https://github.com/JuliaLang/julia
Tip revision: c722927a164cb95a788078bb74cf5ae735662d8f authored by Valentin Churavy on 06 December 2020, 04:50:50 UTC
add freeze intrinsic
add freeze intrinsic
Tip revision: c722927
aotcompile.cpp
// This file is a part of Julia. License is MIT: https://julialang.org/license
#include "llvm-version.h"
#include "platform.h"
// target support
#include <llvm/ADT/Triple.h>
#include <llvm/Support/TargetRegistry.h>
#include <llvm/Target/TargetMachine.h>
#include <llvm/IR/DataLayout.h>
#include <llvm/Analysis/TargetTransformInfo.h>
#include <llvm/Analysis/TargetLibraryInfo.h>
// analysis passes
#include <llvm/Analysis/Passes.h>
#include <llvm/Analysis/BasicAliasAnalysis.h>
#include <llvm/Analysis/TypeBasedAliasAnalysis.h>
#include <llvm/Analysis/ScopedNoAliasAA.h>
#include <llvm/IR/Verifier.h>
#include <llvm/Transforms/IPO.h>
#include <llvm/Transforms/Scalar.h>
#include <llvm/Transforms/Vectorize.h>
#include <llvm/Transforms/Instrumentation/AddressSanitizer.h>
#include <llvm/Transforms/Instrumentation/ThreadSanitizer.h>
#include <llvm/Transforms/Scalar/GVN.h>
#include <llvm/Transforms/IPO/AlwaysInliner.h>
#include <llvm/Transforms/InstCombine/InstCombine.h>
#include <llvm/Transforms/Scalar/InstSimplifyPass.h>
#if defined(USE_POLLY)
#include <polly/RegisterPasses.h>
#include <polly/LinkAllPasses.h>
#include <polly/CodeGen/CodegenCleanup.h>
#if defined(USE_POLLY_ACC)
#include <polly/Support/LinkGPURuntime.h>
#endif
#endif
// for outputting assembly
#include <llvm/Bitcode/BitcodeWriter.h>
#include <llvm/Bitcode/BitcodeWriterPass.h>
#include "llvm/Object/ArchiveWriter.h"
#include <llvm/IR/IRPrintingPasses.h>
#include <llvm/CodeGen/AsmPrinter.h>
#include <llvm/CodeGen/MachineModuleInfo.h>
#include <llvm/CodeGen/TargetPassConfig.h>
#include <llvm/MC/MCAsmInfo.h>
#include <llvm/MC/MCStreamer.h>
#include <llvm/MC/MCAsmBackend.h>
#include <llvm/MC/MCCodeEmitter.h>
#if JL_LLVM_VERSION >= 100000
#include <llvm/Support/CodeGen.h>
#endif
#include <llvm/IR/LegacyPassManagers.h>
#include <llvm/Transforms/Utils/Cloning.h>
using namespace llvm;
// our passes
namespace llvm {
extern Pass *createLowerSimdLoopPass();
}
#if JL_LLVM_VERSION < 100000
static const TargetMachine::CodeGenFileType CGFT_ObjectFile = TargetMachine::CGFT_ObjectFile;
static const TargetMachine::CodeGenFileType CGFT_AssemblyFile = TargetMachine::CGFT_AssemblyFile;
#endif
#include "julia.h"
#include "julia_internal.h"
#include "jitlayers.h"
#include "julia_assert.h"
// MSVC's link.exe requires each function declaration to have a Comdat section
// So rather than litter the code with conditionals,
// all global values that get emitted call this function
// and it decides whether the definition needs a Comdat section and adds the appropriate declaration
template<class T> // for GlobalObject's
static T *addComdat(T *G)
{
#if defined(_OS_WINDOWS_)
if (!G->isDeclaration()) {
// Add comdat information to make MSVC link.exe happy
// it's valid to emit this for ld.exe too,
// but makes it very slow to link for no benefit
#if defined(_COMPILER_MICROSOFT_)
Comdat *jl_Comdat = G->getParent()->getOrInsertComdat(G->getName());
// ELF only supports Comdat::Any
jl_Comdat->setSelectionKind(Comdat::NoDuplicates);
G->setComdat(jl_Comdat);
#endif
// add __declspec(dllexport) to everything marked for export
if (G->getLinkage() == GlobalValue::ExternalLinkage)
G->setDLLStorageClass(GlobalValue::DLLExportStorageClass);
else
G->setDLLStorageClass(GlobalValue::DefaultStorageClass);
}
#endif
return G;
}
typedef struct {
std::unique_ptr<Module> M;
std::vector<GlobalValue*> jl_sysimg_fvars;
std::vector<GlobalValue*> jl_sysimg_gvars;
std::map<jl_code_instance_t*, std::tuple<uint32_t, uint32_t>> jl_fvar_map;
std::map<void*, int32_t> jl_value_to_llvm; // uses 1-based indexing
} jl_native_code_desc_t;
extern "C" JL_DLLEXPORT
void jl_get_function_id(void *native_code, jl_code_instance_t *codeinst,
int32_t *func_idx, int32_t *specfunc_idx)
{
jl_native_code_desc_t *data = (jl_native_code_desc_t*)native_code;
if (data) {
// get the function index in the fvar lookup table
auto it = data->jl_fvar_map.find(codeinst);
if (it != data->jl_fvar_map.end()) {
std::tie(*func_idx, *specfunc_idx) = it->second;
}
}
}
extern "C"
int32_t jl_get_llvm_gv(void *native_code, jl_value_t *p)
{
// map a jl_value_t memory location to a GlobalVariable
jl_native_code_desc_t *data = (jl_native_code_desc_t*)native_code;
if (data) {
auto it = data->jl_value_to_llvm.find(p);
if (it != data->jl_value_to_llvm.end()) {
return it->second;
}
}
return 0;
}
extern "C" JL_DLLEXPORT
Module* jl_get_llvm_module(void *native_code)
{
jl_native_code_desc_t *data = (jl_native_code_desc_t*)native_code;
