind of an [lltype], the result of [classify_type ty]. See the
[llvm::Type::TypeID] enumeration. *)
module TypeKind : sig
type t =
Void
| Half
| Float
| Double
| X86fp80
| Fp128
| Ppc_fp128
| Label
| Integer
| Function
| Struct
| Array
| Pointer
| Vector
| Metadata
| X86_mmx
end
(** The linkage of a global value, accessed with {!linkage} and
{!set_linkage}. See [llvm::GlobalValue::LinkageTypes]. *)
module Linkage : sig
type t =
External
| Available_externally
| Link_once
| Link_once_odr
| Link_once_odr_auto_hide
| Weak
| Weak_odr
| Appending
| Internal
| Private
| Dllimport
| Dllexport
| External_weak
| Ghost
| Common
| Linker_private
| Linker_private_weak
end
(** The linker visibility of a global value, accessed with {!visibility} and
{!set_visibility}. See [llvm::GlobalValue::VisibilityTypes]. *)
module Visibility : sig
type t =
Default
| Hidden
| Protected
end
(** The following calling convention values may be accessed with
{!function_call_conv} and {!set_function_call_conv}. Calling
conventions are open-ended. *)
module CallConv : sig
val c : int (** [c] is the C calling convention. *)
val fast : int (** [fast] is the calling convention to allow LLVM
maximum optimization opportunities. Use only with
internal linkage. *)
val cold : int (** [cold] is the calling convention for
callee-save. *)
val x86_stdcall : int (** [x86_stdcall] is the familiar stdcall calling
convention from C. *)
val x86_fastcall : int (** [x86_fastcall] is the familiar fastcall calling
convention from C. *)
end
(** The attribute kind of a function parameter, result or the function itself.
See [llvm::Attribute::AttrKind]. *)
module Attribute : sig
type t =
| Zext
| Sext
| Noreturn
| Inreg
| Structret
| Nounwind
| Noalias
| Byval
| Nest
| Readnone
| Readonly
| Noinline
| Alwaysinline
| Optsize
| Ssp
| Sspreq
| Alignment of int
| Nocapture
| Noredzone
| Noimplicitfloat
| Naked
| Inlinehint
| Stackalignment of int
| ReturnsTwice
| UWTable
| NonLazyBind
end
(** The predicate for an integer comparison ([icmp]) instruction.
See the [llvm::ICmpInst::Predicate] enumeration. *)
module Icmp : sig
type t =
| Eq
| Ne
| Ugt
| Uge
| Ult
| Ule
| Sgt
| Sge
| Slt
| Sle
end
(** The predicate for a floating-point comparison ([fcmp]) instruction.
See the [llvm::FCmpInst::Predicate] enumeration. *)
module Fcmp : sig
type t =
| False
| Oeq
| Ogt
| Oge
| Olt
| Ole
| One
| Ord
| Uno
| Ueq
| Ugt
| Uge
| Ult
| Ule
| Une
| True
end
(** The opcodes for LLVM instructions and constant expressions. *)
module Opcode : sig
type t =
| Invalid (* not an instruction *)
(* Terminator Instructions *)
| Ret
| Br
| Switch
| IndirectBr
| Invoke
| Invalid2
| Unreachable
(* Standard Binary Operators *)
| Add
| FAdd
| Sub
| FSub
| Mul
| FMul
| UDiv
| SDiv
| FDiv
| URem
| SRem
| FRem
(* Logical Operators *)
| Shl
| LShr
| AShr
| And
| Or
| Xor
(* Memory Operators *)
| Alloca
| Load
| Store
| GetElementPtr
(* Cast Operators *)
| Trunc
| ZExt
| SExt
| FPToUI
| FPToSI
| UIToFP
| SIToFP
| FPTrunc
| FPExt
| PtrToInt
| IntToPtr
| BitCast
(* Other Operators *)
| ICmp
| FCmp
| PHI
| Call
| Select
| UserOp1
| UserOp2
| VAArg
| ExtractElement
| InsertElement
| ShuffleVector
| ExtractValue
| InsertValue
| Fence
| AtomicCmpXchg
| AtomicRMW
| Resume
| LandingPad
end
(** The type of a clause of a [landingpad] instruction.
See [llvm::LandingPadInst::ClauseType]. *)
module LandingPadClauseTy : sig
type t =
| Catch
| Filter
end
(** The thread local mode of a global value, accessed with {!thread_local_mode}
and {!set_thread_local_mode}.
See [llvm::GlobalVariable::ThreadLocalMode]. *)
module ThreadLocalMode : sig
type t =
| None
| GeneralDynamic
| LocalDynamic
| InitialExec
| LocalExec
end
(** The ordering of an atomic [load], [store], [cmpxchg], [atomicrmw] or
[fence] instruction. See [llvm::AtomicOrdering]. *)
module AtomicOrdering : sig
type t =
| NotAtomic
| Unordered
| Monotonic
| Invalid (* removed due to API changes *)
| Acquire
| Release
| AcqiureRelease
| SequentiallyConsistent
end
(** The opcode of an [atomicrmw] instruction.
See [llvm::AtomicRMWInst::BinOp]. *)
module AtomicRMWBinOp : sig
type t =
| Xchg
| Add
| Sub
| And
| Nand
| Or
| Xor
| Max
| Min
| UMax
| UMin
end
(** The kind of an [llvalue], the result of [classify_value v].
See the various [LLVMIsA*] functions. *)
module ValueKind : sig
type t =
| NullValue
| Argument
| BasicBlock
| InlineAsm
| MDNode
| MDString
| BlockAddress
| ConstantAggregateZero
| ConstantArray
| ConstantDataArray
| ConstantDataVector
| ConstantExpr
| ConstantFP
| ConstantInt
| ConstantPointerNull
| ConstantStruct
| ConstantVector
| Function
| GlobalAlias
| GlobalVariable
| UndefValue
| Instruction of Opcode.t
end
(** {6 Iteration} *)
(** [Before b] and [At_end a] specify positions from the start of the ['b] list
of [a]. [llpos] is used to specify positions in and for forward iteration
through the various value lists maintained by the LLVM IR. *)
type ('a, 'b) llpos =
| At_end of 'a
| Before of 'b
(** [After b] and [At_start a] specify positions from the end of the ['b] list
of [a]. [llrev_pos] is used for reverse iteration through the various value
lists maintained by the LLVM IR. *)
type ('a, 'b) llrev_pos =
| At_start of 'a
| After of 'b
(** {6 Exceptions} *)
exception IoError of string
(** {6 Global configuration} *)
(** [enable_pretty_stacktraces ()] enables LLVM's built-in stack trace code.
This intercepts the OS's crash signals and prints which component of LLVM
you were in at the time of the crash. *)
val enable_pretty_stacktrace : unit -> unit
(** [install_fatal_error_handler f] installs [f] as LLVM's fatal error handler.
The handler will receive the reason for termination as a string. After
the handler has been executed, LLVM calls [exit(1)]. *)
val install_fatal_error_handler : (string -> unit) -> unit
(** [reset_fatal_error_handler ()] resets LLVM's fatal error handler. *)
val reset_fatal_error_handler : unit -> unit
(** {6 Contexts} *)
(** [create_context ()] creates a context for storing the "global" state in
LLVM. See the constructor [llvm::LLVMContext]. *)
val create_context : unit -> llcontext
(** [destroy_context ()] destroys a context. See the destructor
[llvm::LLVMContext::~LLVMContext]. *)
val dispose_context : llcontext -> unit
(** See the function [llvm::getGlobalContext]. *)
val global_context : unit -> llcontext
(** [mdkind_id context name] returns the MDKind ID that corresponds to the
name [name] in the context [context]. See the function
[llvm::LLVMContext::getMDKindID]. *)
val mdkind_id : llcontext -> string -> int
(** {6 Modules} *)
(** [create_module context id] creates a module with the supplied module ID in
the context [context]. Modules are not garbage collected; it is mandatory
to call {!dispose_module} to free memory. See the constructor
[llvm::Module::Module]. *)
val create_module : llcontext -> string -> llmodule
(** [dispose_module m] destroys a module [m] and all of the IR objects it
contained. All references to subordinate objects are invalidated;
referencing them will invoke undefined behavior. See the destructor
[llvm::Module::~Module]. *)
val dispose_module : llmodule -> unit
(** [target_triple m] is the target specifier for the module [m], something like
[i686-apple-darwin8]. See the method [llvm::Module::getTargetTriple]. *)
val target_triple: llmodule -> string
(** [target_triple triple m] changes the target specifier for the module [m] to
the string [triple]. See the method [llvm::Module::setTargetTriple]. *)
val set_target_triple: string -> llmodule -> unit
(** [data_layout m] is the data layout specifier for the module [m], something
like [e-p:32:32:32-i1:8:8-i8:8:8-i16:16:16-...-a0:0:64-f80:128:128]. See the
method [llvm::Module::getDataLayout]. *)
val data_layout: llmodule -> string
(** [set_data_layout s m] changes the data layout specifier for the module [m]
to the string [s]. See the method [llvm::Module::setDataLayout]. *)
val set_data_layout: string -> llmodule -> unit
(** [dump_module m] prints the .ll representation of the module [m] to standard
error. See the method [llvm::Module::dump]. *)
val dump_module : llmodule -> unit
(** [print_module f m] prints the .ll representation of the module [m]
to file [f]. See the method [llvm::Module::print]. *)
val print_module : string -> llmodule -> unit
(** [string_of_llmodule m] returns the .ll representation of the module [m]
as a string. See the method [llvm::Module::print]. *)
val string_of_llmodule : llmodule -> string
(** [set_module_inline_asm m asm] sets the inline assembler for the module. See
the method [llvm::Module::setModuleInlineAsm]. *)
val set_module_inline_asm : llmodule -> string -> unit
(** [module_context m] returns the context of the specified module.
See the method [llvm::Module::getContext] *)
val module_context : llmodule -> llcontext
(** {6 Types} *)
(** [classify_type ty] returns the {!TypeKind.t} corresponding to the type [ty].
See the method [llvm::Type::getTypeID]. *)
val classify_type : lltype -> TypeKind.t
(** [type_is_sized ty] returns whether the type has a size or not.
If it doesn't then it is not safe to call the [DataLayout::] methods on it.
*)
val type_is_sized : lltype -> bool
(** [type_context ty] returns the {!llcontext} corresponding to the type [ty].
