(*===-- llvm_executionengine.mli - LLVM OCaml Interface -------*- OCaml -*-===* * * Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. * See https://llvm.org/LICENSE.txt for license information. * SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception * *===----------------------------------------------------------------------===*) (** JIT Interpreter. This interface provides an OCaml API for LLVM execution engine (JIT/ interpreter), the classes in the [ExecutionEngine] library. *) exception Error of string (** [initialize ()] initializes the backend corresponding to the host. Returns [true] if initialization is successful; [false] indicates that there is no such backend or it is unable to emit object code via MCJIT. *) val initialize : unit -> bool (** An execution engine is either a JIT compiler or an interpreter, capable of directly loading an LLVM module and executing its functions without first invoking a static compiler and generating a native executable. *) type llexecutionengine (** MCJIT compiler options. See [llvm::TargetOptions]. *) type llcompileroptions = { opt_level: int; code_model: Llvm_target.CodeModel.t; no_framepointer_elim: bool; enable_fast_isel: bool; } (** Default MCJIT compiler options: [{ opt_level = 0; code_model = CodeModel.JIT_default; no_framepointer_elim = false; enable_fast_isel = false }] *) val default_compiler_options : llcompileroptions (** [create m optlevel] creates a new MCJIT just-in-time compiler, taking ownership of the module [m] if successful with the desired optimization level [optlevel]. Raises [Error msg] if an error occurrs. The execution engine is not garbage collected and must be destroyed with [dispose ee]. Run {!initialize} before using this function. See the function [llvm::EngineBuilder::create]. *) val create : ?options:llcompileroptions -> Llvm.llmodule -> llexecutionengine (** [dispose ee] releases the memory used by the execution engine and must be invoked to avoid memory leaks. *) val dispose : llexecutionengine -> unit (** [add_module m ee] adds the module [m] to the execution engine [ee]. *) val add_module : Llvm.llmodule -> llexecutionengine -> unit (** [remove_module m ee] removes the module [m] from the execution engine [ee]. Raises [Error msg] if an error occurs. *) val remove_module : Llvm.llmodule -> llexecutionengine -> unit (** [run_static_ctors ee] executes the static constructors of each module in the execution engine [ee]. *) val run_static_ctors : llexecutionengine -> unit (** [run_static_dtors ee] executes the static destructors of each module in the execution engine [ee]. *) val run_static_dtors : llexecutionengine -> unit (** [data_layout ee] is the data layout of the execution engine [ee]. *) val data_layout : llexecutionengine -> Llvm_target.DataLayout.t (** [add_global_mapping gv ptr ee] tells the execution engine [ee] that the global [gv] is at the specified location [ptr], which must outlive [gv] and [ee]. All uses of [gv] in the compiled code will refer to [ptr]. *) val add_global_mapping : Llvm.llvalue -> 'a Ctypes.ptr -> llexecutionengine -> unit (** [get_global_value_address id typ ee] returns a pointer to the identifier [id] as type [typ], which will be a pointer type for a value, and which will be live as long as [id] and [ee] are. Caution: this function finalizes, i.e. forces code generation, all loaded modules. Further modifications to the modules will not have any effect. *) val get_global_value_address : string -> 'a Ctypes.typ -> llexecutionengine -> 'a (** [get_function_address fn typ ee] returns a pointer to the function [fn] as type [typ], which will be a pointer type for a function (e.g. [(int -> int) typ]), and which will be live as long as [fn] and [ee] are. Caution: this function finalizes, i.e. forces code generation, all loaded modules. Further modifications to the modules will not have any effect. *) val get_function_address : string -> 'a Ctypes.typ -> llexecutionengine -> 'a