if (data)
return data->M.get();
else
return NULL;
}
extern "C" JL_DLLEXPORT
GlobalValue* jl_get_llvm_function(void *native_code, uint32_t idx)
{
jl_native_code_desc_t *data = (jl_native_code_desc_t*)native_code;
if (data)
return data->jl_sysimg_fvars[idx];
else
return NULL;
}
extern "C" JL_DLLEXPORT
LLVMContext* jl_get_llvm_context(void *native_code)
{
jl_native_code_desc_t *data = (jl_native_code_desc_t*)native_code;
if (data)
return &data->M->getContext();
else
return NULL;
}
static void emit_offset_table(Module &mod, const std::vector<GlobalValue*> &vars, StringRef name, Type *T_psize)
{
// Emit a global variable with all the variable addresses.
// The cloning pass will convert them into offsets.
assert(!vars.empty());
size_t nvars = vars.size();
std::vector<Constant*> addrs(nvars);
for (size_t i = 0; i < nvars; i++) {
Constant *var = vars[i];
addrs[i] = ConstantExpr::getBitCast(var, T_psize);
}
ArrayType *vars_type = ArrayType::get(T_psize, nvars);
new GlobalVariable(mod, vars_type, true,
GlobalVariable::ExternalLinkage,
ConstantArray::get(vars_type, addrs),
name);
}
static bool is_safe_char(unsigned char c)
{
return ('0' <= c && c <= '9') ||
('A' <= c && c <= 'Z') ||
('a' <= c && c <= 'z') ||
(c == '_' || c == '$') ||
(c >= 128 && c < 255);
}
static const char hexchars[16] = {
'0', '1', '2', '3', '4', '5', '6', '7',
'8', '9', 'A', 'B', 'C', 'D', 'E', 'F' };
static const char *const common_names[256] = {
// 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, a, b, c, d, e, f
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x00
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x10
"SP", "NOT", "DQT", "YY", 0, "REM", "AND", "SQT", // 0x20
"LPR", "RPR", "MUL", "SUM", 0, "SUB", "DOT", "DIV", // 0x28
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, "COL", 0, "LT", "EQ", "GT", "QQ", // 0x30
"AT", 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x40
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, "LBR", "RDV", "RBR", "POW", 0, // 0x50
"TIC", 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x60
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, "LCR", "OR", "RCR", "TLD", "DEL", // 0x70
0 }; // remainder is filled with zeros, though are also all safe characters
// reversibly removes special characters from the name of GlobalObjects,
// which might cause them to be treated special by LLVM or the system linker
// the only non-identifier characters we allow to appear are '.' and '$',
// and all of UTF-8 above code-point 128 (except 255)
// most are given "friendly" abbreviations
// the remaining few will print as hex
// e.g. mangles "llvm.a≠a$a!a##" as "llvmDOT.a≠a$aNOT.aYY.YY."
static void makeSafeName(GlobalObject &G)
{
StringRef Name = G.getName();
SmallVector<char, 32> SafeName;
for (unsigned char c : Name.bytes()) {
if (is_safe_char(c)) {
SafeName.push_back(c);
}
else {
if (common_names[c]) {
SafeName.push_back(common_names[c][0]);
SafeName.push_back(common_names[c][1]);
if (common_names[c][2])
SafeName.push_back(common_names[c][2]);
}
else {
SafeName.push_back(hexchars[(c >> 4) & 0xF]);
SafeName.push_back(hexchars[c & 0xF]);
}
SafeName.push_back('.');
}
}
if (SafeName.size() != Name.size())
G.setName(StringRef(SafeName.data(), SafeName.size()));
}
static void jl_ci_cache_lookup(const jl_cgparams_t &cgparams, jl_method_instance_t *mi, size_t world, jl_code_instance_t **ci_out, jl_code_info_t **src_out)
{
jl_value_t *ci = cgparams.lookup(mi, world, world);
JL_GC_PROMISE_ROOTED(ci);
jl_code_instance_t *codeinst = NULL;
if (ci != jl_nothing) {
codeinst = (jl_code_instance_t*)ci;
*src_out = (jl_code_info_t*)codeinst->inferred;
jl_method_t *def = codeinst->def->def.method;
if ((jl_value_t*)*src_out == jl_nothing)
*src_out = NULL;
if (*src_out && jl_is_method(def))
*src_out = jl_uncompress_ir(def, codeinst, (jl_array_t*)*src_out);
}
if (*src_out == NULL || !jl_is_code_info(*src_out)) {
if (cgparams.lookup != jl_rettype_inferred) {
jl_error("Refusing to automatically run type inference with custom cache lookup.");
}
else {
*src_out = jl_type_infer(mi, world, 0);
if (*src_out) {
codeinst = jl_get_method_inferred(mi, (*src_out)->rettype, (*src_out)->min_world, (*src_out)->max_world);
if ((*src_out)->inferred && !codeinst->inferred)
codeinst->inferred = jl_nothing;
}
}
}
*ci_out = codeinst;
}
// takes the running content that has collected in the shadow module and dump it to disk
// this builds the object file portion of the sysimage files for fast startup, and can
// also be used be extern consumers like GPUCompiler.jl to obtain a module containing
// all reachable & inferrrable functions. The `policy` flag switches between the defaul
// mode `0` and the extern mode `1`.