See the method [llvm::Type::getContext]. *)
val type_context : lltype -> llcontext
(** [dump_type ty] prints the .ll representation of the type [ty] to standard
error. See the method [llvm::Type::dump]. *)
val dump_type : lltype -> unit
(** [string_of_lltype ty] returns a string describing the type [ty]. *)
val string_of_lltype : lltype -> string
(** {7 Operations on integer types} *)
(** [i1_type c] returns an integer type of bitwidth 1 in the context [c]. See
[llvm::Type::Int1Ty]. *)
val i1_type : llcontext -> lltype
(** [i8_type c] returns an integer type of bitwidth 8 in the context [c]. See
[llvm::Type::Int8Ty]. *)
val i8_type : llcontext -> lltype
(** [i16_type c] returns an integer type of bitwidth 16 in the context [c]. See
[llvm::Type::Int16Ty]. *)
val i16_type : llcontext -> lltype
(** [i32_type c] returns an integer type of bitwidth 32 in the context [c]. See
[llvm::Type::Int32Ty]. *)
val i32_type : llcontext -> lltype
(** [i64_type c] returns an integer type of bitwidth 64 in the context [c]. See
[llvm::Type::Int64Ty]. *)
val i64_type : llcontext -> lltype
(** [integer_type c n] returns an integer type of bitwidth [n] in the context
[c]. See the method [llvm::IntegerType::get]. *)
val integer_type : llcontext -> int -> lltype
(** [integer_bitwidth c ty] returns the number of bits in the integer type [ty]
in the context [c]. See the method [llvm::IntegerType::getBitWidth]. *)
val integer_bitwidth : lltype -> int
(** {7 Operations on real types} *)
(** [float_type c] returns the IEEE 32-bit floating point type in the context
[c]. See [llvm::Type::FloatTy]. *)
val float_type : llcontext -> lltype
(** [double_type c] returns the IEEE 64-bit floating point type in the context
[c]. See [llvm::Type::DoubleTy]. *)
val double_type : llcontext -> lltype
(** [x86fp80_type c] returns the x87 80-bit floating point type in the context
[c]. See [llvm::Type::X86_FP80Ty]. *)
val x86fp80_type : llcontext -> lltype
(** [fp128_type c] returns the IEEE 128-bit floating point type in the context
[c]. See [llvm::Type::FP128Ty]. *)
val fp128_type : llcontext -> lltype
(** [ppc_fp128_type c] returns the PowerPC 128-bit floating point type in the
context [c]. See [llvm::Type::PPC_FP128Ty]. *)
val ppc_fp128_type : llcontext -> lltype
(** {7 Operations on function types} *)
(** [function_type ret_ty param_tys] returns the function type returning
[ret_ty] and taking [param_tys] as parameters.
See the method [llvm::FunctionType::get]. *)
val function_type : lltype -> lltype array -> lltype
(** [var_arg_function_type ret_ty param_tys] is just like
[function_type ret_ty param_tys] except that it returns the function type
which also takes a variable number of arguments.
See the method [llvm::FunctionType::get]. *)
val var_arg_function_type : lltype -> lltype array -> lltype
(** [is_var_arg fty] returns [true] if [fty] is a varargs function type, [false]
otherwise. See the method [llvm::FunctionType::isVarArg]. *)
val is_var_arg : lltype -> bool
(** [return_type fty] gets the return type of the function type [fty].
See the method [llvm::FunctionType::getReturnType]. *)
val return_type : lltype -> lltype
(** [param_types fty] gets the parameter types of the function type [fty].
See the method [llvm::FunctionType::getParamType]. *)
val param_types : lltype -> lltype array
(** {7 Operations on struct types} *)
(** [struct_type context tys] returns the structure type in the context
[context] containing in the types in the array [tys]. See the method
[llvm::StructType::get]. *)
val struct_type : llcontext -> lltype array -> lltype
(** [packed_struct_type context ys] returns the packed structure type in the
context [context] containing in the types in the array [tys]. See the method
[llvm::StructType::get]. *)
val packed_struct_type : llcontext -> lltype array -> lltype
(** [struct_name ty] returns the name of the named structure type [ty],
or None if the structure type is not named *)
val struct_name : lltype -> string option
(** [named_struct_type context name] returns the named structure type [name]
in the context [context].
See the method [llvm::StructType::get]. *)
val named_struct_type : llcontext -> string -> lltype
(** [struct_set_body ty elts ispacked] sets the body of the named struct [ty]
to the [elts] elements.
See the moethd [llvm::StructType::setBody]. *)
val struct_set_body : lltype -> lltype array -> bool -> unit
(** [struct_element_types sty] returns the constituent types of the struct type
[sty]. See the method [llvm::StructType::getElementType]. *)
val struct_element_types : lltype -> lltype array
(** [is_packed sty] returns [true] if the structure type [sty] is packed,
[false] otherwise. See the method [llvm::StructType::isPacked]. *)
val is_packed : lltype -> bool
(** [is_opaque sty] returns [true] if the structure type [sty] is opaque.
[false] otherwise. See the method [llvm::StructType::isOpaque]. *)
val is_opaque : lltype -> bool
(** {7 Operations on pointer, vector, and array types} *)
(** [array_type ty n] returns the array type containing [n] elements of type
[ty]. See the method [llvm::ArrayType::get]. *)
val array_type : lltype -> int -> lltype
(** [pointer_type ty] returns the pointer type referencing objects of type
[ty] in the default address space (0).
See the method [llvm::PointerType::getUnqual]. *)
val pointer_type : lltype -> lltype
(** [qualified_pointer_type ty as] returns the pointer type referencing objects
of type [ty] in address space [as].
See the method [llvm::PointerType::get]. *)
val qualified_pointer_type : lltype -> int -> lltype
(** [vector_type ty n] returns the array type containing [n] elements of the
primitive type [ty]. See the method [llvm::ArrayType::get]. *)
val vector_type : lltype -> int -> lltype
(** [element_type ty] returns the element type of the pointer, vector, or array
type [ty]. See the method [llvm::SequentialType::get]. *)
val element_type : lltype -> lltype
(** [element_type aty] returns the element count of the array type [aty].
See the method [llvm::ArrayType::getNumElements]. *)
val array_length : lltype -> int
(** [address_space pty] returns the address space qualifier of the pointer type
[pty]. See the method [llvm::PointerType::getAddressSpace]. *)
val address_space : lltype -> int
(** [element_type ty] returns the element count of the vector type [ty].
See the method [llvm::VectorType::getNumElements]. *)
val vector_size : lltype -> int
(** {7 Operations on other types} *)
(** [void_type c] creates a type of a function which does not return any
value in the context [c]. See [llvm::Type::VoidTy]. *)
val void_type : llcontext -> lltype
(** [label_type c] creates a type of a basic block in the context [c]. See
[llvm::Type::LabelTy]. *)
val label_type : llcontext -> lltype
(** [x86_mmx_type c] returns the x86 64-bit MMX register type in the
context [c]. See [llvm::Type::X86_MMXTy]. *)
val x86_mmx_type : llcontext -> lltype
(** [type_by_name m name] returns the specified type from the current module
if it exists.
See the method [llvm::Module::getTypeByName] *)
val type_by_name : llmodule -> string -> lltype option
(* {6 Values} *)
(** [type_of v] returns the type of the value [v].
See the method [llvm::Value::getType]. *)
val type_of : llvalue -> lltype
(** [classify_value v] returns the kind of the value [v]. *)
val classify_value : llvalue -> ValueKind.t
(** [value_name v] returns the name of the value [v]. For global values, this is
the symbol name. For instructions and basic blocks, it is the SSA register
name. It is meaningless for constants.
See the method [llvm::Value::getName]. *)
val value_name : llvalue -> string
(** [set_value_name n v] sets the name of the value [v] to [n]. See the method
[llvm::Value::setName]. *)
val set_value_name : string -> llvalue -> unit
(** [dump_value v] prints the .ll representation of the value [v] to standard
error. See the method [llvm::Value::dump]. *)
val dump_value : llvalue -> unit
(** [string_of_llvalue v] returns a string describing the value [v]. *)
val string_of_llvalue : llvalue -> string
(** [replace_all_uses_with old new] replaces all uses of the value [old]
with the value [new]. See the method [llvm::Value::replaceAllUsesWith]. *)
val replace_all_uses_with : llvalue -> llvalue -> unit
(* {6 Uses} *)
(** [use_begin v] returns the first position in the use list for the value [v].
[use_begin] and [use_succ] can e used to iterate over the use list in order.
See the method [llvm::Value::use_begin]. *)
val use_begin : llvalue -> lluse option
(** [use_succ u] returns the use list position succeeding [u].
See the method [llvm::use_value_iterator::operator++]. *)
val use_succ : lluse -> lluse option
(** [user u] returns the user of the use [u].
See the method [llvm::Use::getUser]. *)
val user : lluse -> llvalue
(** [used_value u] returns the usee of the use [u].
See the method [llvm::Use::getUsedValue]. *)
val used_value : lluse -> llvalue
(** [iter_uses f v] applies function [f] to each of the users of the value [v]
in order. Tail recursive. *)
val iter_uses : (lluse -> unit) -> llvalue -> unit
(** [fold_left_uses f init v] is [f (... (f init u1) ...) uN] where
[u1,...,uN] are the users of the value [v]. Tail recursive. *)
val fold_left_uses : ('a -> lluse -> 'a) -> 'a -> llvalue -> 'a
(** [fold_right_uses f v init] is [f u1 (... (f uN init) ...)] where
[u1,...,uN] are the users of the value [v]. Not tail recursive. *)
val fold_right_uses : (lluse -> 'a -> 'a) -> llvalue -> 'a -> 'a
(* {6 Users} *)
(** [operand v i] returns the operand at index [i] for the value [v]. See the
method [llvm::User::getOperand]. *)
val operand : llvalue -> int -> llvalue
(** [set_operand v i o] sets the operand of the value [v] at the index [i] to
the value [o].
See the method [llvm::User::setOperand]. *)
val set_operand : llvalue -> int -> llvalue -> unit
(** [num_operands v] returns the number of operands for the value [v].
See the method [llvm::User::getNumOperands]. *)
val num_operands : llvalue -> int
(** {7 Operations on constants of (mostly) any type} *)
(** [is_constant v] returns [true] if the value [v] is a constant, [false]
otherwise. Similar to [llvm::isa<Constant>]. *)
val is_constant : llvalue -> bool
(** [const_null ty] returns the constant null (zero) of the type [ty].
See the method [llvm::Constant::getNullValue]. *)
val const_null : lltype -> llvalue
(** [const_all_ones ty] returns the constant '-1' of the integer or vector type
[ty]. See the method [llvm::Constant::getAllOnesValue]. *)
val const_all_ones : (*int|vec*)lltype -> llvalue
(** [const_pointer_null ty] returns the constant null (zero) pointer of the type
[ty]. See the method [llvm::ConstantPointerNull::get]. *)
val const_pointer_null : lltype -> llvalue
(** [undef ty] returns the undefined value of the type [ty].
See the method [llvm::UndefValue::get]. *)
val undef : lltype -> llvalue
(** [is_null v] returns [true] if the value [v] is the null (zero) value.
