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rpcs3/Utilities/JIT.cpp

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#include "util/types.hpp"
#include "util/sysinfo.hpp"
#include "JIT.h"
#include "StrFmt.h"
#include "File.h"
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#include "util/logs.hpp"
#include "mutex.h"
#include "util/vm.hpp"
#include "util/asm.hpp"
#include <charconv>
#include <zlib.h>
#ifdef __linux__
#define CAN_OVERCOMMIT
#endif
LOG_CHANNEL(jit_log, "JIT");
static u8* get_jit_memory()
{
// Reserve 2G memory (magic static)
static void* const s_memory2 = []() -> void*
{
void* ptr = utils::memory_reserve(0x80000000);
#ifdef CAN_OVERCOMMIT
utils::memory_commit(ptr, 0x80000000);
utils::memory_protect(ptr, 0x40000000, utils::protection::wx);
#endif
return ptr;
}();
return static_cast<u8*>(s_memory2);
}
// Allocation counters (1G code, 1G data subranges)
static atomic_t<u64> s_code_pos{0}, s_data_pos{0};
// Snapshot of code generated before main()
static std::vector<u8> s_code_init, s_data_init;
template <atomic_t<u64>& Ctr, uint Off, utils::protection Prot>
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static u8* add_jit_memory(usz size, uint align)
{
// Select subrange
u8* pointer = get_jit_memory() + Off;
if (!size && !align) [[unlikely]]
{
// Return subrange info
return pointer;
}
u64 olda, newa;
// Simple allocation by incrementing pointer to the next free data
const u64 pos = Ctr.atomic_op([&](u64& ctr) -> u64
{
const u64 _pos = utils::align(ctr & 0xffff'ffff, align);
const u64 _new = utils::align(_pos + size, align);
if (_new > 0x40000000) [[unlikely]]
{
// Sorry, we failed, and further attempts should fail too.
ctr |= 0x40000000;
return -1;
}
// Last allocation is stored in highest bits
olda = ctr >> 32;
newa = olda;
// Check the necessity to commit more memory
if (_new > olda) [[unlikely]]
{
newa = utils::align(_new, 0x200000);
}
ctr += _new - (ctr & 0xffff'ffff);
return _pos;
});
if (pos == umax) [[unlikely]]
{
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jit_log.error("Out of memory (size=0x%x, align=0x%x, off=0x%x)", size, align, Off);
return nullptr;
}
if (olda != newa) [[unlikely]]
{
#ifndef CAN_OVERCOMMIT
// Commit more memory
utils::memory_commit(pointer + olda, newa - olda, Prot);
#endif
// Acknowledge committed memory
Ctr.atomic_op([&](u64& ctr)
{
if ((ctr >> 32) < newa)
{
ctr += (newa - (ctr >> 32)) << 32;
}
});
}
return pointer + pos;
}
jit_runtime::jit_runtime()
: HostRuntime()
{
}
jit_runtime::~jit_runtime()
{
}
asmjit::Error jit_runtime::_add(void** dst, asmjit::CodeHolder* code) noexcept
{
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usz codeSize = code->getCodeSize();
if (!codeSize) [[unlikely]]
{
*dst = nullptr;
return asmjit::kErrorNoCodeGenerated;
}
void* p = jit_runtime::alloc(codeSize, 16);
if (!p) [[unlikely]]
{
*dst = nullptr;
return asmjit::kErrorNoVirtualMemory;
}
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usz relocSize = code->relocate(p);
if (!relocSize) [[unlikely]]
{
*dst = nullptr;
return asmjit::kErrorInvalidState;
}
flush(p, relocSize);
*dst = p;
return asmjit::kErrorOk;
}
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asmjit::Error jit_runtime::_release(void*) noexcept
{
return asmjit::kErrorOk;
}
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u8* jit_runtime::alloc(usz size, uint align, bool exec) noexcept
{
if (exec)
{
return add_jit_memory<s_code_pos, 0x0, utils::protection::wx>(size, align);
}
else
{
return add_jit_memory<s_data_pos, 0x40000000, utils::protection::rw>(size, align);
}
}
void jit_runtime::initialize()
{
if (!s_code_init.empty() || !s_data_init.empty())
{
return;
}
// Create code/data snapshot
s_code_init.resize(s_code_pos & 0xffff'ffff);
std::memcpy(s_code_init.data(), alloc(0, 0, true), s_code_init.size());
s_data_init.resize(s_data_pos & 0xffff'ffff);
std::memcpy(s_data_init.data(), alloc(0, 0, false), s_data_init.size());
}
void jit_runtime::finalize() noexcept
{
// Reset JIT memory
#ifdef CAN_OVERCOMMIT
utils::memory_reset(get_jit_memory(), 0x80000000);
utils::memory_protect(get_jit_memory(), 0x40000000, utils::protection::wx);
#else
utils::memory_decommit(get_jit_memory(), 0x80000000);
#endif
s_code_pos = 0;
s_data_pos = 0;
// Restore code/data snapshot
std::memcpy(alloc(s_code_init.size(), 1, true), s_code_init.data(), s_code_init.size());
std::memcpy(alloc(s_data_init.size(), 1, false), s_data_init.data(), s_data_init.size());
}
asmjit::Runtime& asmjit::get_global_runtime()
{
// 16 MiB for internal needs