extern "C" JL_DLLEXPORT
void *jl_create_native(jl_array_t *methods, const jl_cgparams_t cgparams, int _policy)
{
jl_native_code_desc_t *data = new jl_native_code_desc_t;
jl_codegen_params_t params;
params.params = &cgparams;
std::map<jl_code_instance_t*, jl_compile_result_t> emitted;
jl_method_instance_t *mi = NULL;
jl_code_info_t *src = NULL;
JL_GC_PUSH1(&src);
JL_LOCK(&codegen_lock);
uint64_t compiler_start_time = jl_hrtime();
CompilationPolicy policy = (CompilationPolicy) _policy;
std::unique_ptr<Module> clone(jl_create_llvm_module("text"));
// compile all methods for the current world and type-inference world
size_t compile_for[] = { jl_typeinf_world, jl_world_counter };
for (int worlds = 0; worlds < 2; worlds++) {
params.world = compile_for[worlds];
if (!params.world)
continue;
// Don't emit methods for the typeinf_world with extern policy
if (policy == CompilationPolicy::Extern && params.world == jl_typeinf_world)
continue;
size_t i, l;
for (i = 0, l = jl_array_len(methods); i < l; i++) {
// each item in this list is either a MethodInstance indicating something
// to compile, or an svec(rettype, sig) describing a C-callable alias to create.
jl_value_t *item = jl_array_ptr_ref(methods, i);
if (jl_is_simplevector(item)) {
if (worlds == 1)
jl_compile_extern_c(clone.get(), ¶ms, NULL, jl_svecref(item, 0), jl_svecref(item, 1));
continue;
}
mi = (jl_method_instance_t*)item;
src = NULL;
// if this method is generally visible to the current compilation world,
// and this is either the primary world, or not applicable in the primary world
// then we want to compile and emit this
if (mi->def.method->primary_world <= params.world && params.world <= mi->def.method->deleted_world) {
// find and prepare the source code to compile
jl_code_instance_t *codeinst = NULL;
jl_ci_cache_lookup(cgparams, mi, params.world, &codeinst, &src);
if (src && !emitted.count(codeinst)) {
// now add it to our compilation results
JL_GC_PROMISE_ROOTED(codeinst->rettype);
jl_compile_result_t result = jl_emit_code(mi, src, codeinst->rettype, params);
if (std::get<0>(result))
emitted[codeinst] = std::move(result);
}
}
}
// finally, make sure all referenced methods also get compiled or fixed up
jl_compile_workqueue(emitted, params, policy);
}
JL_GC_POP();
// process the globals array, before jl_merge_module destroys them
std::vector<std::string> gvars;
for (auto &global : params.globals) {
gvars.push_back(std::string(global.second->getName()));
data->jl_value_to_llvm[global.first] = gvars.size();
}
// clones the contents of the module `m` to the shadow_output collector
// while examining and recording what kind of function pointer we have
for (auto &def : emitted) {
jl_merge_module(clone.get(), std::move(std::get<0>(def.second)));
jl_code_instance_t *this_code = def.first;
jl_llvm_functions_t decls = std::get<1>(def.second);
StringRef func = decls.functionObject;
StringRef cfunc = decls.specFunctionObject;
uint32_t func_id = 0;
uint32_t cfunc_id = 0;
if (func == "jl_fptr_args") {
func_id = -1;
}
else if (func == "jl_fptr_sparam") {
func_id = -2;
}
else {
data->jl_sysimg_fvars.push_back(cast<Function>(clone->getNamedValue(func)));
func_id = data->jl_sysimg_fvars.size();
}
if (!cfunc.empty()) {
data->jl_sysimg_fvars.push_back(cast<Function>(clone->getNamedValue(cfunc)));
cfunc_id = data->jl_sysimg_fvars.size();
}
data->jl_fvar_map[this_code] = std::make_tuple(func_id, cfunc_id);
}
if (params._shared_module) {
std::unique_ptr<Module> shared(params._shared_module);
params._shared_module = NULL;
jl_merge_module(clone.get(), std::move(shared));
}
// now get references to the globals in the merged module
