rtl.cpp
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//===-RTLs/generic-64bit/src/rtl.cpp - Target RTLs Implementation - C++ -*-===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// RTL for generic 64-bit machine
//
//===----------------------------------------------------------------------===//
#include <cassert>
#include <cstdio>
#include <cstring>
#include <cstdlib>
#include <dlfcn.h>
#include <ffi.h>
#include <gelf.h>
#include <link.h>
#include <list>
#include <string>
#include <vector>
#include "Debug.h"
#include "omptargetplugin.h"
#ifndef TARGET_NAME
#define TARGET_NAME Generic ELF - 64bit
#endif
#define DEBUG_PREFIX "TARGET " GETNAME(TARGET_NAME) " RTL"
#ifndef TARGET_ELF_ID
#define TARGET_ELF_ID 0
#endif
#include "../../common/elf_common.c"
#define NUMBER_OF_DEVICES 4
#define OFFLOADSECTIONNAME "omp_offloading_entries"
/// Array of Dynamic libraries loaded for this target.
struct DynLibTy {
char *FileName;
void *Handle;
};
/// Keep entries table per device.
struct FuncOrGblEntryTy {
__tgt_target_table Table;
};
/// Class containing all the device information.
class RTLDeviceInfoTy {
std::vector<std::list<FuncOrGblEntryTy>> FuncGblEntries;
public:
std::list<DynLibTy> DynLibs;
// Record entry point associated with device.
void createOffloadTable(int32_t device_id, __tgt_offload_entry *begin,
__tgt_offload_entry *end) {
assert(device_id < (int32_t)FuncGblEntries.size() &&
"Unexpected device id!");
FuncGblEntries[device_id].emplace_back();
FuncOrGblEntryTy &E = FuncGblEntries[device_id].back();
E.Table.EntriesBegin = begin;
E.Table.EntriesEnd = end;
}
// Return true if the entry is associated with device.
bool findOffloadEntry(int32_t device_id, void *addr) {
assert(device_id < (int32_t)FuncGblEntries.size() &&
"Unexpected device id!");
FuncOrGblEntryTy &E = FuncGblEntries[device_id].back();
for (__tgt_offload_entry *i = E.Table.EntriesBegin, *e = E.Table.EntriesEnd;
i < e; ++i) {
if (i->addr == addr)
return true;
}
return false;
}
// Return the pointer to the target entries table.
__tgt_target_table *getOffloadEntriesTable(int32_t device_id) {
assert(device_id < (int32_t)FuncGblEntries.size() &&
"Unexpected device id!");
FuncOrGblEntryTy &E = FuncGblEntries[device_id].back();
return &E.Table;
}
RTLDeviceInfoTy(int32_t num_devices) {
FuncGblEntries.resize(num_devices);
}
~RTLDeviceInfoTy() {
// Close dynamic libraries
for (auto &lib : DynLibs) {
if (lib.Handle) {
dlclose(lib.Handle);
remove(lib.FileName);
}
}
}
};
static RTLDeviceInfoTy DeviceInfo(NUMBER_OF_DEVICES);
#ifdef __cplusplus
extern "C" {
#endif
int32_t __tgt_rtl_is_valid_binary(__tgt_device_image *image) {
// If we don't have a valid ELF ID we can just fail.
#if TARGET_ELF_ID < 1
return 0;
#else
return elf_check_machine(image, TARGET_ELF_ID);
#endif
}
int32_t __tgt_rtl_number_of_devices() { return NUMBER_OF_DEVICES; }
int32_t __tgt_rtl_init_device(int32_t device_id) { return OFFLOAD_SUCCESS; }
__tgt_target_table *__tgt_rtl_load_binary(int32_t device_id,
__tgt_device_image *image) {
DP("Dev %d: load binary from " DPxMOD " image\n", device_id,
DPxPTR(image->ImageStart));
assert(device_id >= 0 && device_id < NUMBER_OF_DEVICES && "bad dev id");
size_t ImageSize = (size_t)image->ImageEnd - (size_t)image->ImageStart;
size_t NumEntries = (size_t)(image->EntriesEnd - image->EntriesBegin);
DP("Expecting to have %zd entries defined.\n", NumEntries);
// Is the library version incompatible with the header file?
if (elf_version(EV_CURRENT) == EV_NONE) {
DP("Incompatible ELF library!\n");
return NULL;
}
// Obtain elf handler
Elf *e = elf_memory((char *)image->ImageStart, ImageSize);
if (!e) {
DP("Unable to get ELF handle: %s!\n", elf_errmsg(-1));
return NULL;
}
if (elf_kind(e) != ELF_K_ELF) {
DP("Invalid Elf kind!\n");
elf_end(e);
return NULL;
}
// Find the entries section offset
Elf_Scn *section = 0;
Elf64_Off entries_offset = 0;
size_t shstrndx;
if (elf_getshdrstrndx(e, &shstrndx)) {
DP("Unable to get ELF strings index!\n");
elf_end(e);
return NULL;
}
while ((section = elf_nextscn(e, section))) {
GElf_Shdr hdr;
gelf_getshdr(section, &hdr);
if (!strcmp(elf_strptr(e, shstrndx, hdr.sh_name), OFFLOADSECTIONNAME)) {
entries_offset = hdr.sh_addr;
break;
}
}
if (!entries_offset) {
DP("Entries Section Offset Not Found\n");
elf_end(e);
return NULL;
}
DP("Offset of entries section is (" DPxMOD ").\n", DPxPTR(entries_offset));
// load dynamic library and get the entry points. We use the dl library
// to do the loading of the library, but we could do it directly to avoid the
// dump to the temporary file.