See the method [llvm::Constant::isNullValue]. *)
val is_null : llvalue -> bool
(** [is_undef v] returns [true] if the value [v] is an undefined value, [false]
otherwise. Similar to [llvm::isa<UndefValue>]. *)
val is_undef : llvalue -> bool
(** [constexpr_opcode v] returns an [Opcode.t] corresponding to constexpr
value [v], or [Opcode.Invalid] if [v] is not a constexpr. *)
val constexpr_opcode : llvalue -> Opcode.t
(** {7 Operations on instructions} *)
(** [has_metadata i] returns whether or not the instruction [i] has any
metadata attached to it. See the function
[llvm::Instruction::hasMetadata]. *)
val has_metadata : llvalue -> bool
(** [metadata i kind] optionally returns the metadata associated with the
kind [kind] in the instruction [i] See the function
[llvm::Instruction::getMetadata]. *)
val metadata : llvalue -> llmdkind -> llvalue option
(** [set_metadata i kind md] sets the metadata [md] of kind [kind] in the
instruction [i]. See the function [llvm::Instruction::setMetadata]. *)
val set_metadata : llvalue -> llmdkind -> llvalue -> unit
(** [clear_metadata i kind] clears the metadata of kind [kind] in the
instruction [i]. See the function [llvm::Instruction::setMetadata]. *)
val clear_metadata : llvalue -> llmdkind -> unit
(** {7 Operations on metadata} *)
(** [mdstring c s] returns the MDString of the string [s] in the context [c].
See the method [llvm::MDNode::get]. *)
val mdstring : llcontext -> string -> llvalue
(** [mdnode c elts] returns the MDNode containing the values [elts] in the
context [c].
See the method [llvm::MDNode::get]. *)
val mdnode : llcontext -> llvalue array -> llvalue
(** [get_mdstring v] returns the MDString.
See the method [llvm::MDString::getString] *)
val get_mdstring : llvalue -> string option
(** [get_named_metadata m name] returns all the MDNodes belonging to the named
metadata (if any).
See the method [llvm::NamedMDNode::getOperand]. *)
val get_named_metadata : llmodule -> string -> llvalue array
(** [add_named_metadata_operand m name v] adds [v] as the last operand of
metadata named [name] in module [m]. If the metadata does not exist,
it is created.
See the methods [llvm::Module::getNamedMetadata()] and
[llvm::MDNode::addOperand()]. *)
val add_named_metadata_operand : llmodule -> string -> llvalue -> unit
(** {7 Operations on scalar constants} *)
(** [const_int ty i] returns the integer constant of type [ty] and value [i].
See the method [llvm::ConstantInt::get]. *)
val const_int : lltype -> int -> llvalue
(** [const_of_int64 ty i] returns the integer constant of type [ty] and value
[i]. See the method [llvm::ConstantInt::get]. *)
val const_of_int64 : lltype -> Int64.t -> bool -> llvalue
(** [int64_of_const c] returns the int64 value of the [c] constant integer.
None is returned if this is not an integer constant, or bitwidth exceeds 64.
See the method [llvm::ConstantInt::getSExtValue].*)
val int64_of_const : llvalue -> Int64.t option
(** [const_int_of_string ty s r] returns the integer constant of type [ty] and
value [s], with the radix [r]. See the method [llvm::ConstantInt::get]. *)
val const_int_of_string : lltype -> string -> int -> llvalue
(** [const_float ty n] returns the floating point constant of type [ty] and
value [n]. See the method [llvm::ConstantFP::get]. *)
val const_float : lltype -> float -> llvalue
(** [const_float_of_string ty s] returns the floating point constant of type
[ty] and value [n]. See the method [llvm::ConstantFP::get]. *)
val const_float_of_string : lltype -> string -> llvalue
(** {7 Operations on composite constants} *)
(** [const_string c s] returns the constant [i8] array with the values of the
characters in the string [s] in the context [c]. The array is not
null-terminated (but see {!const_stringz}). This value can in turn be used
as the initializer for a global variable. See the method
[llvm::ConstantArray::get]. *)
val const_string : llcontext -> string -> llvalue
(** [const_stringz c s] returns the constant [i8] array with the values of the
characters in the string [s] and a null terminator in the context [c]. This
value can in turn be used as the initializer for a global variable.
See the method [llvm::ConstantArray::get]. *)
val const_stringz : llcontext -> string -> llvalue
(** [const_array ty elts] returns the constant array of type
[array_type ty (Array.length elts)] and containing the values [elts].
This value can in turn be used as the initializer for a global variable.
See the method [llvm::ConstantArray::get]. *)
val const_array : lltype -> llvalue array -> llvalue
(** [const_struct context elts] returns the structured constant of type
[struct_type (Array.map type_of elts)] and containing the values [elts]
in the context [context]. This value can in turn be used as the initializer
for a global variable. See the method [llvm::ConstantStruct::getAnon]. *)
val const_struct : llcontext -> llvalue array -> llvalue
(** [const_named_struct namedty elts] returns the structured constant of type
[namedty] (which must be a named structure type) and containing the values [elts].
This value can in turn be used as the initializer
for a global variable. See the method [llvm::ConstantStruct::get]. *)
val const_named_struct : lltype -> llvalue array -> llvalue
(** [const_packed_struct context elts] returns the structured constant of
type {!packed_struct_type} [(Array.map type_of elts)] and containing the
values [elts] in the context [context]. This value can in turn be used as
the initializer for a global variable. See the method
[llvm::ConstantStruct::get]. *)
val const_packed_struct : llcontext -> llvalue array -> llvalue
(** [const_vector elts] returns the vector constant of type
[vector_type (type_of elts.(0)) (Array.length elts)] and containing the
values [elts]. See the method [llvm::ConstantVector::get]. *)
val const_vector : llvalue array -> llvalue
(** {7 Constant expressions} *)
(** [align_of ty] returns the alignof constant for the type [ty]. This is
equivalent to [const_ptrtoint (const_gep (const_null (pointer_type {i8,ty}))
(const_int i32_type 0) (const_int i32_type 1)) i32_type], but considerably
more readable. See the method [llvm::ConstantExpr::getAlignOf]. *)
val align_of : lltype -> llvalue
(** [size_of ty] returns the sizeof constant for the type [ty]. This is
equivalent to [const_ptrtoint (const_gep (const_null (pointer_type ty))
(const_int i32_type 1)) i64_type], but considerably more readable.
See the method [llvm::ConstantExpr::getSizeOf]. *)
val size_of : lltype -> llvalue
(** [const_neg c] returns the arithmetic negation of the constant [c].
See the method [llvm::ConstantExpr::getNeg]. *)
val const_neg : llvalue -> llvalue
(** [const_nsw_neg c] returns the arithmetic negation of the constant [c] with
no signed wrapping. The result is undefined if the negation overflows.
See the method [llvm::ConstantExpr::getNSWNeg]. *)
val const_nsw_neg : llvalue -> llvalue
(** [const_nuw_neg c] returns the arithmetic negation of the constant [c] with
no unsigned wrapping. The result is undefined if the negation overflows.
See the method [llvm::ConstantExpr::getNUWNeg]. *)
val const_nuw_neg : llvalue -> llvalue
(** [const_fneg c] returns the arithmetic negation of the constant float [c].
See the method [llvm::ConstantExpr::getFNeg]. *)
val const_fneg : llvalue -> llvalue
(** [const_not c] returns the bitwise inverse of the constant [c].
See the method [llvm::ConstantExpr::getNot]. *)
val const_not : llvalue -> llvalue
(** [const_add c1 c2] returns the constant sum of two constants.
See the method [llvm::ConstantExpr::getAdd]. *)
val const_add : llvalue -> llvalue -> llvalue
(** [const_nsw_add c1 c2] returns the constant sum of two constants with no
signed wrapping. The result is undefined if the sum overflows.
See the method [llvm::ConstantExpr::getNSWAdd]. *)
val const_nsw_add : llvalue -> llvalue -> llvalue
(** [const_nuw_add c1 c2] returns the constant sum of two constants with no
unsigned wrapping. The result is undefined if the sum overflows.
See the method [llvm::ConstantExpr::getNSWAdd]. *)
val const_nuw_add : llvalue -> llvalue -> llvalue
(** [const_fadd c1 c2] returns the constant sum of two constant floats.
See the method [llvm::ConstantExpr::getFAdd]. *)
val const_fadd : llvalue -> llvalue -> llvalue
(** [const_sub c1 c2] returns the constant difference, [c1 - c2], of two
constants. See the method [llvm::ConstantExpr::getSub]. *)
val const_sub : llvalue -> llvalue -> llvalue
(** [const_nsw_sub c1 c2] returns the constant difference of two constants with
no signed wrapping. The result is undefined if the sum overflows.
See the method [llvm::ConstantExpr::getNSWSub]. *)
val const_nsw_sub : llvalue -> llvalue -> llvalue
(** [const_nuw_sub c1 c2] returns the constant difference of two constants with
no unsigned wrapping. The result is undefined if the sum overflows.
See the method [llvm::ConstantExpr::getNSWSub]. *)
val const_nuw_sub : llvalue -> llvalue -> llvalue
(** [const_fsub c1 c2] returns the constant difference, [c1 - c2], of two
constant floats. See the method [llvm::ConstantExpr::getFSub]. *)
val const_fsub : llvalue -> llvalue -> llvalue
(** [const_mul c1 c2] returns the constant product of two constants.
See the method [llvm::ConstantExpr::getMul]. *)
val const_mul : llvalue -> llvalue -> llvalue
(** [const_nsw_mul c1 c2] returns the constant product of two constants with
no signed wrapping. The result is undefined if the sum overflows.
See the method [llvm::ConstantExpr::getNSWMul]. *)
val const_nsw_mul : llvalue -> llvalue -> llvalue
(** [const_nuw_mul c1 c2] returns the constant product of two constants with
no unsigned wrapping. The result is undefined if the sum overflows.
See the method [llvm::ConstantExpr::getNSWMul]. *)
val const_nuw_mul : llvalue -> llvalue -> llvalue
(** [const_fmul c1 c2] returns the constant product of two constants floats.
See the method [llvm::ConstantExpr::getFMul]. *)
val const_fmul : llvalue -> llvalue -> llvalue
(** [const_udiv c1 c2] returns the constant quotient [c1 / c2] of two unsigned
integer constants.
See the method [llvm::ConstantExpr::getUDiv]. *)
val const_udiv : llvalue -> llvalue -> llvalue
(** [const_sdiv c1 c2] returns the constant quotient [c1 / c2] of two signed
integer constants.
See the method [llvm::ConstantExpr::getSDiv]. *)
val const_sdiv : llvalue -> llvalue -> llvalue
(** [const_exact_sdiv c1 c2] returns the constant quotient [c1 / c2] of two
signed integer constants. The result is undefined if the result is rounded
or overflows. See the method [llvm::ConstantExpr::getExactSDiv]. *)
val const_exact_sdiv : llvalue -> llvalue -> llvalue
(** [const_fdiv c1 c2] returns the constant quotient [c1 / c2] of two floating
point constants.
See the method [llvm::ConstantExpr::getFDiv]. *)
val const_fdiv : llvalue -> llvalue -> llvalue
(** [const_urem c1 c2] returns the constant remainder [c1 MOD c2] of two
unsigned integer constants.
See the method [llvm::ConstantExpr::getURem]. *)
val const_urem : llvalue -> llvalue -> llvalue
(** [const_srem c1 c2] returns the constant remainder [c1 MOD c2] of two
signed integer constants.
See the method [llvm::ConstantExpr::getSRem]. *)
val const_srem : llvalue -> llvalue -> llvalue
(** [const_frem c1 c2] returns the constant remainder [c1 MOD c2] of two
signed floating point constants.