// and set them to be internalized and initialized at startup
for (auto &global : gvars) {
GlobalVariable *G = cast<GlobalVariable>(clone->getNamedValue(global));
G->setInitializer(ConstantPointerNull::get(cast<PointerType>(G->getValueType())));
G->setLinkage(GlobalVariable::InternalLinkage);
data->jl_sysimg_gvars.push_back(G);
}
#if defined(_OS_WINDOWS_) && defined(_CPU_X86_64_)
// setting the function personality enables stack unwinding and catching exceptions
// so make sure everything has something set
Type *T_int32 = Type::getInt32Ty(clone->getContext());
Function *juliapersonality_func =
Function::Create(FunctionType::get(T_int32, true),
Function::ExternalLinkage, "__julia_personality", clone.get());
juliapersonality_func->setDLLStorageClass(GlobalValue::DLLImportStorageClass);
#endif
// move everything inside, now that we've merged everything
// (before adding the exported headers)
for (GlobalObject &G : clone->global_objects()) {
if (!G.isDeclaration()) {
G.setLinkage(Function::InternalLinkage);
makeSafeName(G);
addComdat(&G);
#if defined(_OS_WINDOWS_) && defined(_CPU_X86_64_)
// Add unwind exception personalities to functions to handle async exceptions
if (Function *F = dyn_cast<Function>(&G))
F->setPersonalityFn(juliapersonality_func);
#endif
}
}
data->M = std::move(clone);
jl_cumulative_compile_time += (jl_hrtime() - compiler_start_time);
JL_UNLOCK(&codegen_lock); // Might GC
return (void*)data;
}
static void emit_result(std::vector<NewArchiveMember> &Archive, SmallVectorImpl<char> &OS,
StringRef Name, std::vector<std::string> &outputs)
{
outputs.push_back({ OS.data(), OS.size() });
Archive.push_back(NewArchiveMember(MemoryBufferRef(outputs.back(), Name)));
OS.clear();
}
static object::Archive::Kind getDefaultForHost(Triple &triple)
{
if (triple.isOSDarwin())
return object::Archive::K_DARWIN;
return object::Archive::K_GNU;
}
typedef Error ArchiveWriterError;
static void reportWriterError(const ErrorInfoBase &E)
{
std::string err = E.message();
jl_safe_printf("ERROR: failed to emit output file %s\n", err.c_str());
}
// takes the running content that has collected in the shadow module and dump it to disk
// this builds the object file portion of the sysimage files for fast startup
extern "C"
void jl_dump_native(void *native_code,
const char *bc_fname, const char *unopt_bc_fname, const char *obj_fname,
const char *asm_fname,
const char *sysimg_data, size_t sysimg_len)
{
JL_TIMING(NATIVE_DUMP);
jl_native_code_desc_t *data = (jl_native_code_desc_t*)native_code;
LLVMContext &Context = data->M->getContext();
// We don't want to use MCJIT's target machine because
// it uses the large code model and we may potentially
// want less optimizations there.
Triple TheTriple = Triple(jl_TargetMachine->getTargetTriple());
// make sure to emit the native object format, even if FORCE_ELF was set in codegen
#if defined(_OS_WINDOWS_)
TheTriple.setObjectFormat(Triple::COFF);
#elif defined(_OS_DARWIN_)
TheTriple.setObjectFormat(Triple::MachO);
TheTriple.setOS(llvm::Triple::MacOSX);
#endif
std::unique_ptr<TargetMachine> TM(
jl_TargetMachine->getTarget().createTargetMachine(
TheTriple.getTriple(),
jl_TargetMachine->getTargetCPU(),
jl_TargetMachine->getTargetFeatureString(),
jl_TargetMachine->Options,
#if defined(_OS_LINUX_) || defined(_OS_FREEBSD_)
Reloc::PIC_,
#else
Optional<Reloc::Model>(),
#endif
#if defined(_CPU_PPC_) || defined(_CPU_PPC64_)
// On PPC the small model is limited to 16bit offsets
CodeModel::Medium,
#else
// Use small model so that we can use signed 32bits offset in the function and GV tables
CodeModel::Small,
#endif
CodeGenOpt::Aggressive // -O3 TODO: respect command -O0 flag?