//
// 1) Create tmp file with the library contents.
// 2) Use dlopen to load the file and dlsym to retrieve the symbols.
char tmp_name[] = "/tmp/tmpfile_XXXXXX";
int tmp_fd = mkstemp(tmp_name);
if (tmp_fd == -1) {
elf_end(e);
return NULL;
}
FILE *ftmp = fdopen(tmp_fd, "wb");
if (!ftmp) {
elf_end(e);
return NULL;
}
fwrite(image->ImageStart, ImageSize, 1, ftmp);
fclose(ftmp);
DynLibTy Lib = {tmp_name, dlopen(tmp_name, RTLD_LAZY)};
if (!Lib.Handle) {
DP("Target library loading error: %s\n", dlerror());
elf_end(e);
return NULL;
}
DeviceInfo.DynLibs.push_back(Lib);
struct link_map *libInfo = (struct link_map *)Lib.Handle;
// The place where the entries info is loaded is the library base address
// plus the offset determined from the ELF file.
Elf64_Addr entries_addr = libInfo->l_addr + entries_offset;
DP("Pointer to first entry to be loaded is (" DPxMOD ").\n",
DPxPTR(entries_addr));
// Table of pointers to all the entries in the target.
__tgt_offload_entry *entries_table = (__tgt_offload_entry *)entries_addr;
__tgt_offload_entry *entries_begin = &entries_table[0];
__tgt_offload_entry *entries_end = entries_begin + NumEntries;
if (!entries_begin) {
DP("Can't obtain entries begin\n");
elf_end(e);
return NULL;
}
DP("Entries table range is (" DPxMOD ")->(" DPxMOD ")\n",
DPxPTR(entries_begin), DPxPTR(entries_end));
DeviceInfo.createOffloadTable(device_id, entries_begin, entries_end);
elf_end(e);
return DeviceInfo.getOffloadEntriesTable(device_id);
}
void *__tgt_rtl_data_alloc(int32_t device_id, int64_t size, void *hst_ptr) {
void *ptr = malloc(size);
return ptr;
}
int32_t __tgt_rtl_data_submit(int32_t device_id, void *tgt_ptr, void *hst_ptr,
int64_t size) {
memcpy(tgt_ptr, hst_ptr, size);
return OFFLOAD_SUCCESS;
}
int32_t __tgt_rtl_data_retrieve(int32_t device_id, void *hst_ptr, void *tgt_ptr,
int64_t size) {
memcpy(hst_ptr, tgt_ptr, size);
return OFFLOAD_SUCCESS;
}
int32_t __tgt_rtl_data_delete(int32_t device_id, void *tgt_ptr) {
free(tgt_ptr);
return OFFLOAD_SUCCESS;
}
int32_t __tgt_rtl_run_target_team_region(int32_t device_id, void *tgt_entry_ptr,
void **tgt_args,
ptrdiff_t *tgt_offsets,
int32_t arg_num, int32_t team_num,
int32_t thread_limit,
uint64_t loop_tripcount /*not used*/) {
// ignore team num and thread limit.
// Use libffi to launch execution.
ffi_cif cif;
// All args are references.
std::vector<ffi_type *> args_types(arg_num, &ffi_type_pointer);
std::vector<void *> args(arg_num);
std::vector<void *> ptrs(arg_num);
for (int32_t i = 0; i < arg_num; ++i) {
ptrs[i] = (void *)((intptr_t)tgt_args[i] + tgt_offsets[i]);
args[i] = &ptrs[i];
}
ffi_status status = ffi_prep_cif(&cif, FFI_DEFAULT_ABI, arg_num,
&ffi_type_void, &args_types[0]);
assert(status == FFI_OK && "Unable to prepare target launch!");
if (status != FFI_OK)
return OFFLOAD_FAIL;
DP("Running entry point at " DPxMOD "...\n", DPxPTR(tgt_entry_ptr));
void (*entry)(void);
*((void**) &entry) = tgt_entry_ptr;
ffi_call(&cif, entry, NULL, &args[0]);
return OFFLOAD_SUCCESS;
}
int32_t __tgt_rtl_run_target_region(int32_t device_id, void *tgt_entry_ptr,
void **tgt_args, ptrdiff_t *tgt_offsets,
int32_t arg_num) {
// use one team and one thread.
return __tgt_rtl_run_target_team_region(device_id, tgt_entry_ptr, tgt_args,
tgt_offsets, arg_num, 1, 1, 0);
}
#ifdef __cplusplus
}
#endif