See the method [llvm::ConstantExpr::getFRem]. *)
val const_frem : llvalue -> llvalue -> llvalue
(** [const_and c1 c2] returns the constant bitwise [AND] of two integer
constants.
See the method [llvm::ConstantExpr::getAnd]. *)
val const_and : llvalue -> llvalue -> llvalue
(** [const_or c1 c2] returns the constant bitwise [OR] of two integer
constants.
See the method [llvm::ConstantExpr::getOr]. *)
val const_or : llvalue -> llvalue -> llvalue
(** [const_xor c1 c2] returns the constant bitwise [XOR] of two integer
constants.
See the method [llvm::ConstantExpr::getXor]. *)
val const_xor : llvalue -> llvalue -> llvalue
(** [const_icmp pred c1 c2] returns the constant comparison of two integer
constants, [c1 pred c2].
See the method [llvm::ConstantExpr::getICmp]. *)
val const_icmp : Icmp.t -> llvalue -> llvalue -> llvalue
(** [const_fcmp pred c1 c2] returns the constant comparison of two floating
point constants, [c1 pred c2].
See the method [llvm::ConstantExpr::getFCmp]. *)
val const_fcmp : Fcmp.t -> llvalue -> llvalue -> llvalue
(** [const_shl c1 c2] returns the constant integer [c1] left-shifted by the
constant integer [c2].
See the method [llvm::ConstantExpr::getShl]. *)
val const_shl : llvalue -> llvalue -> llvalue
(** [const_lshr c1 c2] returns the constant integer [c1] right-shifted by the
constant integer [c2] with zero extension.
See the method [llvm::ConstantExpr::getLShr]. *)
val const_lshr : llvalue -> llvalue -> llvalue
(** [const_ashr c1 c2] returns the constant integer [c1] right-shifted by the
constant integer [c2] with sign extension.
See the method [llvm::ConstantExpr::getAShr]. *)
val const_ashr : llvalue -> llvalue -> llvalue
(** [const_gep pc indices] returns the constant [getElementPtr] of [p1] with the
constant integers indices from the array [indices].
See the method [llvm::ConstantExpr::getGetElementPtr]. *)
val const_gep : llvalue -> llvalue array -> llvalue
(** [const_in_bounds_gep pc indices] returns the constant [getElementPtr] of [p1]
with the constant integers indices from the array [indices].
See the method [llvm::ConstantExpr::getInBoundsGetElementPtr]. *)
val const_in_bounds_gep : llvalue -> llvalue array -> llvalue
(** [const_trunc c ty] returns the constant truncation of integer constant [c]
to the smaller integer type [ty].
See the method [llvm::ConstantExpr::getTrunc]. *)
val const_trunc : llvalue -> lltype -> llvalue
(** [const_sext c ty] returns the constant sign extension of integer constant
[c] to the larger integer type [ty].
See the method [llvm::ConstantExpr::getSExt]. *)
val const_sext : llvalue -> lltype -> llvalue
(** [const_zext c ty] returns the constant zero extension of integer constant
[c] to the larger integer type [ty].
See the method [llvm::ConstantExpr::getZExt]. *)
val const_zext : llvalue -> lltype -> llvalue
(** [const_fptrunc c ty] returns the constant truncation of floating point
constant [c] to the smaller floating point type [ty].
See the method [llvm::ConstantExpr::getFPTrunc]. *)
val const_fptrunc : llvalue -> lltype -> llvalue
(** [const_fpext c ty] returns the constant extension of floating point constant
[c] to the larger floating point type [ty].
See the method [llvm::ConstantExpr::getFPExt]. *)
val const_fpext : llvalue -> lltype -> llvalue
(** [const_uitofp c ty] returns the constant floating point conversion of
unsigned integer constant [c] to the floating point type [ty].
See the method [llvm::ConstantExpr::getUIToFP]. *)
val const_uitofp : llvalue -> lltype -> llvalue
(** [const_sitofp c ty] returns the constant floating point conversion of
signed integer constant [c] to the floating point type [ty].
See the method [llvm::ConstantExpr::getSIToFP]. *)
val const_sitofp : llvalue -> lltype -> llvalue
(** [const_fptoui c ty] returns the constant unsigned integer conversion of
floating point constant [c] to integer type [ty].
See the method [llvm::ConstantExpr::getFPToUI]. *)
val const_fptoui : llvalue -> lltype -> llvalue
(** [const_fptoui c ty] returns the constant unsigned integer conversion of
floating point constant [c] to integer type [ty].
See the method [llvm::ConstantExpr::getFPToSI]. *)
val const_fptosi : llvalue -> lltype -> llvalue
(** [const_ptrtoint c ty] returns the constant integer conversion of
pointer constant [c] to integer type [ty].
See the method [llvm::ConstantExpr::getPtrToInt]. *)
val const_ptrtoint : llvalue -> lltype -> llvalue
(** [const_inttoptr c ty] returns the constant pointer conversion of
integer constant [c] to pointer type [ty].
See the method [llvm::ConstantExpr::getIntToPtr]. *)
val const_inttoptr : llvalue -> lltype -> llvalue
(** [const_bitcast c ty] returns the constant bitwise conversion of constant [c]
to type [ty] of equal size.
See the method [llvm::ConstantExpr::getBitCast]. *)
val const_bitcast : llvalue -> lltype -> llvalue
(** [const_zext_or_bitcast c ty] returns a constant zext or bitwise cast
conversion of constant [c] to type [ty].
See the method [llvm::ConstantExpr::getZExtOrBitCast]. *)
val const_zext_or_bitcast : llvalue -> lltype -> llvalue
(** [const_sext_or_bitcast c ty] returns a constant sext or bitwise cast
conversion of constant [c] to type [ty].
See the method [llvm::ConstantExpr::getSExtOrBitCast]. *)
val const_sext_or_bitcast : llvalue -> lltype -> llvalue
(** [const_trunc_or_bitcast c ty] returns a constant trunc or bitwise cast
conversion of constant [c] to type [ty].
See the method [llvm::ConstantExpr::getTruncOrBitCast]. *)
val const_trunc_or_bitcast : llvalue -> lltype -> llvalue
(** [const_pointercast c ty] returns a constant bitcast or a pointer-to-int
cast conversion of constant [c] to type [ty] of equal size.
See the method [llvm::ConstantExpr::getPointerCast]. *)
val const_pointercast : llvalue -> lltype -> llvalue
(** [const_intcast c ty ~is_signed] returns a constant sext/zext, bitcast,
or trunc for integer -> integer casts of constant [c] to type [ty].
When converting a narrower value to a wider one, whether sext or zext
will be used is controlled by [is_signed].
See the method [llvm::ConstantExpr::getIntegerCast]. *)
val const_intcast : llvalue -> lltype -> is_signed:bool -> llvalue
(** [const_fpcast c ty] returns a constant fpext, bitcast, or fptrunc for fp ->
fp casts of constant [c] to type [ty].
See the method [llvm::ConstantExpr::getFPCast]. *)
val const_fpcast : llvalue -> lltype -> llvalue
(** [const_select cond t f] returns the constant conditional which returns value
[t] if the boolean constant [cond] is true and the value [f] otherwise.
See the method [llvm::ConstantExpr::getSelect]. *)
val const_select : llvalue -> llvalue -> llvalue -> llvalue
(** [const_extractelement vec i] returns the constant [i]th element of
constant vector [vec]. [i] must be a constant [i32] value unsigned less than
the size of the vector.
See the method [llvm::ConstantExpr::getExtractElement]. *)
val const_extractelement : llvalue -> llvalue -> llvalue
(** [const_insertelement vec v i] returns the constant vector with the same
elements as constant vector [v] but the [i]th element replaced by the
constant [v]. [v] must be a constant value with the type of the vector
elements. [i] must be a constant [i32] value unsigned less than the size
of the vector.
See the method [llvm::ConstantExpr::getInsertElement]. *)
val const_insertelement : llvalue -> llvalue -> llvalue -> llvalue
(** [const_shufflevector a b mask] returns a constant [shufflevector].
See the LLVM Language Reference for details on the [shufflevector]
instruction.
See the method [llvm::ConstantExpr::getShuffleVector]. *)
val const_shufflevector : llvalue -> llvalue -> llvalue -> llvalue
(** [const_extractvalue agg idxs] returns the constant [idxs]th value of
constant aggregate [agg]. Each [idxs] must be less than the size of the
aggregate. See the method [llvm::ConstantExpr::getExtractValue]. *)
val const_extractvalue : llvalue -> int array -> llvalue
(** [const_insertvalue agg val idxs] inserts the value [val] in the specified
indexs [idxs] in the aggegate [agg]. Each [idxs] must be less than the size
of the aggregate. See the method [llvm::ConstantExpr::getInsertValue]. *)
val const_insertvalue : llvalue -> llvalue -> int array -> llvalue
(** [const_inline_asm ty asm con side align] inserts a inline assembly string.
See the method [llvm::InlineAsm::get]. *)
val const_inline_asm : lltype -> string -> string -> bool -> bool -> llvalue
(** [block_address f bb] returns the address of the basic block [bb] in the
function [f]. See the method [llvm::BasicBlock::get]. *)
val block_address : llvalue -> llbasicblock -> llvalue
(** {7 Operations on global variables, functions, and aliases (globals)} *)
(** [global_parent g] is the enclosing module of the global value [g].
See the method [llvm::GlobalValue::getParent]. *)
val global_parent : llvalue -> llmodule
(** [is_declaration g] returns [true] if the global value [g] is a declaration
only. Returns [false] otherwise.
See the method [llvm::GlobalValue::isDeclaration]. *)
val is_declaration : llvalue -> bool
(** [linkage g] returns the linkage of the global value [g].
See the method [llvm::GlobalValue::getLinkage]. *)
val linkage : llvalue -> Linkage.t
(** [set_linkage l g] sets the linkage of the global value [g] to [l].
See the method [llvm::GlobalValue::setLinkage]. *)
val set_linkage : Linkage.t -> llvalue -> unit
(** [section g] returns the linker section of the global value [g].
See the method [llvm::GlobalValue::getSection]. *)
val section : llvalue -> string
(** [set_section s g] sets the linker section of the global value [g] to [s].
See the method [llvm::GlobalValue::setSection]. *)
val set_section : string -> llvalue -> unit
(** [visibility g] returns the linker visibility of the global value [g].
See the method [llvm::GlobalValue::getVisibility]. *)
val visibility : llvalue -> Visibility.t
(** [set_visibility v g] sets the linker visibility of the global value [g] to
[v]. See the method [llvm::GlobalValue::setVisibility]. *)
val set_visibility : Visibility.t -> llvalue -> unit
(** [alignment g] returns the required alignment of the global value [g].