static constexpr u64 size = 1024 * 1024 * 16;
struct custom_runtime final : asmjit::HostRuntime
{
custom_runtime() noexcept
{
// Search starting in first 2 GiB of memory
for (u64 addr = size;; addr += size)
{
if (auto ptr = utils::memory_reserve(size, reinterpret_cast<void*>(addr)))
{
m_pos.raw() = static_cast<std::byte*>(ptr);
break;
}
}
// Initialize "end" pointer
m_max = m_pos + size;
// Make memory writable + executable
utils::memory_commit(m_pos, size, utils::protection::wx);
}
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custom_runtime(const custom_runtime&) = delete;
custom_runtime& operator=(const custom_runtime&) = delete;
asmjit::Error _add(void** dst, asmjit::CodeHolder* code) noexcept override
{
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usz codeSize = code->getCodeSize();
if (!codeSize) [[unlikely]]
{
*dst = nullptr;
return asmjit::kErrorNoCodeGenerated;
}
void* p = m_pos.fetch_add(utils::align(codeSize, 4096));
if (!p || m_pos > m_max) [[unlikely]]
{
*dst = nullptr;
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jit_log.fatal("Out of memory (static asmjit)");
return asmjit::kErrorNoVirtualMemory;
}
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usz relocSize = code->relocate(p);
if (!relocSize) [[unlikely]]
{
*dst = nullptr;
return asmjit::kErrorInvalidState;
}
utils::memory_protect(p, utils::align(codeSize, 4096), utils::protection::rx);
flush(p, relocSize);
*dst = p;
return asmjit::kErrorOk;
}
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asmjit::Error _release(void*) noexcept override
{
return asmjit::kErrorOk;
}
private:
atomic_t<std::byte*> m_pos{};
std::byte* m_max{};
};
// Magic static
static custom_runtime g_rt;
return g_rt;
}
#ifdef LLVM_AVAILABLE
#include <unordered_map>
#include <unordered_set>
#include <deque>
#ifdef _MSC_VER
#pragma warning(push, 0)
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#else
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wall"
#pragma GCC diagnostic ignored "-Wextra"
#pragma GCC diagnostic ignored "-Wold-style-cast"
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#pragma GCC diagnostic ignored "-Wunused-parameter"
#pragma GCC diagnostic ignored "-Wstrict-aliasing"
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#pragma GCC diagnostic ignored "-Wredundant-decls"
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#pragma GCC diagnostic ignored "-Weffc++"
#pragma GCC diagnostic ignored "-Wmissing-noreturn"
#endif
#include "llvm/Support/TargetSelect.h"
#include "llvm/Support/FormattedStream.h"
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#include "llvm/Support/Host.h"
#include "llvm/ExecutionEngine/ExecutionEngine.h"
#include "llvm/ExecutionEngine/RTDyldMemoryManager.h"
#include "llvm/ExecutionEngine/ObjectCache.h"
#ifdef _MSC_VER
#pragma warning(pop)
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#else
#pragma GCC diagnostic pop
#endif
const bool jit_initialize = []() -> bool
{
llvm::InitializeNativeTarget();
llvm::InitializeNativeTargetAsmPrinter();
llvm::InitializeNativeTargetAsmParser();
LLVMLinkInMCJIT();
return true;
}();
[[noreturn]] static void null(const char* name)
{
fmt::throw_exception("Null function: %s", name);
}
namespace vm
{
extern u8* const g_sudo_addr;
}
static shared_mutex null_mtx;
static std::unordered_map<std::string, u64> null_funcs;
static u64 make_null_function(const std::string& name)
{
if (name.starts_with("__0x"))
{
u32 addr = -1;
auto res = std::from_chars(name.c_str() + 4, name.c_str() + name.size(), addr, 16);
if (res.ec == std::errc() && res.ptr == name.c_str() + name.size() && addr < 0x8000'0000)
{
// Point the garbage to reserved, non-executable memory
return reinterpret_cast<u64>(vm::g_sudo_addr + addr);
}
}
std::lock_guard lock(null_mtx);
if (u64& func_ptr = null_funcs[name]) [[likely]]
{
// Already exists
return func_ptr;
}
else
{
using namespace asmjit;
// Build a "null" function that contains its name
const auto func = build_function_asm<void (*)()>([&](X86Assembler& c, auto& args)
{
Label data = c.newLabel();
c.lea(args[0], x86::qword_ptr(data, 0));
c.jmp(imm_ptr(&null));
c.align(kAlignCode, 16);
c.bind(data);
// Copy function name bytes
for (char ch : name)
c.db(ch);
c.db(0);
c.align(kAlignData, 16);
});
func_ptr = reinterpret_cast<u64>(func);
return func_ptr;
}
}
// Simple memory manager
struct MemoryManager1 : llvm::RTDyldMemoryManager
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{
// 256 MiB for code or data
static constexpr u64 c_max_size = 0x20000000 / 2;