));
legacy::PassManager PM;
addTargetPasses(&PM, TM.get());
// set up optimization passes
SmallVector<char, 128> bc_Buffer;
SmallVector<char, 128> obj_Buffer;
SmallVector<char, 128> asm_Buffer;
SmallVector<char, 128> unopt_bc_Buffer;
raw_svector_ostream bc_OS(bc_Buffer);
raw_svector_ostream obj_OS(obj_Buffer);
raw_svector_ostream asm_OS(asm_Buffer);
raw_svector_ostream unopt_bc_OS(unopt_bc_Buffer);
std::vector<NewArchiveMember> bc_Archive;
std::vector<NewArchiveMember> obj_Archive;
std::vector<NewArchiveMember> asm_Archive;
std::vector<NewArchiveMember> unopt_bc_Archive;
std::vector<std::string> outputs;
if (unopt_bc_fname)
PM.add(createBitcodeWriterPass(unopt_bc_OS));
if (bc_fname || obj_fname || asm_fname) {
addOptimizationPasses(&PM, jl_options.opt_level, true, true);
addMachinePasses(&PM, TM.get());
}
if (bc_fname)
PM.add(createBitcodeWriterPass(bc_OS));
if (obj_fname)
if (TM->addPassesToEmitFile(PM, obj_OS, nullptr, CGFT_ObjectFile, false))
jl_safe_printf("ERROR: target does not support generation of object files\n");
if (asm_fname)
if (TM->addPassesToEmitFile(PM, asm_OS, nullptr, CGFT_AssemblyFile, false))
jl_safe_printf("ERROR: target does not support generation of object files\n");
// Reset the target triple to make sure it matches the new target machine
data->M->setTargetTriple(TM->getTargetTriple().str());
DataLayout DL = TM->createDataLayout();
DL.reset(DL.getStringRepresentation() + "-ni:10:11:12:13");
data->M->setDataLayout(DL);
Type *T_size;
if (sizeof(size_t) == 8)
T_size = Type::getInt64Ty(Context);
else
T_size = Type::getInt32Ty(Context);
Type *T_psize = T_size->getPointerTo();
// add metadata information
if (imaging_mode) {
emit_offset_table(*data->M, data->jl_sysimg_gvars, "jl_sysimg_gvars", T_psize);
emit_offset_table(*data->M, data->jl_sysimg_fvars, "jl_sysimg_fvars", T_psize);
// reflect the address of the jl_RTLD_DEFAULT_handle variable
// back to the caller, so that we can check for consistency issues
GlobalValue *jlRTLD_DEFAULT_var = jl_emit_RTLD_DEFAULT_var(data->M.get());
addComdat(new GlobalVariable(*data->M,
jlRTLD_DEFAULT_var->getType(),
true,
GlobalVariable::ExternalLinkage,
jlRTLD_DEFAULT_var,
"jl_RTLD_DEFAULT_handle_pointer"));
}
// do the actual work
auto add_output = [&] (Module &M, StringRef unopt_bc_Name, StringRef bc_Name, StringRef obj_Name, StringRef asm_Name) {
PM.run(M);
if (unopt_bc_fname)
emit_result(unopt_bc_Archive, unopt_bc_Buffer, unopt_bc_Name, outputs);
if (bc_fname)
emit_result(bc_Archive, bc_Buffer, bc_Name, outputs);
if (obj_fname)
emit_result(obj_Archive, obj_Buffer, obj_Name, outputs);
if (asm_fname)
emit_result(asm_Archive, asm_Buffer, asm_Name, outputs);
};
add_output(*data->M, "unopt.bc", "text.bc", "text.o", "text.s");
std::unique_ptr<Module> sysimage(new Module("sysimage", Context));
sysimage->setTargetTriple(data->M->getTargetTriple());
sysimage->setDataLayout(data->M->getDataLayout());
data->M.reset(); // free memory for data->M
if (sysimg_data) {
Constant *data = ConstantDataArray::get(Context,
ArrayRef<uint8_t>((const unsigned char*)sysimg_data, sysimg_len));
addComdat(new GlobalVariable(*sysimage, data->getType(), false,
GlobalVariable::ExternalLinkage,
data, "jl_system_image_data"))->setAlignment(Align(64));
Constant *len = ConstantInt::get(T_size, sysimg_len);
addComdat(new GlobalVariable(*sysimage, len->getType(), true,
GlobalVariable::ExternalLinkage,
len, "jl_system_image_size"));
}
add_output(*sysimage, "data.bc", "data.bc", "data.o", "data.s");
object::Archive::Kind Kind = getDefaultForHost(TheTriple);
if (unopt_bc_fname)
handleAllErrors(writeArchive(unopt_bc_fname, unopt_bc_Archive, true,
Kind, true, false), reportWriterError);
if (bc_fname)
handleAllErrors(writeArchive(bc_fname, bc_Archive, true,
Kind, true, false), reportWriterError);
if (obj_fname)
handleAllErrors(writeArchive(obj_fname, obj_Archive, true,
Kind, true, false), reportWriterError);
if (asm_fname)
handleAllErrors(writeArchive(asm_fname, asm_Archive, true,
Kind, true, false), reportWriterError);
delete data;
}
void addTargetPasses(legacy::PassManagerBase *PM, TargetMachine *TM)
{
PM->add(new TargetLibraryInfoWrapperPass(Triple(TM->getTargetTriple())));
PM->add(createTargetTransformInfoWrapperPass(TM->getTargetIRAnalysis()));
}
void addMachinePasses(legacy::PassManagerBase *PM, TargetMachine *TM)
{
// TODO: don't do this on CPUs that natively support Float16
PM->add(createDemoteFloat16Pass());
PM->add(createGVNPass());
}
// this defines the set of optimization passes defined for Julia at various optimization levels.
// it assumes that the TLI and TTI wrapper passes have already been added.
void addOptimizationPasses(legacy::PassManagerBase *PM, int opt_level,
bool lower_intrinsics, bool dump_native)
{
#ifdef JL_DEBUG_BUILD
PM->add(createGCInvariantVerifierPass(true));
PM->add(createVerifierPass());
#endif
PM->add(createConstantMergePass());
if (opt_level < 2) {
PM->add(createCFGSimplificationPass());
if (opt_level == 1) {
PM->add(createSROAPass());
PM->add(createInstructionCombiningPass());
PM->add(createEarlyCSEPass());
// maybe add GVN?