See the method [llvm::GlobalValue::getAlignment]. *)
val alignment : llvalue -> int
(** [set_alignment n g] sets the required alignment of the global value [g] to
[n] bytes. See the method [llvm::GlobalValue::setAlignment]. *)
val set_alignment : int -> llvalue -> unit
(** {7 Operations on global variables} *)
(** [declare_global ty name m] returns a new global variable of type [ty] and
with name [name] in module [m] in the default address space (0). If such a
global variable already exists, it is returned. If the type of the existing
global differs, then a bitcast to [ty] is returned. *)
val declare_global : lltype -> string -> llmodule -> llvalue
(** [declare_qualified_global ty name addrspace m] returns a new global variable
of type [ty] and with name [name] in module [m] in the address space
[addrspace]. If such a global variable already exists, it is returned. If
the type of the existing global differs, then a bitcast to [ty] is
returned. *)
val declare_qualified_global : lltype -> string -> int -> llmodule -> llvalue
(** [define_global name init m] returns a new global with name [name] and
initializer [init] in module [m] in the default address space (0). If the
named global already exists, it is renamed.
See the constructor of [llvm::GlobalVariable]. *)
val define_global : string -> llvalue -> llmodule -> llvalue
(** [define_qualified_global name init addrspace m] returns a new global with
name [name] and initializer [init] in module [m] in the address space
[addrspace]. If the named global already exists, it is renamed.
See the constructor of [llvm::GlobalVariable]. *)
val define_qualified_global : string -> llvalue -> int -> llmodule -> llvalue
(** [lookup_global name m] returns [Some g] if a global variable with name
[name] exists in module [m]. If no such global exists, returns [None].
See the [llvm::GlobalVariable] constructor. *)
val lookup_global : string -> llmodule -> llvalue option
(** [delete_global gv] destroys the global variable [gv].
See the method [llvm::GlobalVariable::eraseFromParent]. *)
val delete_global : llvalue -> unit
(** [global_begin m] returns the first position in the global variable list of
the module [m]. [global_begin] and [global_succ] can be used to iterate
over the global list in order.
See the method [llvm::Module::global_begin]. *)
val global_begin : llmodule -> (llmodule, llvalue) llpos
(** [global_succ gv] returns the global variable list position succeeding
[Before gv].
See the method [llvm::Module::global_iterator::operator++]. *)
val global_succ : llvalue -> (llmodule, llvalue) llpos
(** [iter_globals f m] applies function [f] to each of the global variables of
module [m] in order. Tail recursive. *)
val iter_globals : (llvalue -> unit) -> llmodule -> unit
(** [fold_left_globals f init m] is [f (... (f init g1) ...) gN] where
[g1,...,gN] are the global variables of module [m]. Tail recursive. *)
val fold_left_globals : ('a -> llvalue -> 'a) -> 'a -> llmodule -> 'a
(** [global_end m] returns the last position in the global variable list of the
module [m]. [global_end] and [global_pred] can be used to iterate over the
global list in reverse.
See the method [llvm::Module::global_end]. *)
val global_end : llmodule -> (llmodule, llvalue) llrev_pos
(** [global_pred gv] returns the global variable list position preceding
[After gv].
See the method [llvm::Module::global_iterator::operator--]. *)
val global_pred : llvalue -> (llmodule, llvalue) llrev_pos
(** [rev_iter_globals f m] applies function [f] to each of the global variables
of module [m] in reverse order. Tail recursive. *)
val rev_iter_globals : (llvalue -> unit) -> llmodule -> unit
(** [fold_right_globals f m init] is [f g1 (... (f gN init) ...)] where
[g1,...,gN] are the global variables of module [m]. Tail recursive. *)
val fold_right_globals : (llvalue -> 'a -> 'a) -> llmodule -> 'a -> 'a
(** [is_global_constant gv] returns [true] if the global variabile [gv] is a
constant. Returns [false] otherwise.
See the method [llvm::GlobalVariable::isConstant]. *)
val is_global_constant : llvalue -> bool
(** [set_global_constant c gv] sets the global variable [gv] to be a constant if
[c] is [true] and not if [c] is [false].
See the method [llvm::GlobalVariable::setConstant]. *)
val set_global_constant : bool -> llvalue -> unit
(** [global_initializer gv] returns the initializer for the global variable
[gv]. See the method [llvm::GlobalVariable::getInitializer]. *)
val global_initializer : llvalue -> llvalue
(** [set_initializer c gv] sets the initializer for the global variable
[gv] to the constant [c].
See the method [llvm::GlobalVariable::setInitializer]. *)
val set_initializer : llvalue -> llvalue -> unit
(** [remove_initializer gv] unsets the initializer for the global variable
[gv].
See the method [llvm::GlobalVariable::setInitializer]. *)
val remove_initializer : llvalue -> unit
(** [is_thread_local gv] returns [true] if the global variable [gv] is
thread-local and [false] otherwise.
See the method [llvm::GlobalVariable::isThreadLocal]. *)
val is_thread_local : llvalue -> bool
(** [set_thread_local c gv] sets the global variable [gv] to be thread local if
[c] is [true] and not otherwise.
See the method [llvm::GlobalVariable::setThreadLocal]. *)
val set_thread_local : bool -> llvalue -> unit
(** [is_thread_local gv] returns the thread local mode of the global
variable [gv].
See the method [llvm::GlobalVariable::getThreadLocalMode]. *)
val thread_local_mode : llvalue -> ThreadLocalMode.t
(** [set_thread_local c gv] sets the thread local mode of the global
variable [gv].
See the method [llvm::GlobalVariable::setThreadLocalMode]. *)
val set_thread_local_mode : ThreadLocalMode.t -> llvalue -> unit
(** [is_externally_initialized gv] returns [true] if the global
variable [gv] is externally initialized and [false] otherwise.
See the method [llvm::GlobalVariable::isExternallyInitialized]. *)
val is_externally_initialized : llvalue -> bool
(** [set_externally_initialized c gv] sets the global variable [gv] to be
externally initialized if [c] is [true] and not otherwise.
See the method [llvm::GlobalVariable::setExternallyInitialized]. *)
val set_externally_initialized : bool -> llvalue -> unit
(** {7 Operations on aliases} *)
(** [add_alias m t a n] inserts an alias in the module [m] with the type [t] and
the aliasee [a] with the name [n].
See the constructor for [llvm::GlobalAlias]. *)
val add_alias : llmodule -> lltype -> llvalue -> string -> llvalue
(** {7 Operations on functions} *)
(** [declare_function name ty m] returns a new function of type [ty] and
with name [name] in module [m]. If such a function already exists,
it is returned. If the type of the existing function differs, then a bitcast
to [ty] is returned. *)
val declare_function : string -> lltype -> llmodule -> llvalue
(** [define_function name ty m] creates a new function with name [name] and
type [ty] in module [m]. If the named function already exists, it is
renamed. An entry basic block is created in the function.
See the constructor of [llvm::GlobalVariable]. *)
val define_function : string -> lltype -> llmodule -> llvalue
(** [lookup_function name m] returns [Some f] if a function with name
[name] exists in module [m]. If no such function exists, returns [None].
See the method [llvm::Module] constructor. *)
val lookup_function : string -> llmodule -> llvalue option
(** [delete_function f] destroys the function [f].
See the method [llvm::Function::eraseFromParent]. *)
val delete_function : llvalue -> unit
(** [function_begin m] returns the first position in the function list of the
module [m]. [function_begin] and [function_succ] can be used to iterate over
the function list in order.
See the method [llvm::Module::begin]. *)
val function_begin : llmodule -> (llmodule, llvalue) llpos
(** [function_succ gv] returns the function list position succeeding
[Before gv].
See the method [llvm::Module::iterator::operator++]. *)
val function_succ : llvalue -> (llmodule, llvalue) llpos
(** [iter_functions f m] applies function [f] to each of the functions of module
[m] in order. Tail recursive. *)
val iter_functions : (llvalue -> unit) -> llmodule -> unit
(** [fold_left_function f init m] is [f (... (f init f1) ...) fN] where
[f1,...,fN] are the functions of module [m]. Tail recursive. *)
val fold_left_functions : ('a -> llvalue -> 'a) -> 'a -> llmodule -> 'a
(** [function_end m] returns the last position in the function list of
the module [m]. [function_end] and [function_pred] can be used to iterate
over the function list in reverse.
See the method [llvm::Module::end]. *)
val function_end : llmodule -> (llmodule, llvalue) llrev_pos
(** [function_pred gv] returns the function list position preceding [After gv].
See the method [llvm::Module::iterator::operator--]. *)
val function_pred : llvalue -> (llmodule, llvalue) llrev_pos
(** [rev_iter_functions f fn] applies function [f] to each of the functions of
module [m] in reverse order. Tail recursive. *)
val rev_iter_functions : (llvalue -> unit) -> llmodule -> unit
(** [fold_right_functions f m init] is [f (... (f init fN) ...) f1] where
[f1,...,fN] are the functions of module [m]. Tail recursive. *)
val fold_right_functions : (llvalue -> 'a -> 'a) -> llmodule -> 'a -> 'a
(** [is_intrinsic f] returns true if the function [f] is an intrinsic.
See the method [llvm::Function::isIntrinsic]. *)
val is_intrinsic : llvalue -> bool
(** [function_call_conv f] returns the calling convention of the function [f].
See the method [llvm::Function::getCallingConv]. *)
val function_call_conv : llvalue -> int
(** [set_function_call_conv cc f] sets the calling convention of the function
[f] to the calling convention numbered [cc].
See the method [llvm::Function::setCallingConv]. *)
val set_function_call_conv : int -> llvalue -> unit
(** [gc f] returns [Some name] if the function [f] has a garbage
collection algorithm specified and [None] otherwise.
See the method [llvm::Function::getGC]. *)
val gc : llvalue -> string option
(** [set_gc gc f] sets the collection algorithm for the function [f] to
[gc]. See the method [llvm::Function::setGC]. *)
val set_gc : string option -> llvalue -> unit
(** [add_function_attr f a] adds attribute [a] to the return type of function
[f]. *)
val add_function_attr : llvalue -> Attribute.t -> unit
(** [add_target_dependent_function_attr f a] adds target-dependent attribute
[a] to function [f]. *)
val add_target_dependent_function_attr : llvalue -> string -> string -> unit
(** [function_attr f] returns the function attribute for the function [f].
See the method [llvm::Function::getAttributes] *)
val function_attr : llvalue -> Attribute.t list
(** [remove_function_attr f a] removes attribute [a] from the return type of
function [f]. *)
val remove_function_attr : llvalue -> Attribute.t -> unit
(** {7 Operations on params} *)
(** [params f] returns the parameters of function [f].
See the method [llvm::Function::getArgumentList]. *)
val params : llvalue -> llvalue array
(** [param f n] returns the [n]th parameter of function [f].
See the method [llvm::Function::getArgumentList]. *)
val param : llvalue -> int -> llvalue
(** [param_attr p] returns the attributes of parameter [p].
See the methods [llvm::Function::getAttributes] and
[llvm::Attributes::getParamAttributes] *)
val param_attr : llvalue -> Attribute.t list
(** [param_parent p] returns the parent function that owns the parameter.
See the method [llvm::Argument::getParent]. *)
val param_parent : llvalue -> llvalue
(** [param_begin f] returns the first position in the parameter list of the
function [f]. [param_begin] and [param_succ] can be used to iterate over
the parameter list in order.