// Allocation unit (2M)
static constexpr u64 c_page_size = 2 * 1024 * 1024;
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// Reserve 512 MiB
u8* const ptr = static_cast<u8*>(utils::memory_reserve(c_max_size * 2));
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u64 code_ptr = 0;
u64 data_ptr = c_max_size;
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MemoryManager1() = default;
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MemoryManager1(const MemoryManager1&) = delete;
MemoryManager1& operator=(const MemoryManager1&) = delete;
~MemoryManager1() override
{
utils::memory_release(ptr, c_max_size * 2);
}
llvm::JITSymbol findSymbol(const std::string& name) override
{
u64 addr = RTDyldMemoryManager::getSymbolAddress(name);
if (!addr)
{
addr = make_null_function(name);
if (!addr)
{
fmt::throw_exception("Failed to link '%s'", name);
}
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}
return {addr, llvm::JITSymbolFlags::Exported};
}
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u8* allocate(u64& oldp, uptr size, uint align, utils::protection prot)
{
if (align > c_page_size)
{
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jit_log.fatal("Unsupported alignment (size=0x%x, align=0x%x)", size, align);
return nullptr;
}
const u64 olda = utils::align(oldp, align);
const u64 newp = utils::align(olda + size, align);
if ((newp - 1) / c_max_size != oldp / c_max_size)
{
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jit_log.fatal("Out of memory (size=0x%x, align=0x%x)", size, align);
return nullptr;
}
if ((oldp - 1) / c_page_size != (newp - 1) / c_page_size)
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{
// Allocate pages on demand
const u64 pagea = utils::align(oldp, c_page_size);
const u64 psize = utils::align(newp - pagea, c_page_size);
utils::memory_commit(this->ptr + pagea, psize, prot);
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}
// Update allocation counter
oldp = newp;
return this->ptr + olda;
}
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u8* allocateCodeSection(uptr size, uint align, uint /*sec_id*/, llvm::StringRef /*sec_name*/) override
{
return allocate(code_ptr, size, align, utils::protection::wx);
}
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u8* allocateDataSection(uptr size, uint align, uint /*sec_id*/, llvm::StringRef /*sec_name*/, bool /*is_ro*/) override
{
return allocate(data_ptr, size, align, utils::protection::rw);
}
bool finalizeMemory(std::string* = nullptr) override
{
return false;
}
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void registerEHFrames(u8*, u64, usz) override
{
}
void deregisterEHFrames() override
{
}
};
// Simple memory manager
struct MemoryManager2 : llvm::RTDyldMemoryManager
{
MemoryManager2() = default;
~MemoryManager2() override
{
}
llvm::JITSymbol findSymbol(const std::string& name) override
{
u64 addr = RTDyldMemoryManager::getSymbolAddress(name);
if (!addr)
{
addr = make_null_function(name);
if (!addr)
{
fmt::throw_exception("Failed to link '%s' (MM2)", name);
}
}
return {addr, llvm::JITSymbolFlags::Exported};
}
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u8* allocateCodeSection(uptr size, uint align, uint /*sec_id*/, llvm::StringRef /*sec_name*/) override
{
return jit_runtime::alloc(size, align, true);
}
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u8* allocateDataSection(uptr size, uint align, uint /*sec_id*/, llvm::StringRef /*sec_name*/, bool /*is_ro*/) override
{
return jit_runtime::alloc(size, align, false);
}
bool finalizeMemory(std::string* = nullptr) override
{
return false;
}
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void registerEHFrames(u8*, u64, usz) override
{
}
void deregisterEHFrames() override
{
}
};
// Helper class
class ObjectCache final : public llvm::ObjectCache
{
const std::string& m_path;
public:
ObjectCache(const std::string& path)
: m_path(path)
{
}
~ObjectCache() override = default;
void notifyObjectCompiled(const llvm::Module* _module, llvm::MemoryBufferRef obj) override
{
std::string name = m_path;
name.append(_module->getName().data());
//fs::file(name, fs::rewrite).write(obj.getBufferStart(), obj.getBufferSize());
name.append(".gz");
z_stream zs{};
uLong zsz = compressBound(::narrow<u32>(obj.getBufferSize())) + 256;
auto zbuf = std::make_unique<uchar[]>(zsz);
#ifndef _MSC_VER
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wold-style-cast"
#endif
deflateInit2(&zs, 9, Z_DEFLATED, 16 + 15, 9, Z_DEFAULT_STRATEGY);
#ifndef _MSC_VER
#pragma GCC diagnostic pop
