(*===-- 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 DLL storage class of a global value, accessed with {!dll_storage_class} and {!set_dll_storage_class}. See [llvm::GlobalValue::DLLStorageClassTypes]. *) module DLLStorageClass : sig type t = | Default | DLLImport | DLLExport 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 (** Equal *) | Ne (** Not equal *) | Ugt (** Unsigned greater than *) | Uge (** Unsigned greater or equal *) | Ult (** Unsigned less than *) | Ule (** Unsigned less or equal *) | Sgt (** Signed greater than *) | Sge (** Signed greater or equal *) | Slt (** Signed less than *) | Sle (** Signed less or equal *) end (** The predicate for a floating-point comparison ([fcmp]) instruction. Ordered means that neither operand is a QNAN while unordered means that either operand may be a QNAN. See the [llvm::FCmpInst::Predicate] enumeration. *) module Fcmp : sig type t = | False (** Always false *) | Oeq (** Ordered and equal *) | Ogt (** Ordered and greater than *) | Oge (** Ordered and greater or equal *) | Olt (** Ordered and less than *) | Ole (** Ordered and less or equal *) | One (** Ordered and not equal *) | Ord (** Ordered (no operand is NaN) *) | Uno (** Unordered (one operand at least is NaN) *) | Ueq (** Unordered and equal *) | Ugt (** Unordered and greater than *) | Uge (** Unordered and greater or equal *) | Ult (** Unordered and less than *) | Ule (** Unordered and less or equal *) | Une (** Unordered and not equal *) | True (** Always true *) end (** The opcodes for LLVM instructions and constant expressions. *) module Opcode : sig type t = | Invalid (** Not an instruction *) | Ret (** Terminator Instructions *) | Br | Switch | IndirectBr | Invoke | Invalid2 | Unreachable | Add (** Standard Binary Operators *) | FAdd | Sub | FSub | Mul | FMul | UDiv | SDiv | FDiv | URem | SRem | FRem | Shl (** Logical Operators *) | LShr | AShr | And | Or | Xor | Alloca (** Memory Operators *) | Load | Store | GetElementPtr | Trunc (** Cast Operators *) | ZExt | SExt | FPToUI | FPToSI | UIToFP | SIToFP | FPTrunc | FPExt | PtrToInt | IntToPtr | BitCast | ICmp (** Other Operators *) | 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 (** [parse_command_line_options ?overview args] parses [args] using the LLVM command line parser. Note that the only stable thing about this function is its signature; you cannot rely on any particular set of command line arguments being interpreted the same way across LLVM versions. See the function [llvm::cl::ParseCommandLineOptions()]. *) val parse_command_line_options : ?overview:string -> string array -> 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 -> llmdkind (** {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 (** [operand_use v i] returns the use of the operand at index [i] for the value [v]. See the method [llvm::User::getOperandUse]. *) val operand_use : llvalue -> int -> lluse (** [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]. *) 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]. *) 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 (** [mdnull c ] returns a null MDNode in context [c]. *) val mdnull : llcontext -> 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 (** [float_of_const c] returns the float value of the [c] constant float. None is returned if this is not an float constant. See the method [llvm::ConstantFP::getDoubleValue].*) val float_of_const : llvalue -> float option (** [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 (** [string_of_const c] returns [Some str] if [c] is a string constant, or [None] if this is not a string constant. *) val string_of_const : llvalue -> string option (** [const_element c] returns a constant for a specified index's element. See the method ConstantDataSequential::getElementAsConstant. *) val const_element : llvalue -> int -> 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 [pc] 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 [pc] 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 (** [dll_storage_class g] returns the DLL storage class of the global value [g]. See the method [llvm::GlobalValue::getDLLStorageClass]. *) val dll_storage_class : llvalue -> DLLStorageClass.t (** [set_dll_storage_class v g] sets the DLL storage class of the global value [g] to [v]. See the method [llvm::GlobalValue::setDLLStorageClass]. *) val set_dll_storage_class : DLLStorageClass.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]. *) 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 (** [fcmp_predicate i] returns the [fcmp.t] corresponding to an [fcmp] instruction [i]. *) val fcmp_predicate : llvalue -> Fcmp.t option (** [inst_clone i] returns a copy of instruction [i], The instruction has no parent, and no name. See the method [llvm::Instruction::clone]. *) val instr_clone : llvalue -> llvalue (** {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 terminators} *) (** [is_terminator v] returns true if the instruction [v] is a terminator. *) val is_terminator : llvalue -> bool (** [successor v i] returns the successor at index [i] for the value [v]. See the method [llvm::TerminatorInst::getSuccessor]. *) val successor : llvalue -> int -> llbasicblock (** [set_successor v i o] sets the successor of the value [v] at the index [i] to the value [o]. See the method [llvm::TerminatorInst::setSuccessor]. *) val set_successor : llvalue -> int -> llbasicblock -> unit (** [num_successors v] returns the number of successors for the value [v]. See the method [llvm::TerminatorInst::getNumSuccessors]. *) val num_successors : llvalue -> int (** [successors v] returns the successors of [v]. *) val successors : llvalue -> llbasicblock array (** [iter_successors f v] applies function f to each successor [v] in order. Tail recursive. *) val iter_successors : (llbasicblock -> unit) -> llvalue -> unit (** [fold_successors f v init] is [f (... (f init vN) ...) v1] where [v1,...,vN] are the successors of [v]. Tail recursive. *) val fold_successors : (llbasicblock -> 'a -> 'a) -> llvalue -> 'a -> 'a (** {7 Operations on branches} *) (** [is_conditional v] returns true if the branch instruction [v] is conditional. See the method [llvm::BranchInst::isConditional]. *) val is_conditional : llvalue -> bool (** [condition v] return the condition of the branch instruction [v]. See the method [llvm::BranchInst::getCondition]. *) val condition : llvalue -> llvalue (** [set_condition v c] sets the condition of the branch instruction [v] to the value [c]. See the method [llvm::BranchInst::setCondition]. *) val set_condition : llvalue -> llvalue -> unit (** [get_branch c] returns a description of the branch instruction [c]. *) val get_branch : llvalue -> [ `Conditional of llvalue * llbasicblock * llbasicblock | `Unconditional of llbasicblock ] option (** {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_empty_phi ty name b] creates a [%name = phi %ty] instruction at the position specified by the instruction builder [b]. [ty] is the type of the instruction. See the method [llvm::LLVMBuilder::CreatePHI]. *) val build_empty_phi : lltype -> 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_extractvalue 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