See the method [llvm::Function::arg_begin]. *)
val param_begin : llvalue -> (llvalue, llvalue) llpos
(** [param_succ bb] returns the parameter list position succeeding
[Before bb].
See the method [llvm::Function::arg_iterator::operator++]. *)
val param_succ : llvalue -> (llvalue, llvalue) llpos
(** [iter_params f fn] applies function [f] to each of the parameters
of function [fn] in order. Tail recursive. *)
val iter_params : (llvalue -> unit) -> llvalue -> unit
(** [fold_left_params f init fn] is [f (... (f init b1) ...) bN] where
[b1,...,bN] are the parameters of function [fn]. Tail recursive. *)
val fold_left_params : ('a -> llvalue -> 'a) -> 'a -> llvalue -> 'a
(** [param_end f] returns the last position in the parameter list of
the function [f]. [param_end] and [param_pred] can be used to iterate
over the parameter list in reverse.
See the method [llvm::Function::arg_end]. *)
val param_end : llvalue -> (llvalue, llvalue) llrev_pos
(** [param_pred gv] returns the function list position preceding [After gv].
See the method [llvm::Function::arg_iterator::operator--]. *)
val param_pred : llvalue -> (llvalue, llvalue) llrev_pos
(** [rev_iter_params f fn] applies function [f] to each of the parameters
of function [fn] in reverse order. Tail recursive. *)
val rev_iter_params : (llvalue -> unit) -> llvalue -> unit
(** [fold_right_params f fn init] is [f (... (f init bN) ...) b1] where
[b1,...,bN] are the parameters of function [fn]. Tail recursive. *)
val fold_right_params : (llvalue -> 'a -> 'a) -> llvalue -> 'a -> 'a
(** [add_param p a] adds attribute [a] to parameter [p]. *)
val add_param_attr : llvalue -> Attribute.t -> unit
(** [remove_param_attr p a] removes attribute [a] from parameter [p]. *)
val remove_param_attr : llvalue -> Attribute.t -> unit
(** [set_param_alignment p a] set the alignment of parameter [p] to [a]. *)
val set_param_alignment : llvalue -> int -> unit
(** {7 Operations on basic blocks} *)
(** [basic_blocks fn] returns the basic blocks of the function [f].
See the method [llvm::Function::getBasicBlockList]. *)
val basic_blocks : llvalue -> llbasicblock array
(** [entry_block fn] returns the entry basic block of the function [f].
See the method [llvm::Function::getEntryBlock]. *)
val entry_block : llvalue -> llbasicblock
(** [delete_block bb] deletes the basic block [bb].
See the method [llvm::BasicBlock::eraseFromParent]. *)
val delete_block : llbasicblock -> unit
(** [remove_block bb] removes the basic block [bb] from its parent function.
See the method [llvm::BasicBlock::removeFromParent]. *)
val remove_block : llbasicblock -> unit
(** [move_block_before pos bb] moves the basic block [bb] before [pos].
See the method [llvm::BasicBlock::moveBefore]. *)
val move_block_before : llbasicblock -> llbasicblock -> unit
(** [move_block_after pos bb] moves the basic block [bb] after [pos].
See the method [llvm::BasicBlock::moveAfter]. *)
val move_block_after : llbasicblock -> llbasicblock -> unit
(** [append_block c name f] creates a new basic block named [name] at the end of
function [f] in the context [c].
See the constructor of [llvm::BasicBlock]. *)
val append_block : llcontext -> string -> llvalue -> llbasicblock
(** [insert_block c name bb] creates a new basic block named [name] before the
basic block [bb] in the context [c].
See the constructor of [llvm::BasicBlock]. *)
val insert_block : llcontext -> string -> llbasicblock -> llbasicblock
(** [block_parent bb] returns the parent function that owns the basic block.
See the method [llvm::BasicBlock::getParent]. *)
val block_parent : llbasicblock -> llvalue
(** [block_begin f] returns the first position in the basic block list of the
function [f]. [block_begin] and [block_succ] can be used to iterate over
the basic block list in order.
See the method [llvm::Function::begin]. *)
val block_begin : llvalue -> (llvalue, llbasicblock) llpos
(** [block_succ bb] returns the basic block list position succeeding
[Before bb].
See the method [llvm::Function::iterator::operator++]. *)
val block_succ : llbasicblock -> (llvalue, llbasicblock) llpos
(** [iter_blocks f fn] applies function [f] to each of the basic blocks
of function [fn] in order. Tail recursive. *)
val iter_blocks : (llbasicblock -> unit) -> llvalue -> unit
(** [fold_left_blocks f init fn] is [f (... (f init b1) ...) bN] where
[b1,...,bN] are the basic blocks of function [fn]. Tail recursive. *)
val fold_left_blocks : ('a -> llbasicblock -> 'a) -> 'a -> llvalue -> 'a
(** [block_end f] returns the last position in the basic block list of
the function [f]. [block_end] and [block_pred] can be used to iterate
over the basic block list in reverse.
See the method [llvm::Function::end]. *)
val block_end : llvalue -> (llvalue, llbasicblock) llrev_pos
(** [block_pred bb] returns the basic block list position preceding [After bb].
See the method [llvm::Function::iterator::operator--]. *)
val block_pred : llbasicblock -> (llvalue, llbasicblock) llrev_pos
(** [block_terminator bb] returns the terminator of the basic block [bb]. *)
val block_terminator : llbasicblock -> llvalue option
(** [rev_iter_blocks f fn] applies function [f] to each of the basic blocks
of function [fn] in reverse order. Tail recursive. *)
val rev_iter_blocks : (llbasicblock -> unit) -> llvalue -> unit
(** [fold_right_blocks f fn init] is [f (... (f init bN) ...) b1] where
[b1,...,bN] are the basic blocks of function [fn]. Tail recursive. *)
val fold_right_blocks : (llbasicblock -> 'a -> 'a) -> llvalue -> 'a -> 'a
(** [value_of_block bb] losslessly casts [bb] to an [llvalue]. *)
val value_of_block : llbasicblock -> llvalue
(** [value_is_block v] returns [true] if the value [v] is a basic block and
[false] otherwise.
Similar to [llvm::isa<BasicBlock>]. *)
val value_is_block : llvalue -> bool
(** [block_of_value v] losslessly casts [v] to an [llbasicblock]. *)
val block_of_value : llvalue -> llbasicblock
(** {7 Operations on instructions} *)
(** [instr_parent i] is the enclosing basic block of the instruction [i].
See the method [llvm::Instruction::getParent]. *)
val instr_parent : llvalue -> llbasicblock
(** [delete_instruction i] deletes the instruction [i].
* See the method [llvm::Instruction::eraseFromParent]. *)
val delete_instruction : llvalue -> unit
(** [instr_begin bb] returns the first position in the instruction list of the
basic block [bb]. [instr_begin] and [instr_succ] can be used to iterate over
the instruction list in order.
See the method [llvm::BasicBlock::begin]. *)
val instr_begin : llbasicblock -> (llbasicblock, llvalue) llpos
(** [instr_succ i] returns the instruction list position succeeding [Before i].
See the method [llvm::BasicBlock::iterator::operator++]. *)
val instr_succ : llvalue -> (llbasicblock, llvalue) llpos
(** [iter_instrs f bb] applies function [f] to each of the instructions of basic
block [bb] in order. Tail recursive. *)
val iter_instrs: (llvalue -> unit) -> llbasicblock -> unit
(** [fold_left_instrs f init bb] is [f (... (f init g1) ...) gN] where
[g1,...,gN] are the instructions of basic block [bb]. Tail recursive. *)
val fold_left_instrs: ('a -> llvalue -> 'a) -> 'a -> llbasicblock -> 'a
(** [instr_end bb] returns the last position in the instruction list of the
basic block [bb]. [instr_end] and [instr_pred] can be used to iterate over
the instruction list in reverse.
See the method [llvm::BasicBlock::end]. *)
val instr_end : llbasicblock -> (llbasicblock, llvalue) llrev_pos
(** [instr_pred i] returns the instruction list position preceding [After i].
See the method [llvm::BasicBlock::iterator::operator--]. *)
val instr_pred : llvalue -> (llbasicblock, llvalue) llrev_pos
(** [fold_right_instrs f bb init] is [f (... (f init fN) ...) f1] where
[f1,...,fN] are the instructions of basic block [bb]. Tail recursive. *)
val fold_right_instrs: (llvalue -> 'a -> 'a) -> llbasicblock -> 'a -> 'a
(** [inst_opcode i] returns the [Opcode.t] corresponding to instruction [i],
or [Opcode.Invalid] if [i] is not an instruction. *)
val instr_opcode : llvalue -> Opcode.t
(** [icmp_predicate i] returns the [Icmp.t] corresponding to an [icmp]
instruction [i]. *)
val icmp_predicate : llvalue -> Icmp.t option
(** {7 Operations on call sites} *)
(** [instruction_call_conv ci] is the calling convention for the call or invoke
instruction [ci], which may be one of the values from the module
{!CallConv}. See the method [llvm::CallInst::getCallingConv] and
[llvm::InvokeInst::getCallingConv]. *)
val instruction_call_conv: llvalue -> int
(** [set_instruction_call_conv cc ci] sets the calling convention for the call
or invoke instruction [ci] to the integer [cc], which can be one of the
values from the module {!CallConv}.
See the method [llvm::CallInst::setCallingConv]
and [llvm::InvokeInst::setCallingConv]. *)
val set_instruction_call_conv: int -> llvalue -> unit
(** [add_instruction_param_attr ci i a] adds attribute [a] to the [i]th
parameter of the call or invoke instruction [ci]. [i]=0 denotes the return
value. *)
val add_instruction_param_attr : llvalue -> int -> Attribute.t -> unit
(** [remove_instruction_param_attr ci i a] removes attribute [a] from the
[i]th parameter of the call or invoke instruction [ci]. [i]=0 denotes the
return value. *)
val remove_instruction_param_attr : llvalue -> int -> Attribute.t -> unit
(** {7 Operations on call instructions (only)} *)
(** [is_tail_call ci] is [true] if the call instruction [ci] is flagged as
eligible for tail call optimization, [false] otherwise.
See the method [llvm::CallInst::isTailCall]. *)
val is_tail_call : llvalue -> bool
(** [set_tail_call tc ci] flags the call instruction [ci] as eligible for tail
call optimization if [tc] is [true], clears otherwise.
See the method [llvm::CallInst::setTailCall]. *)
val set_tail_call : bool -> llvalue -> unit
(** {7 Operations on load/store instructions (only)} *)
(** [is_volatile i] is [true] if the load or store instruction [i] is marked
as volatile.
See the methods [llvm::LoadInst::isVolatile] and
[llvm::StoreInst::isVolatile]. *)
val is_volatile : llvalue -> bool
(** [set_volatile v i] marks the load or store instruction [i] as volatile
if [v] is [true], unmarks otherwise.