#endif
zs.avail_in = static_cast<uInt>(obj.getBufferSize());
zs.next_in = reinterpret_cast<uchar*>(const_cast<char*>(obj.getBufferStart()));
zs.avail_out = static_cast<uInt>(zsz);
zs.next_out = zbuf.get();
switch (deflate(&zs, Z_FINISH))
{
case Z_OK:
case Z_STREAM_END:
{
deflateEnd(&zs);
break;
}
default:
{
jit_log.error("LLVM: Failed to compress module: %s", _module->getName().data());
deflateEnd(&zs);
return;
}
}
if (!fs::write_file(name, fs::rewrite, zbuf.get(), zsz - zs.avail_out))
{
jit_log.error("LLVM: Failed to create module file: %s (%s)", name, fs::g_tls_error);
return;
}
jit_log.notice("LLVM: Created module: %s", _module->getName().data());
}
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static std::unique_ptr<llvm::MemoryBuffer> load(const std::string& path)
{
if (fs::file cached{path + ".gz", fs::read})
{
std::vector<uchar> gz = cached.to_vector<uchar>();
std::vector<uchar> out;
z_stream zs{};
if (gz.empty()) [[unlikely]]
{
return nullptr;
}
#ifndef _MSC_VER
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wold-style-cast"
#endif
inflateInit2(&zs, 16 + 15);
#ifndef _MSC_VER
#pragma GCC diagnostic pop
#endif
zs.avail_in = static_cast<uInt>(gz.size());
zs.next_in = gz.data();
out.resize(gz.size() * 6);
zs.avail_out = static_cast<uInt>(out.size());
zs.next_out = out.data();
while (zs.avail_in)
{
switch (inflate(&zs, Z_FINISH))
{
case Z_OK: break;
case Z_STREAM_END: break;
case Z_BUF_ERROR:
{
if (zs.avail_in)
break;
[[fallthrough]];
}
default:
inflateEnd(&zs);
return nullptr;
}
if (zs.avail_in)
{
auto cur_size = zs.next_out - out.data();
out.resize(out.size() + 65536);
zs.avail_out = static_cast<uInt>(out.size() - cur_size);
zs.next_out = out.data() + cur_size;
}
}
out.resize(zs.next_out - out.data());
inflateEnd(&zs);
auto buf = llvm::WritableMemoryBuffer::getNewUninitMemBuffer(out.size());
std::memcpy(buf->getBufferStart(), out.data(), out.size());
return buf;
}
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if (fs::file cached{path, fs::read})
{
if (cached.size() == 0) [[unlikely]]
{
return nullptr;
}
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auto buf = llvm::WritableMemoryBuffer::getNewUninitMemBuffer(cached.size());
cached.read(buf->getBufferStart(), buf->getBufferSize());
return buf;
}
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return nullptr;
}
std::unique_ptr<llvm::MemoryBuffer> getObject(const llvm::Module* _module) override
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{
std::string path = m_path;
path.append(_module->getName().data());
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if (auto buf = load(path))
{
jit_log.notice("LLVM: Loaded module: %s", _module->getName().data());
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return buf;
}
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return nullptr;
}
};
std::string jit_compiler::cpu(const std::string& _cpu)
{
std::string m_cpu = _cpu;
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if (m_cpu.empty())
{
m_cpu = llvm::sys::getHostCPUName().operator std::string();
if (m_cpu == "sandybridge" ||
m_cpu == "ivybridge" ||
m_cpu == "haswell" ||
m_cpu == "broadwell" ||
m_cpu == "skylake" ||
m_cpu == "skylake-avx512" ||
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m_cpu == "cascadelake" ||
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m_cpu == "cooperlake" ||
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m_cpu == "cannonlake" ||
m_cpu == "icelake" ||
m_cpu == "icelake-client" ||
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m_cpu == "icelake-server" ||
m_cpu == "tigerlake")
{
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// Downgrade if AVX is not supported by some chips
if (!utils::has_avx())
{
m_cpu = "nehalem";
}
}
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if (m_cpu == "skylake-avx512" ||
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m_cpu == "cascadelake" ||
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m_cpu == "cooperlake" ||
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m_cpu == "cannonlake" ||
m_cpu == "icelake" ||
m_cpu == "icelake-client" ||
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m_cpu == "icelake-server" ||
m_cpu == "tigerlake")
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{
// Downgrade if AVX-512 is disabled or not supported
if (!utils::has_avx512())
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{
m_cpu = "skylake";
}
}
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if (m_cpu == "znver1" && utils::has_clwb())
