/*===-- target_ocaml.c - LLVM OCaml Glue ------------------------*- C++ -*-===*\ |* *| |* The LLVM Compiler Infrastructure *| |* *| |* This file is distributed under the University of Illinois Open Source *| |* License. See LICENSE.TXT for details. *| |* *| |*===----------------------------------------------------------------------===*| |* *| |* This file glues LLVM's OCaml interface to its C interface. These functions *| |* are by and large transparent wrappers to the corresponding C functions. *| |* *| |* Note that these functions intentionally take liberties with the CAMLparamX *| |* macros, since most of the parameters are not GC heap objects. *| |* *| \*===----------------------------------------------------------------------===*/ #include "llvm-c/Target.h" #include "llvm-c/TargetMachine.h" #include "caml/alloc.h" #include "caml/fail.h" #include "caml/memory.h" #include "caml/custom.h" #include "caml/callback.h" void llvm_raise(value Prototype, char *Message); value llvm_string_of_message(char* Message); /*===---- Data Layout -----------------------------------------------------===*/ #define DataLayout_val(v) (*(LLVMTargetDataRef *)(Data_custom_val(v))) static void llvm_finalize_data_layout(value DataLayout) { LLVMDisposeTargetData(DataLayout_val(DataLayout)); } static struct custom_operations llvm_data_layout_ops = { (char *) "Llvm_target.DataLayout.t", llvm_finalize_data_layout, custom_compare_default, custom_hash_default, custom_serialize_default, custom_deserialize_default, custom_compare_ext_default }; value llvm_alloc_data_layout(LLVMTargetDataRef DataLayout) { value V = alloc_custom(&llvm_data_layout_ops, sizeof(LLVMTargetDataRef), 0, 1); DataLayout_val(V) = DataLayout; return V; } /* string -> DataLayout.t */ CAMLprim value llvm_datalayout_of_string(value StringRep) { return llvm_alloc_data_layout(LLVMCreateTargetData(String_val(StringRep))); } /* DataLayout.t -> string */ CAMLprim value llvm_datalayout_as_string(value TD) { char *StringRep = LLVMCopyStringRepOfTargetData(DataLayout_val(TD)); value Copy = copy_string(StringRep); LLVMDisposeMessage(StringRep); return Copy; } /* [<Llvm.PassManager.any] Llvm.PassManager.t -> DataLayout.t -> unit */ CAMLprim value llvm_datalayout_add_to_pass_manager(LLVMPassManagerRef PM, value DL) { LLVMAddTargetData(DataLayout_val(DL), PM); return Val_unit; } /* DataLayout.t -> Endian.t */ CAMLprim value llvm_datalayout_byte_order(value DL) { return Val_int(LLVMByteOrder(DataLayout_val(DL))); } /* DataLayout.t -> int */ CAMLprim value llvm_datalayout_pointer_size(value DL) { return Val_int(LLVMPointerSize(DataLayout_val(DL))); } /* Llvm.llcontext -> DataLayout.t -> Llvm.lltype */ CAMLprim LLVMTypeRef llvm_datalayout_intptr_type(LLVMContextRef C, value DL) { return LLVMIntPtrTypeInContext(C, DataLayout_val(DL));; } /* int -> DataLayout.t -> int */ CAMLprim value llvm_datalayout_qualified_pointer_size(value AS, value DL) { return Val_int(LLVMPointerSizeForAS(DataLayout_val(DL), Int_val(AS))); } /* Llvm.llcontext -> int -> DataLayout.t -> Llvm.lltype */ CAMLprim LLVMTypeRef llvm_datalayout_qualified_intptr_type(LLVMContextRef C, value AS, value DL) { return LLVMIntPtrTypeForASInContext(C, DataLayout_val(DL), Int_val(AS)); } /* Llvm.lltype -> DataLayout.t -> Int64.t */ CAMLprim value llvm_datalayout_size_in_bits(LLVMTypeRef Ty, value DL) { return caml_copy_int64(LLVMSizeOfTypeInBits(DataLayout_val(DL), Ty)); } /* Llvm.lltype -> DataLayout.t -> Int64.t */ CAMLprim value llvm_datalayout_store_size(LLVMTypeRef Ty, value DL) { return caml_copy_int64(LLVMStoreSizeOfType(DataLayout_val(DL), Ty)); } /* Llvm.lltype -> DataLayout.t -> Int64.t */ CAMLprim value llvm_datalayout_abi_size(LLVMTypeRef Ty, value DL) { return caml_copy_int64(LLVMABISizeOfType(DataLayout_val(DL), Ty)); } /* Llvm.lltype -> DataLayout.t -> int */ CAMLprim value llvm_datalayout_abi_align(LLVMTypeRef