See the methods [llvm::LoadInst::setVolatile] and
[llvm::StoreInst::setVolatile]. *)
val set_volatile : bool -> llvalue -> unit
(** {7 Operations on phi nodes} *)
(** [add_incoming (v, bb) pn] adds the value [v] to the phi node [pn] for use
with branches from [bb]. See the method [llvm::PHINode::addIncoming]. *)
val add_incoming : (llvalue * llbasicblock) -> llvalue -> unit
(** [incoming pn] returns the list of value-block pairs for phi node [pn].
See the method [llvm::PHINode::getIncomingValue]. *)
val incoming : llvalue -> (llvalue * llbasicblock) list
(** {6 Instruction builders} *)
(** [builder context] creates an instruction builder with no position in
the context [context]. It is invalid to use this builder until its position
is set with {!position_before} or {!position_at_end}. See the constructor
for [llvm::LLVMBuilder]. *)
val builder : llcontext -> llbuilder
(** [builder_at ip] creates an instruction builder positioned at [ip].
See the constructor for [llvm::LLVMBuilder]. *)
val builder_at : llcontext -> (llbasicblock, llvalue) llpos -> llbuilder
(** [builder_before ins] creates an instruction builder positioned before the
instruction [isn]. See the constructor for [llvm::LLVMBuilder]. *)
val builder_before : llcontext -> llvalue -> llbuilder
(** [builder_at_end bb] creates an instruction builder positioned at the end of
the basic block [bb]. See the constructor for [llvm::LLVMBuilder]. *)
val builder_at_end : llcontext -> llbasicblock -> llbuilder
(** [position_builder ip bb] moves the instruction builder [bb] to the position
[ip].
See the constructor for [llvm::LLVMBuilder]. *)
val position_builder : (llbasicblock, llvalue) llpos -> llbuilder -> unit
(** [position_before ins b] moves the instruction builder [b] to before the
instruction [isn]. See the method [llvm::LLVMBuilder::SetInsertPoint]. *)
val position_before : llvalue -> llbuilder -> unit
(** [position_at_end bb b] moves the instruction builder [b] to the end of the
basic block [bb]. See the method [llvm::LLVMBuilder::SetInsertPoint]. *)
val position_at_end : llbasicblock -> llbuilder -> unit
(** [insertion_block b] returns the basic block that the builder [b] is
positioned to insert into. Raises [Not_Found] if the instruction builder is
uninitialized.
See the method [llvm::LLVMBuilder::GetInsertBlock]. *)
val insertion_block : llbuilder -> llbasicblock
(** [insert_into_builder i name b] inserts the specified instruction [i] at the
position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::Insert]. *)
val insert_into_builder : llvalue -> string -> llbuilder -> unit
(** {7 Metadata} *)
(** [set_current_debug_location b md] sets the current debug location [md] in
the builder [b].
See the method [llvm::IRBuilder::SetDebugLocation]. *)
val set_current_debug_location : llbuilder -> llvalue -> unit
(** [clear_current_debug_location b] clears the current debug location in the
builder [b]. *)
val clear_current_debug_location : llbuilder -> unit
(** [current_debug_location b] returns the current debug location, or None
if none is currently set.
See the method [llvm::IRBuilder::GetDebugLocation]. *)
val current_debug_location : llbuilder -> llvalue option
(** [set_inst_debug_location b i] sets the current debug location of the builder
[b] to the instruction [i].
See the method [llvm::IRBuilder::SetInstDebugLocation]. *)
val set_inst_debug_location : llbuilder -> llvalue -> unit
(** {7 Terminators} *)
(** [build_ret_void b] creates a
[ret void]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateRetVoid]. *)
val build_ret_void : llbuilder -> llvalue
(** [build_ret v b] creates a
[ret %v]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateRet]. *)
val build_ret : llvalue -> llbuilder -> llvalue
(** [build_aggregate_ret vs b] creates a
[ret {...} { %v1, %v2, ... } ]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateAggregateRet]. *)
val build_aggregate_ret : llvalue array -> llbuilder -> llvalue
(** [build_br bb b] creates a
[br %bb]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateBr]. *)
val build_br : llbasicblock -> llbuilder -> llvalue
(** [build_cond_br cond tbb fbb b] creates a
[br %cond, %tbb, %fbb]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateCondBr]. *)
val build_cond_br : llvalue -> llbasicblock -> llbasicblock -> llbuilder ->
llvalue
(** [build_switch case elsebb count b] creates an empty
[switch %case, %elsebb]
instruction at the position specified by the instruction builder [b] with
space reserved for [count] cases.
See the method [llvm::LLVMBuilder::CreateSwitch]. *)
val build_switch : llvalue -> llbasicblock -> int -> llbuilder -> llvalue
(** [build_malloc ty name b] creates an [malloc]
instruction at the position specified by the instruction builder [b].
See the method [llvm::CallInst::CreateMalloc]. *)
val build_malloc : lltype -> string -> llbuilder -> llvalue
(** [build_array_malloc ty val name b] creates an [array malloc]
instruction at the position specified by the instruction builder [b].
See the method [llvm::CallInst::CreateArrayMalloc]. *)
val build_array_malloc : lltype -> llvalue -> string -> llbuilder -> llvalue
(** [build_free p b] creates a [free]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFree]. *)
val build_free : llvalue -> llbuilder -> llvalue
(** [add_case sw onval bb] causes switch instruction [sw] to branch to [bb]
when its input matches the constant [onval].
See the method [llvm::SwitchInst::addCase]. **)
val add_case : llvalue -> llvalue -> llbasicblock -> unit
(** [switch_default_dest sw] returns the default destination of the [switch]
instruction.
See the method [llvm:;SwitchInst::getDefaultDest]. **)
val switch_default_dest : llvalue -> llbasicblock
(** [build_indirect_br addr count b] creates a
[indirectbr %addr]
instruction at the position specified by the instruction builder [b] with
space reserved for [count] destinations.
See the method [llvm::LLVMBuilder::CreateIndirectBr]. *)
val build_indirect_br : llvalue -> int -> llbuilder -> llvalue
(** [add_destination br bb] adds the basic block [bb] as a possible branch
location for the indirectbr instruction [br].
See the method [llvm::IndirectBrInst::addDestination]. **)
val add_destination : llvalue -> llbasicblock -> unit
(** [build_invoke fn args tobb unwindbb name b] creates an
[%name = invoke %fn(args) to %tobb unwind %unwindbb]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateInvoke]. *)
val build_invoke : llvalue -> llvalue array -> llbasicblock ->
llbasicblock -> string -> llbuilder -> llvalue
(** [build_landingpad ty persfn numclauses name b] creates an
[landingpad]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateLandingPad]. *)
val build_landingpad : lltype -> llvalue -> int -> string -> llbuilder ->
llvalue
(** [set_cleanup lp] sets the cleanup flag in the [landingpad]instruction.
See the method [llvm::LandingPadInst::setCleanup]. *)
val set_cleanup : llvalue -> bool -> unit
(** [add_clause lp clause] adds the clause to the [landingpad]instruction.
See the method [llvm::LandingPadInst::addClause]. *)
val add_clause : llvalue -> llvalue -> unit
(** [build_resume exn b] builds a [resume exn] instruction
at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateResume] *)
val build_resume : llvalue -> llbuilder -> llvalue
(** [build_unreachable b] creates an
[unreachable]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateUnwind]. *)
val build_unreachable : llbuilder -> llvalue
(** {7 Arithmetic} *)
(** [build_add x y name b] creates a
[%name = add %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateAdd]. *)
val build_add : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_nsw_add x y name b] creates a
[%name = nsw add %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateNSWAdd]. *)
val build_nsw_add : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_nuw_add x y name b] creates a
[%name = nuw add %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateNUWAdd]. *)
val build_nuw_add : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_fadd x y name b] creates a
[%name = fadd %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFAdd]. *)
val build_fadd : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_sub x y name b] creates a
[%name = sub %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateSub]. *)
val build_sub : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_nsw_sub x y name b] creates a
[%name = nsw sub %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateNSWSub]. *)
val build_nsw_sub : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_nuw_sub x y name b] creates a
[%name = nuw sub %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateNUWSub]. *)
val build_nuw_sub : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_fsub x y name b] creates a
[%name = fsub %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFSub]. *)
val build_fsub : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_mul x y name b] creates a
[%name = mul %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateMul]. *)
val build_mul : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_nsw_mul x y name b] creates a
[%name = nsw mul %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateNSWMul]. *)
val build_nsw_mul : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_nuw_mul x y name b] creates a
[%name = nuw mul %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateNUWMul]. *)
val build_nuw_mul : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_fmul x y name b] creates a
[%name = fmul %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFMul]. *)
val build_fmul : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_udiv x y name b] creates a
[%name = udiv %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateUDiv]. *)
val build_udiv : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_sdiv x y name b] creates a
[%name = sdiv %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateSDiv]. *)
val build_sdiv : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_exact_sdiv x y name b] creates a
[%name = exact sdiv %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateExactSDiv]. *)
val build_exact_sdiv : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_fdiv x y name b] creates a
[%name = fdiv %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFDiv]. *)
val build_fdiv : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_urem x y name b] creates a
[%name = urem %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateURem]. *)
val build_urem : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_SRem x y name b] creates a
[%name = srem %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateSRem]. *)
val build_srem : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_frem x y name b] creates a
[%name = frem %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFRem]. *)
val build_frem : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_shl x y name b] creates a
[%name = shl %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateShl]. *)
val build_shl : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_lshr x y name b] creates a
[%name = lshr %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateLShr]. *)
val build_lshr : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_ashr x y name b] creates a
[%name = ashr %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateAShr]. *)
val build_ashr : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_and x y name b] creates a
[%name = and %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateAnd]. *)
val build_and : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_or x y name b] creates a
[%name = or %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateOr]. *)
val build_or : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_xor x y name b] creates a
[%name = xor %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateXor]. *)
val build_xor : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** [build_neg x name b] creates a
[%name = sub 0, %x]
instruction at the position specified by the instruction builder [b].
[-0.0] is used for floating point types to compute the correct sign.
See the method [llvm::LLVMBuilder::CreateNeg]. *)
val build_neg : llvalue -> string -> llbuilder -> llvalue
(** [build_nsw_neg x name b] creates a
[%name = nsw sub 0, %x]
instruction at the position specified by the instruction builder [b].
[-0.0] is used for floating point types to compute the correct sign.
See the method [llvm::LLVMBuilder::CreateNeg]. *)
val build_nsw_neg : llvalue -> string -> llbuilder -> llvalue
(** [build_nuw_neg x name b] creates a
[%name = nuw sub 0, %x]
instruction at the position specified by the instruction builder [b].
[-0.0] is used for floating point types to compute the correct sign.
See the method [llvm::LLVMBuilder::CreateNeg]. *)
val build_nuw_neg : llvalue -> string -> llbuilder -> llvalue
(** [build_fneg x name b] creates a
[%name = fsub 0, %x]
instruction at the position specified by the instruction builder [b].
[-0.0] is used for floating point types to compute the correct sign.
See the method [llvm::LLVMBuilder::CreateFNeg]. *)
val build_fneg : llvalue -> string -> llbuilder -> llvalue
(** [build_xor x name b] creates a
[%name = xor %x, -1]
instruction at the position specified by the instruction builder [b].