// also try GVNHoist and GVNSink
}
PM->add(createMemCpyOptPass());
PM->add(createAlwaysInlinerLegacyPass()); // Respect always_inline
PM->add(createLowerSimdLoopPass()); // Annotate loop marked with "loopinfo" as LLVM parallel loop
if (lower_intrinsics) {
PM->add(createBarrierNoopPass());
PM->add(createLowerExcHandlersPass());
PM->add(createGCInvariantVerifierPass(false));
PM->add(createRemoveNIPass());
PM->add(createLateLowerGCFramePass());
PM->add(createFinalLowerGCPass());
PM->add(createLowerPTLSPass(dump_native));
}
else {
PM->add(createRemoveNIPass());
}
PM->add(createLowerSimdLoopPass()); // Annotate loop marked with "loopinfo" as LLVM parallel loop
if (dump_native)
PM->add(createMultiVersioningPass());
#if defined(JL_ASAN_ENABLED)
PM->add(createAddressSanitizerFunctionPass());
#endif
#if defined(JL_MSAN_ENABLED)
PM->add(createMemorySanitizerPass(true));
#endif
#if defined(JL_TSAN_ENABLED)
PM->add(createThreadSanitizerLegacyPassPass());
#endif
return;
}
PM->add(createPropagateJuliaAddrspaces());
PM->add(createScopedNoAliasAAWrapperPass());
PM->add(createTypeBasedAAWrapperPass());
if (opt_level >= 3) {
PM->add(createBasicAAWrapperPass());
}
PM->add(createCFGSimplificationPass());
PM->add(createDeadCodeEliminationPass());
PM->add(createSROAPass());
//PM->add(createMemCpyOptPass());
PM->add(createAlwaysInlinerLegacyPass()); // Respect always_inline
// Running `memcpyopt` between this and `sroa` seems to give `sroa` a hard time
// merging the `alloca` for the unboxed data and the `alloca` created by the `alloc_opt`
// pass.
PM->add(createAllocOptPass());
// consider AggressiveInstCombinePass at optlevel > 2
PM->add(createInstructionCombiningPass());
PM->add(createCFGSimplificationPass());
if (dump_native)
PM->add(createMultiVersioningPass());
PM->add(createSROAPass());
PM->add(createInstSimplifyLegacyPass());
PM->add(createJumpThreadingPass());
PM->add(createReassociatePass());
PM->add(createEarlyCSEPass());
// Load forwarding above can expose allocations that aren't actually used
// remove those before optimizing loops.
PM->add(createAllocOptPass());
PM->add(createLoopRotatePass());
// moving IndVarSimplify here prevented removing the loop in perf_sumcartesian(10:-1:1)
PM->add(createLoopIdiomPass());
#ifdef USE_POLLY
// LCSSA (which has already run at this point due to the dependencies of the
// above passes) introduces redundant phis that hinder Polly. Therefore we
// run InstCombine here to remove them.
PM->add(createInstructionCombiningPass());
PM->add(polly::createCodePreparationPass());
polly::registerPollyPasses(*PM);
PM->add(polly::createCodegenCleanupPass());
#endif
// LoopRotate strips metadata from terminator, so run LowerSIMD afterwards
PM->add(createLowerSimdLoopPass()); // Annotate loop marked with "loopinfo" as LLVM parallel loop
PM->add(createLICMPass());
PM->add(createJuliaLICMPass());
PM->add(createLoopUnswitchPass());
PM->add(createLICMPass());
PM->add(createJuliaLICMPass());
// Subsequent passes not stripping metadata from terminator
PM->add(createInstSimplifyLegacyPass());
PM->add(createIndVarSimplifyPass());
PM->add(createLoopDeletionPass());
PM->add(createSimpleLoopUnrollPass());
// Run our own SROA on heap objects before LLVM's
PM->add(createAllocOptPass());
// Re-run SROA after loop-unrolling (useful for small loops that operate,
// over the structure of an aggregate)
PM->add(createSROAPass());
// might not be necessary:
PM->add(createInstSimplifyLegacyPass());
PM->add(createGVNPass());
PM->add(createMemCpyOptPass());
PM->add(createSCCPPass());
// Run instcombine after redundancy elimination to exploit opportunities
// opened up by them.
// This needs to be InstCombine instead of InstSimplify to allow
// loops over Union-typed arrays to vectorize.
PM->add(createInstructionCombiningPass());
PM->add(createJumpThreadingPass());
PM->add(createDeadStoreEliminationPass());
// More dead allocation (store) deletion before loop optimization
// consider removing this:
PM->add(createAllocOptPass());
// see if all of the constant folding has exposed more loops
// to simplification and deletion
// this helps significantly with cleaning up iteration
PM->add(createCFGSimplificationPass());
PM->add(createLoopDeletionPass());
PM->add(createInstructionCombiningPass());
PM->add(createLoopVectorizePass());
PM->add(createLoopLoadEliminationPass());
PM->add(createCFGSimplificationPass());
PM->add(createSLPVectorizerPass());
// might need this after LLVM 11:
//PM->add(createVectorCombinePass());
PM->add(createAggressiveDCEPass());
if (lower_intrinsics) {
// LowerPTLS removes an indirect call. As a result, it is likely to trigger
// LLVM's devirtualization heuristics, which would result in the entire
// pass pipeline being re-exectuted. Prevent this by inserting a barrier.