Ty, value DL) { return Val_int(LLVMABIAlignmentOfType(DataLayout_val(DL), Ty)); } /* Llvm.lltype -> DataLayout.t -> int */ CAMLprim value llvm_datalayout_stack_align(LLVMTypeRef Ty, value DL) { return Val_int(LLVMCallFrameAlignmentOfType(DataLayout_val(DL), Ty)); } /* Llvm.lltype -> DataLayout.t -> int */ CAMLprim value llvm_datalayout_preferred_align(LLVMTypeRef Ty, value DL) { return Val_int(LLVMPreferredAlignmentOfType(DataLayout_val(DL), Ty)); } /* Llvm.llvalue -> DataLayout.t -> int */ CAMLprim value llvm_datalayout_preferred_align_of_global(LLVMValueRef GlobalVar, value DL) { return Val_int(LLVMPreferredAlignmentOfGlobal(DataLayout_val(DL), GlobalVar)); } /* Llvm.lltype -> Int64.t -> DataLayout.t -> int */ CAMLprim value llvm_datalayout_element_at_offset(LLVMTypeRef Ty, value Offset, value DL) { return Val_int(LLVMElementAtOffset(DataLayout_val(DL), Ty, Int64_val(Offset))); } /* Llvm.lltype -> int -> DataLayout.t -> Int64.t */ CAMLprim value llvm_datalayout_offset_of_element(LLVMTypeRef Ty, value Index, value DL) { return caml_copy_int64(LLVMOffsetOfElement(DataLayout_val(DL), Ty, Int_val(Index))); } /*===---- Target ----------------------------------------------------------===*/ static value llvm_target_option(LLVMTargetRef Target) { if(Target != NULL) { value Result = caml_alloc_small(1, 0); Store_field(Result, 0, (value) Target); return Result; } return Val_int(0); } /* unit -> string */ CAMLprim value llvm_target_default_triple(value Unit) { char *TripleCStr = LLVMGetDefaultTargetTriple(); value TripleStr = caml_copy_string(TripleCStr); LLVMDisposeMessage(TripleCStr); return TripleStr; } /* unit -> Target.t option */ CAMLprim value llvm_target_first(value Unit) { return llvm_target_option(LLVMGetFirstTarget()); } /* Target.t -> Target.t option */ CAMLprim value llvm_target_succ(LLVMTargetRef Target) { return llvm_target_option(LLVMGetNextTarget(Target)); } /* string -> Target.t option */ CAMLprim value llvm_target_by_name(value Name) { return llvm_target_option(LLVMGetTargetFromName(String_val(Name))); } /* string -> Target.t */ CAMLprim LLVMTargetRef llvm_target_by_triple(value Triple) { LLVMTargetRef T; char *Error; if(LLVMGetTargetFromTriple(String_val(Triple), &T, &Error)) llvm_raise(*caml_named_value("Llvm_target.Error"), Error); return T; } /* Target.t -> string */ CAMLprim value llvm_target_name(LLVMTargetRef Target) { return caml_copy_string(LLVMGetTargetName(Target)); } /* Target.t -> string */ CAMLprim value llvm_target_description(LLVMTargetRef Target) { return caml_copy_string(LLVMGetTargetDescription(Target)); } /* Target.t -> bool */ CAMLprim value llvm_target_has_jit(LLVMTargetRef Target) { return Val_bool(LLVMTargetHasJIT(Target)); } /* Target.t -> bool */ CAMLprim value llvm_target_has_target_machine(LLVMTargetRef Target) { return Val_bool(LLVMTargetHasTargetMachine(Target)); } /* Target.t -> bool */ CAMLprim value llvm_target_has_asm_backend(LLVMTargetRef Target) { return Val_bool(LLVMTargetHasAsmBackend(Target)); } /*===---- Target Machine --------------------------------------------------===*/ #define TargetMachine_val(v) (*(LLVMTargetMachineRef *)(Data_custom_val(v))) static void llvm_finalize_target_machine(value Machine) { LLVMDisposeTargetMachine(TargetMachine_val(Machine)); } static struct custom_operations llvm_target_machine_ops = { (char *) "Llvm_target.TargetMachine.t", llvm_finalize_target_machine, custom_compare_default, custom_hash_default, custom_serialize_default, custom_deserialize_default, custom_compare_ext_default }; static value llvm_alloc_targetmachine(LLVMTargetMachineRef Machine) { value V = alloc_custom(&llvm_target_machine_ops, sizeof(LLVMTargetMachineRef), 0, 1); TargetMachine_val(V) = Machine; return V; } /* triple:string -> ?cpu:string -> ?features:string ?level:CodeGenOptLevel.t -> ?reloc_mode:RelocMode.t ?code_model:CodeModel.t -> Target.t -> TargetMachine.t */ CAMLprim value llvm_create_targetmachine_native(value Triple, value CPU, value Features, value OptLevel, value RelocMode, value CodeModel, LLVMTargetRef Target) { LLVMTargetMachineRef Machine; const char *CPUStr = "", *FeaturesStr = ""; LLVMCodeGenOptLevel OptLevelEnum = LLVMCodeGenLevelDefault; LLVMRelocMode RelocModeEnum = LLVMRelocDefault; LLVMCodeModel CodeModelEnum = LLVMCodeModelDefault; if(CPU != Val_int(0)) CPUStr = String_val(Field(CPU, 0)); if(Features != Val_int(0)) FeaturesStr = String_val(Field(Features, 0)); if(OptLevel != Val_int(0)) OptLevelEnum = Int_val(Field(OptLevel, 0)); if(RelocMode != Val_int(0)) RelocModeEnum = Int_val(Field(RelocMode, 0)); if(CodeModel != Val_int(0)) CodeModelEnum = Int_val(Field(CodeModel, 0)); Machine = LLVMCreateTargetMachine(Target, String_val(Triple), CPUStr, FeaturesStr, OptLevelEnum, RelocModeEnum, CodeModelEnum); return llvm_alloc_targetmachine(Machine); } CAMLprim value llvm_create_targetmachine_bytecode(value *argv, int argn) { return llvm_create_targetmachine_native(argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], (LLVMTargetRef) argv[6]); } /* TargetMachine.t -> Target.t */ CAMLprim LLVMTargetRef llvm_targetmachine_target(value Machine) { return LLVMGetTargetMachineTarget(TargetMachine_val(Machine)); } /* TargetMachine.t -> string */ CAMLprim value llvm_targetmachine_triple(value Machine) { return llvm_string_of_message(LLVMGetTargetMachineTriple( TargetMachine_val(Machine))); } /* TargetMachine.t -> string */ CAMLprim value llvm_targetmachine_cpu(value Machine) { return llvm_string_of_message(LLVMGetTargetMachineCPU( TargetMachine_val(Machine))); } /* TargetMachine.t -> string */ CAMLprim value llvm_targetmachine_features(value Machine) { return llvm_string_of_message(LLVMGetTargetMachineFeatureString( TargetMachine_val(Machine))); } /* TargetMachine.t -> DataLayout.t */ CAMLprim value llvm_targetmachine_data_layout(value Machine) { CAMLparam1(Machine); CAMLlocal1(DataLayout); char *TargetDataCStr; /* LLVMGetTargetMachineData returns a pointer owned by the TargetMachine, so it is impossible to wrap it with llvm_alloc_target_data, which assumes that OCaml owns the pointer. */ LLVMTargetDataRef OrigDataLayout; OrigDataLayout = LLVMGetTargetMachineData(TargetMachine_val(Machine)); TargetDataCStr = LLVMCopyStringRepOfTargetData(OrigDataLayout); DataLayout = llvm_alloc_data_layout(LLVMCreateTargetData(TargetDataCStr)); LLVMDisposeMessage(TargetDataCStr); CAMLreturn(DataLayout); } /* bool -> TargetMachine.t -> unit */ CAMLprim value llvm_targetmachine_set_verbose_asm(value Verb, value Machine) { LLVMSetTargetMachineAsmVerbosity(TargetMachine_val(Machine), Bool_val(Verb)); return Val_unit; } /* Llvm.llmodule -> CodeGenFileType.t -> string -> TargetMachine.t -> unit */ CAMLprim value llvm_targetmachine_emit_to_file(LLVMModuleRef Module, value FileType, value FileName, value Machine) { char *ErrorMessage; if(LLVMTargetMachineEmitToFile(TargetMachine_val(Machine), Module, String_val(FileName), Int_val(FileType), &ErrorMessage)) { llvm_raise(*caml_named_value("Llvm_target.Error"), ErrorMessage); } return Val_unit; } /* Llvm.llmodule -> CodeGenFileType.t -> TargetMachine.t -> Llvm.llmemorybuffer */ CAMLprim LLVMMemoryBufferRef llvm_targetmachine_emit_to_memory_buffer( LLVMModuleRef Module, value FileType, value Machine) { char *ErrorMessage; LLVMMemoryBufferRef Buffer; if(LLVMTargetMachineEmitToMemoryBuffer(TargetMachine_val(Machine), Module, Int_val(FileType), &ErrorMessage, &Buffer)) { llvm_raise(*caml_named_value("Llvm_target.Error"), ErrorMessage); } return Buffer; } /* TargetMachine.t -> Llvm.PassManager.t -> unit */ CAMLprim value llvm_targetmachine_add_analysis_passes(LLVMPassManagerRef PM, value Machine) { LLVMAddAnalysisPasses(TargetMachine_val(Machine), PM); return Val_unit; }