[-1] is the correct "all ones" value for the type of [x].
See the method [llvm::LLVMBuilder::CreateXor]. *)
val build_not : llvalue -> string -> llbuilder -> llvalue
(** {7 Memory} *)
(** [build_alloca ty name b] creates a
[%name = alloca %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateAlloca]. *)
val build_alloca : lltype -> string -> llbuilder -> llvalue
(** [build_array_alloca ty n name b] creates a
[%name = alloca %ty, %n]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateAlloca]. *)
val build_array_alloca : lltype -> llvalue -> string -> llbuilder ->
llvalue
(** [build_load v name b] creates a
[%name = load %v]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateLoad]. *)
val build_load : llvalue -> string -> llbuilder -> llvalue
(** [build_store v p b] creates a
[store %v, %p]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateStore]. *)
val build_store : llvalue -> llvalue -> llbuilder -> llvalue
(** [build_atomicrmw op ptr val o st b] creates an [atomicrmw] instruction with
operation [op] performed on pointer [ptr] and value [val] with ordering [o]
and singlethread flag set to [st] at the position specified by
the instruction builder [b].
See the method [llvm::IRBuilder::CreateAtomicRMW]. *)
val build_atomicrmw : AtomicRMWBinOp.t -> llvalue -> llvalue ->
AtomicOrdering.t -> bool -> string -> llbuilder -> llvalue
(** [build_gep p indices name b] creates a
[%name = getelementptr %p, indices...]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateGetElementPtr]. *)
val build_gep : llvalue -> llvalue array -> string -> llbuilder -> llvalue
(** [build_in_bounds_gep p indices name b] creates a
[%name = gelementptr inbounds %p, indices...]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateInBoundsGetElementPtr]. *)
val build_in_bounds_gep : llvalue -> llvalue array -> string -> llbuilder ->
llvalue
(** [build_struct_gep p idx name b] creates a
[%name = getelementptr %p, 0, idx]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateStructGetElementPtr]. *)
val build_struct_gep : llvalue -> int -> string -> llbuilder ->
llvalue
(** [build_global_string str name b] creates a series of instructions that adds
a global string at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateGlobalString]. *)
val build_global_string : string -> string -> llbuilder -> llvalue
(** [build_global_stringptr str name b] creates a series of instructions that
adds a global string pointer at the position specified by the instruction
builder [b].
See the method [llvm::LLVMBuilder::CreateGlobalStringPtr]. *)
val build_global_stringptr : string -> string -> llbuilder -> llvalue
(** {7 Casts} *)
(** [build_trunc v ty name b] creates a
[%name = trunc %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateTrunc]. *)
val build_trunc : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_zext v ty name b] creates a
[%name = zext %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateZExt]. *)
val build_zext : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_sext v ty name b] creates a
[%name = sext %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateSExt]. *)
val build_sext : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_fptoui v ty name b] creates a
[%name = fptoui %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFPToUI]. *)
val build_fptoui : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_fptosi v ty name b] creates a
[%name = fptosi %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFPToSI]. *)
val build_fptosi : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_uitofp v ty name b] creates a
[%name = uitofp %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateUIToFP]. *)
val build_uitofp : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_sitofp v ty name b] creates a
[%name = sitofp %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateSIToFP]. *)
val build_sitofp : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_fptrunc v ty name b] creates a
[%name = fptrunc %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFPTrunc]. *)
val build_fptrunc : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_fpext v ty name b] creates a
[%name = fpext %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFPExt]. *)
val build_fpext : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_ptrtoint v ty name b] creates a
[%name = prtotint %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreatePtrToInt]. *)
val build_ptrtoint : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_inttoptr v ty name b] creates a
[%name = inttoptr %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateIntToPtr]. *)
val build_inttoptr : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_bitcast v ty name b] creates a
[%name = bitcast %p to %ty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateBitCast]. *)
val build_bitcast : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_zext_or_bitcast v ty name b] creates a zext or bitcast
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateZExtOrBitCast]. *)
val build_zext_or_bitcast : llvalue -> lltype -> string -> llbuilder ->
llvalue
(** [build_sext_or_bitcast v ty name b] creates a sext or bitcast
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateSExtOrBitCast]. *)
val build_sext_or_bitcast : llvalue -> lltype -> string -> llbuilder ->
llvalue
(** [build_trunc_or_bitcast v ty name b] creates a trunc or bitcast
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateZExtOrBitCast]. *)
val build_trunc_or_bitcast : llvalue -> lltype -> string -> llbuilder ->
llvalue
(** [build_pointercast v ty name b] creates a bitcast or pointer-to-int
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreatePointerCast]. *)
val build_pointercast : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_intcast v ty name b] creates a zext, bitcast, or trunc
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateIntCast]. *)
val build_intcast : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_fpcast v ty name b] creates a fpext, bitcast, or fptrunc
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFPCast]. *)
val build_fpcast : llvalue -> lltype -> string -> llbuilder -> llvalue
(** {7 Comparisons} *)
(** [build_icmp pred x y name b] creates a
[%name = icmp %pred %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateICmp]. *)
val build_icmp : Icmp.t -> llvalue -> llvalue -> string ->
llbuilder -> llvalue
(** [build_fcmp pred x y name b] creates a
[%name = fcmp %pred %x, %y]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateFCmp]. *)
val build_fcmp : Fcmp.t -> llvalue -> llvalue -> string ->
llbuilder -> llvalue
(** {7 Miscellaneous instructions} *)
(** [build_phi incoming name b] creates a
[%name = phi %incoming]
instruction at the position specified by the instruction builder [b].
[incoming] is a list of [(llvalue, llbasicblock)] tuples.
See the method [llvm::LLVMBuilder::CreatePHI]. *)
val build_phi : (llvalue * llbasicblock) list -> string -> llbuilder ->
llvalue
(** [build_call fn args name b] creates a
[%name = call %fn(args...)]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateCall]. *)
val build_call : llvalue -> llvalue array -> string -> llbuilder -> llvalue
(** [build_select cond thenv elsev name b] creates a
[%name = select %cond, %thenv, %elsev]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateSelect]. *)
val build_select : llvalue -> llvalue -> llvalue -> string -> llbuilder ->
llvalue
(** [build_va_arg valist argty name b] creates a
[%name = va_arg %valist, %argty]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateVAArg]. *)
val build_va_arg : llvalue -> lltype -> string -> llbuilder -> llvalue
(** [build_extractelement vec i name b] creates a
[%name = extractelement %vec, %i]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateExtractElement]. *)
val build_extractelement : llvalue -> llvalue -> string -> llbuilder ->
llvalue
(** [build_insertelement vec elt i name b] creates a
[%name = insertelement %vec, %elt, %i]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateInsertElement]. *)
val build_insertelement : llvalue -> llvalue -> llvalue -> string ->
llbuilder -> llvalue
(** [build_shufflevector veca vecb mask name b] creates a
[%name = shufflevector %veca, %vecb, %mask]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateShuffleVector]. *)
val build_shufflevector : llvalue -> llvalue -> llvalue -> string ->
llbuilder -> llvalue
(** [build_insertvalue agg idx name b] creates a
[%name = extractvalue %agg, %idx]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateExtractValue]. *)
val build_extractvalue : llvalue -> int -> string -> llbuilder -> llvalue
(** [build_insertvalue agg val idx name b] creates a
[%name = insertvalue %agg, %val, %idx]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateInsertValue]. *)
val build_insertvalue : llvalue -> llvalue -> int -> string -> llbuilder ->
llvalue
(** [build_is_null val name b] creates a
[%name = icmp eq %val, null]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateIsNull]. *)
val build_is_null : llvalue -> string -> llbuilder -> llvalue
(** [build_is_not_null val name b] creates a
[%name = icmp ne %val, null]
instruction at the position specified by the instruction builder [b].
See the method [llvm::LLVMBuilder::CreateIsNotNull]. *)
val build_is_not_null : llvalue -> string -> llbuilder -> llvalue
(** [build_ptrdiff lhs rhs name b] creates a series of instructions that measure
the difference between two pointer values at the position specified by the
instruction builder [b].
See the method [llvm::LLVMBuilder::CreatePtrDiff]. *)
val build_ptrdiff : llvalue -> llvalue -> string -> llbuilder -> llvalue
(** {6 Memory buffers} *)
module MemoryBuffer : sig
(** [of_file p] is the memory buffer containing the contents of the file at
path [p]. If the file could not be read, then [IoError msg] is
raised. *)
val of_file : string -> llmemorybuffer
(** [of_stdin ()] is the memory buffer containing the contents of standard input.
If standard input is empty, then [IoError msg] is raised. *)
val of_stdin : unit -> llmemorybuffer
(** [of_string ~name s] is the memory buffer containing the contents of string [s].
The name of memory buffer is set to [name] if it is provided. *)
val of_string : ?name:string -> string -> llmemorybuffer
(** [as_string mb] is the string containing the contents of memory buffer [mb]. *)
val as_string : llmemorybuffer -> string
(** Disposes of a memory buffer. *)
val dispose : llmemorybuffer -> unit
end
(** {6 Pass Managers} *)
module PassManager : sig
(** *)
type 'a t
type any = [ `Module | `Function ]
(** [PassManager.create ()] constructs a new whole-module pass pipeline. This
type of pipeline is suitable for link-time optimization and whole-module
transformations.
See the constructor of [llvm::PassManager]. *)
val create : unit -> [ `Module ] t
(** [PassManager.create_function m] constructs a new function-by-function
pass pipeline over the module [m]. It does not take ownership of [m].
This type of pipeline is suitable for code generation and JIT compilation
tasks.
See the constructor of [llvm::FunctionPassManager]. *)
val create_function : llmodule -> [ `Function ] t
(** [run_module m pm] initializes, executes on the module [m], and finalizes
all of the passes scheduled in the pass manager [pm]. Returns [true] if
any of the passes modified the module, [false] otherwise.
See the [llvm::PassManager::run] method. *)
val run_module : llmodule -> [ `Module ] t -> bool
(** [initialize fpm] initializes all of the function passes scheduled in the
function pass manager [fpm]. Returns [true] if any of the passes modified
the module, [false] otherwise.
See the [llvm::FunctionPassManager::doInitialization] method. *)
val initialize : [ `Function ] t -> bool
(** [run_function f fpm] executes all of the function passes scheduled in the
function pass manager [fpm] over the function [f]. Returns [true] if any
of the passes modified [f], [false] otherwise.
See the [llvm::FunctionPassManager::run] method. *)
val run_function : llvalue -> [ `Function ] t -> bool
(** [finalize fpm] finalizes all of the function passes scheduled in in the
function pass manager [fpm]. Returns [true] if any of the passes
modified the module, [false] otherwise.
See the [llvm::FunctionPassManager::doFinalization] method. *)
val finalize : [ `Function ] t -> bool
(** Frees the memory of a pass pipeline. For function pipelines, does not free
the module.
See the destructor of [llvm::BasePassManager]. *)
val dispose : [< any ] t -> unit
end
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