PM->add(createBarrierNoopPass());
PM->add(createLowerExcHandlersPass());
PM->add(createGCInvariantVerifierPass(false));
// Needed **before** LateLowerGCFrame on LLVM < 12
// due to bug in `CreateAlignmentAssumption`.
PM->add(createRemoveNIPass());
PM->add(createLateLowerGCFramePass());
PM->add(createFinalLowerGCPass());
// We need these two passes and the instcombine below
// after GC lowering to let LLVM do some constant propagation on the tags.
// and remove some unnecessary write barrier checks.
PM->add(createGVNPass());
PM->add(createSCCPPass());
// Remove dead use of ptls
PM->add(createDeadCodeEliminationPass());
PM->add(createLowerPTLSPass(dump_native));
PM->add(createInstructionCombiningPass());
// Clean up write barrier and ptls lowering
PM->add(createCFGSimplificationPass());
}
else {
PM->add(createRemoveNIPass());
}
PM->add(createCombineMulAddPass());
PM->add(createDivRemPairsPass());
#if defined(JL_ASAN_ENABLED)
PM->add(createAddressSanitizerFunctionPass());
#endif
#if defined(JL_MSAN_ENABLED)
PM->add(createMemorySanitizerPass(true));
#endif
#if defined(JL_TSAN_ENABLED)
PM->add(createThreadSanitizerLegacyPassPass());
#endif
}
// An LLVM module pass that just runs all julia passes in order. Useful for
// debugging
template <int OptLevel>
class JuliaPipeline : public Pass {
public:
static char ID;
// A bit of a hack, but works
struct TPMAdapter : public PassManagerBase {
PMTopLevelManager *TPM;
TPMAdapter(PMTopLevelManager *TPM) : TPM(TPM) {}
void add(Pass *P) { TPM->schedulePass(P); }
};
void preparePassManager(PMStack &Stack) override {
(void)jl_init_llvm();
PMTopLevelManager *TPM = Stack.top()->getTopLevelManager();
TPMAdapter Adapter(TPM);
addTargetPasses(&Adapter, jl_TargetMachine);
addOptimizationPasses(&Adapter, OptLevel);
addMachinePasses(&Adapter, jl_TargetMachine);
}
JuliaPipeline() : Pass(PT_PassManager, ID) {}
Pass *createPrinterPass(raw_ostream &O, const std::string &Banner) const override {
return createPrintModulePass(O, Banner);
}
};
template<> char JuliaPipeline<0>::ID = 0;
template<> char JuliaPipeline<2>::ID = 0;
template<> char JuliaPipeline<3>::ID = 0;
static RegisterPass<JuliaPipeline<0>> X("juliaO0", "Runs the entire julia pipeline (at -O0)", false, false);
static RegisterPass<JuliaPipeline<2>> Y("julia", "Runs the entire julia pipeline (at -O2)", false, false);
static RegisterPass<JuliaPipeline<3>> Z("juliaO3", "Runs the entire julia pipeline (at -O3)", false, false);
extern "C" JL_DLLEXPORT
void jl_add_optimization_passes(LLVMPassManagerRef PM, int opt_level, int lower_intrinsics) {
addOptimizationPasses(unwrap(PM), opt_level, lower_intrinsics);
}
// --- native code info, and dump function to IR and ASM ---
// Get pointer to llvm::Function instance, compiling if necessary
// for use in reflection from Julia.
// this is paired with jl_dump_function_ir, jl_dump_method_asm, jl_dump_llvm_asm in particular ways:
// misuse will leak memory or cause read-after-free
extern "C" JL_DLLEXPORT
void *jl_get_llvmf_defn(jl_method_instance_t *mi, size_t world, char getwrapper, char optimize, const jl_cgparams_t params)
{
if (jl_is_method(mi->def.method) && mi->def.method->source == NULL &&
mi->def.method->generator == NULL) {
// not a generic function
return NULL;
}
static legacy::PassManager *PM;
if (!PM) {
PM = new legacy::PassManager();
addTargetPasses(PM, jl_TargetMachine);
addOptimizationPasses(PM, jl_options.opt_level);
addMachinePasses(PM, jl_TargetMachine);
}
// get the source code for this function
jl_value_t *jlrettype = (jl_value_t*)jl_any_type;
jl_code_info_t *src = NULL;
JL_GC_PUSH2(&src, &jlrettype);
jl_value_t *ci = jl_rettype_inferred(mi, world, world);
if (ci != jl_nothing) {
jl_code_instance_t *codeinst = (jl_code_instance_t*)ci;
src = (jl_code_info_t*)codeinst->inferred;
if ((jl_value_t*)src != jl_nothing && !jl_is_code_info(src) && jl_is_method(mi->def.method))
src = jl_uncompress_ir(mi->def.method, codeinst, (jl_array_t*)src);
jlrettype = codeinst->rettype;
}
if (!src || (jl_value_t*)src == jl_nothing) {
src = jl_type_infer(mi, world, 0);
if (src)
jlrettype = src->rettype;
else if (jl_is_method(mi->def.method)) {
src = mi->def.method->generator ? jl_code_for_staged(mi) : (jl_code_info_t*)mi->def.method->source;
if (src && !jl_is_code_info(src) && jl_is_method(mi->def.method))
src = jl_uncompress_ir(mi->def.method, NULL, (jl_array_t*)src);
}
// TODO: use mi->uninferred
}
// emit this function into a new llvm module
if (src && jl_is_code_info(src)) {
jl_codegen_params_t output;
output.world = world;
output.params = ¶ms;
std::unique_ptr<Module> m;
jl_llvm_functions_t decls;
JL_LOCK(&codegen_lock);
uint64_t compiler_start_time = jl_hrtime();
std::tie(m, decls) = jl_emit_code(mi, src, jlrettype, output);
Function *F = NULL;
if (m) {
// if compilation succeeded, prepare to return the result
// For imaging mode, global constants are currently private without initializer
// which isn't legal. Convert them to extern linkage so that the code can compile
// and will better match what's actually in sysimg.