{
// Upgrade
m_cpu = "znver2";
}
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}
return m_cpu;
}
jit_compiler::jit_compiler(const std::unordered_map<std::string, u64>& _link, const std::string& _cpu, u32 flags)
: m_cpu(cpu(_cpu))
{
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std::string result;
auto null_mod = std::make_unique<llvm::Module> ("null_", m_context);
if (_link.empty())
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{
std::unique_ptr<llvm::RTDyldMemoryManager> mem;
if (flags & 0x1)
{
mem = std::make_unique<MemoryManager1>();
}
else
{
mem = std::make_unique<MemoryManager2>();
null_mod->setTargetTriple(llvm::Triple::normalize("x86_64-unknown-linux-gnu"));
}
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// Auxiliary JIT (does not use custom memory manager, only writes the objects)
m_engine.reset(llvm::EngineBuilder(std::move(null_mod))
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.setErrorStr(&result)
.setEngineKind(llvm::EngineKind::JIT)
.setMCJITMemoryManager(std::move(mem))
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.setOptLevel(llvm::CodeGenOpt::Aggressive)
.setCodeModel(flags & 0x2 ? llvm::CodeModel::Large : llvm::CodeModel::Small)
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.setMCPU(m_cpu)
.create());
}
else
{
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// Primary JIT
m_engine.reset(llvm::EngineBuilder(std::move(null_mod))
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.setErrorStr(&result)
.setEngineKind(llvm::EngineKind::JIT)
.setMCJITMemoryManager(std::make_unique<MemoryManager1>())
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.setOptLevel(llvm::CodeGenOpt::Aggressive)
.setCodeModel(flags & 0x2 ? llvm::CodeModel::Large : llvm::CodeModel::Small)
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.setMCPU(m_cpu)
.create());
for (auto&& [name, addr] : _link)
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{
m_engine->updateGlobalMapping(name, addr);
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}
}
if (!m_engine)
{
fmt::throw_exception("LLVM: Failed to create ExecutionEngine: %s", result);
}
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}
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jit_compiler::~jit_compiler()
{
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}
void jit_compiler::add(std::unique_ptr<llvm::Module> _module, const std::string& path)
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{
ObjectCache cache{path};
m_engine->setObjectCache(&cache);
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const auto ptr = _module.get();
m_engine->addModule(std::move(_module));
m_engine->generateCodeForModule(ptr);
m_engine->setObjectCache(nullptr);
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for (auto& func : ptr->functions())
{
// Delete IR to lower memory consumption
func.deleteBody();
}
}
void jit_compiler::add(std::unique_ptr<llvm::Module> _module)
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{
const auto ptr = _module.get();
m_engine->addModule(std::move(_module));
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m_engine->generateCodeForModule(ptr);
for (auto& func : ptr->functions())
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{
// Delete IR to lower memory consumption
func.deleteBody();
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}
}
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void jit_compiler::add(const std::string& path)
{
auto cache = ObjectCache::load(path);
if (auto object_file = llvm::object::ObjectFile::createObjectFile(*cache))
{
m_engine->addObjectFile( std::move(*object_file) );
}
else
{
jit_log.error("ObjectCache: Adding failed: %s", path);
}
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}
bool jit_compiler::check(const std::string& path)
{
if (auto cache = ObjectCache::load(path))
{
if (auto object_file = llvm::object::ObjectFile::createObjectFile(*cache))
{
return true;
}
if (fs::remove_file(path))
{
jit_log.error("ObjectCache: Removed damaged file: %s", path);
}
}
return false;
}
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void jit_compiler::fin()
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{
m_engine->finalizeObject();
}
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u64 jit_compiler::get(const std::string& name)
{
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return m_engine->getGlobalValueAddress(name);
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}
#endif