for (auto &global : output.globals)
global.second->setLinkage(GlobalValue::ExternalLinkage);
if (optimize)
PM->run(*m.get());
const std::string *fname;
if (decls.functionObject == "jl_fptr_args" || decls.functionObject == "jl_fptr_sparam")
getwrapper = false;
if (!getwrapper)
fname = &decls.specFunctionObject;
else
fname = &decls.functionObject;
F = cast<Function>(m->getNamedValue(*fname));
m.release(); // the return object `llvmf` will be the owning pointer
}
JL_GC_POP();
jl_cumulative_compile_time += (jl_hrtime() - compiler_start_time);
JL_UNLOCK(&codegen_lock); // Might GC
if (F)
return F;
}
const char *mname = name_from_method_instance(mi);
jl_errorf("unable to compile source for function %s", mname);
}
/// addPassesToX helper drives creation and initialization of TargetPassConfig.
static MCContext *
addPassesToGenerateCode(LLVMTargetMachine *TM, PassManagerBase &PM) {
TargetPassConfig *PassConfig = TM->createPassConfig(PM);
PassConfig->setDisableVerify(false);
PM.add(PassConfig);
#if JL_LLVM_VERSION >= 100000
MachineModuleInfoWrapperPass *MMIWP =
new MachineModuleInfoWrapperPass(TM);
PM.add(MMIWP);
#else
MachineModuleInfo *MMI = new MachineModuleInfo(TM);
PM.add(MMI);
#endif
if (PassConfig->addISelPasses())
return NULL;
PassConfig->addMachinePasses();
PassConfig->setInitialized();
#if JL_LLVM_VERSION >= 100000
return &MMIWP->getMMI().getContext();
#else
return &MMI->getContext();
#endif
}
void jl_strip_llvm_debug(Module *m);
// get a native assembly for llvm::Function
// TODO: implement debuginfo handling
extern "C" JL_DLLEXPORT
jl_value_t *jl_dump_llvm_asm(void *F, const char* asm_variant, const char *debuginfo)
{
// precise printing via IR assembler
SmallVector<char, 4096> ObjBufferSV;
{ // scope block
Function *f = (Function*)F;
llvm::raw_svector_ostream asmfile(ObjBufferSV);
assert(!f->isDeclaration());
std::unique_ptr<Module> m(f->getParent());
for (auto &f2 : m->functions()) {
if (f != &f2 && !f->isDeclaration())
f2.deleteBody();
}
jl_strip_llvm_debug(m.get());
legacy::PassManager PM;
LLVMTargetMachine *TM = static_cast<LLVMTargetMachine*>(jl_TargetMachine);
MCContext *Context = addPassesToGenerateCode(TM, PM);
if (Context) {
const MCSubtargetInfo &STI = *TM->getMCSubtargetInfo();
const MCAsmInfo &MAI = *TM->getMCAsmInfo();
const MCRegisterInfo &MRI = *TM->getMCRegisterInfo();
const MCInstrInfo &MII = *TM->getMCInstrInfo();
unsigned OutputAsmDialect = MAI.getAssemblerDialect();
if (!strcmp(asm_variant, "att"))
OutputAsmDialect = 0;
if (!strcmp(asm_variant, "intel"))
OutputAsmDialect = 1;
MCInstPrinter *InstPrinter = TM->getTarget().createMCInstPrinter(
TM->getTargetTriple(), OutputAsmDialect, MAI, MII, MRI);
std::unique_ptr<MCAsmBackend> MAB(TM->getTarget().createMCAsmBackend(
STI, MRI, TM->Options.MCOptions));
std::unique_ptr<MCCodeEmitter> MCE;
#if JL_LLVM_VERSION >= 100000
auto FOut = std::make_unique<formatted_raw_ostream>(asmfile);
#else
auto FOut = llvm::make_unique<formatted_raw_ostream>(asmfile);
#endif
std::unique_ptr<MCStreamer> S(TM->getTarget().createAsmStreamer(
*Context, std::move(FOut), true,
true, InstPrinter,
std::move(MCE), std::move(MAB),
false));
std::unique_ptr<AsmPrinter> Printer(
TM->getTarget().createAsmPrinter(*TM, std::move(S)));
if (Printer) {
PM.add(Printer.release());
PM.run(*m);
}
}
}
return jl_pchar_to_string(ObjBufferSV.data(), ObjBufferSV.size());
}
