#pragma once #include "util/types.hpp" // Include asmjit with warnings ignored #define ASMJIT_EMBED #define ASMJIT_STATIC #define ASMJIT_BUILD_DEBUG #undef Bool #ifdef _MSC_VER #pragma warning(push, 0) #include #pragma warning(pop) #else #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wall" #pragma GCC diagnostic ignored "-Wextra" #pragma GCC diagnostic ignored "-Wold-style-cast" #pragma GCC diagnostic ignored "-Wunused-parameter" #pragma GCC diagnostic ignored "-Wstrict-aliasing" #pragma GCC diagnostic ignored "-Wredundant-decls" #pragma GCC diagnostic ignored "-Wnon-virtual-dtor" #pragma GCC diagnostic ignored "-Weffc++" #ifdef __clang__ #pragma GCC diagnostic ignored "-Wdeprecated-anon-enum-enum-conversion" #pragma GCC diagnostic ignored "-Wcast-qual" #else #pragma GCC diagnostic ignored "-Wduplicated-branches" #pragma GCC diagnostic ignored "-Wdeprecated-enum-enum-conversion" #endif #include #if defined(ARCH_ARM64) #include #endif #pragma GCC diagnostic pop #endif #include #include #include #include #include #include #if defined(ARCH_X64) using native_asm = asmjit::x86::Assembler; using native_args = std::array; #elif defined(ARCH_ARM64) using native_asm = asmjit::a64::Assembler; using native_args = std::array; #endif void jit_announce(uptr func, usz size, std::string_view name); void jit_announce(auto* func, usz size, std::string_view name) { jit_announce(uptr(func), size, name); } enum class jit_class { ppu_code, ppu_data, spu_code, spu_data, }; struct jit_runtime_base { jit_runtime_base() noexcept = default; virtual ~jit_runtime_base() = default; jit_runtime_base(const jit_runtime_base&) = delete; jit_runtime_base& operator=(const jit_runtime_base&) = delete; const asmjit::Environment& environment() const noexcept; void* _add(asmjit::CodeHolder* code) noexcept; virtual uchar* _alloc(usz size, usz align) noexcept = 0; std::string_view dump_name; }; // ASMJIT runtime for emitting code in a single 2G region struct jit_runtime final : jit_runtime_base { jit_runtime(); ~jit_runtime() override; // Allocate executable memory uchar* _alloc(usz size, usz align) noexcept override; // Allocate memory static u8* alloc(usz size, uint align, bool exec = true) noexcept; // Should be called at least once after global initialization static void initialize(); // Deallocate all memory static void finalize() noexcept; }; namespace asmjit { // Should only be used to build global functions jit_runtime_base& get_global_runtime(); // Don't use directly class inline_runtime : public jit_runtime_base { uchar* m_data; usz m_size; public: inline_runtime(uchar* data, usz size); ~inline_runtime(); uchar* _alloc(usz size, usz align) noexcept override; }; // Emit xbegin and adjacent loop, return label at xbegin (don't use xabort please) template [[nodiscard]] inline asmjit::Label build_transaction_enter(asmjit::x86::Assembler& c, asmjit::Label fallback, F func) { Label fall = c.newLabel(); Label begin = c.newLabel(); c.jmp(begin); c.bind(fall); // Don't repeat on zero status (may indicate syscall or interrupt) c.test(x86::eax, x86::eax); c.jz(fallback); // First invoked after failure (can fallback to proceed, or jump anywhere else) func(); // Other bad statuses are ignored regardless of repeat flag (TODO) c.align(AlignMode::kCode, 16); c.bind(begin); return fall; // xbegin should be issued manually, allows to add more check before entering transaction } // Helper to spill RDX (EDX) register for RDTSC inline void build_swap_rdx_with(asmjit::x86::Assembler& c, std::array& args, const asmjit::x86::Gp& with) { #ifdef _WIN32 c.xchg(args[1], with); args[1] = with; #else c.xchg(args[2], with); args[2] = with; #endif } // Get full RDTSC value into chosen register (clobbers rax/rdx or saves only rax with other target) inline void build_get_tsc(asmjit::x86::Assembler& c, const asmjit::x86::Gp& to = asmjit::x86::rax) { if (&to != &x86::rax && &to != &x86::rdx) { // Swap to save its contents c.xchg(x86::rax, to); } c.rdtsc(); c.shl(x86::rdx, 32); if (&to == &x86::rax) { c.or_(x86::rax, x86::rdx); } else if (&to == &x86::rdx) { c.or_(x86::rdx, x86::rax); } else { // Swap back, maybe there is more effective way to do it c.xchg(x86::rax, to); c.mov(to.r32(), to.r32()); c.or_(to.r64(), x86::rdx); } } inline void build_init_args_from_ghc(native_asm& c, native_args& args) { #if defined(ARCH_X64) // TODO: handle case when args don't overlap with r13/rbp/r12/rbx c.mov(args[0], x86::r13); c.mov(args[1], x86::rbp); c.mov(args[2], x86::r12); c.mov(args[3], x86::rbx); #else static_cast(c); static_cast(args); #endif } inline void build_init_ghc_args(native_asm& c, native_args& args) { #if defined(ARCH_X64) // TODO: handle case when args don't overlap with r13/rbp/r12/rbx c.mov(x86::r13, args[0]); c.mov(x86::rbp, args[1]); c.mov(x86::r12, args[2]); c.mov(x86::rbx, args[3]); #else static_cast(c); static_cast(args); #endif } } // Build runtime function with asmjit::X86Assembler template inline FT build_function_asm(std::string_view name, F&& builder) { using namespace asmjit; auto& rt = get_global_runtime(); CodeHolder code; code.init(rt.environment()); #if defined(ARCH_X64) native_args args; #ifdef _WIN32 args[0] = x86::rcx; args[1] = x86::rdx; args[2] = x86::r8; args[3] = x86::r9; #else args[0] = x86::rdi; args[1] = x86::rsi; args[2] = x86::rdx; args[3] = x86::rcx; #endif #elif defined(ARCH_ARM64) native_args args; args[0] = a64::x0; args[1] = a64::x1; args[2] = a64::x2; args[3] = a64::x3; #endif Asm compiler(&code); compiler.addEncodingOptions(EncodingOptions::kOptimizedAlign); if constexpr (std::is_invocable_v) builder(compiler, args); else builder(compiler); rt.dump_name = name; const auto result = rt._add(&code); jit_announce(result, code.codeSize(), name); return reinterpret_cast(uptr(result)); } #if !defined(ARCH_X64) || defined(__APPLE__) template class built_function { FT m_func; public: built_function(const built_function&) = delete; built_function& operator=(const built_function&) = delete; template built_function(std::string_view name, F&& builder, u32 line = __builtin_LINE(), u32 col = __builtin_COLUMN(), const char* file = __builtin_FILE(), const char* func = __builtin_FUNCTION()) : m_func(ensure(build_function_asm(name, std::forward(builder)), const_str(), line, col, file, func)) { } operator FT() const noexcept { return m_func; } template auto operator()(Args&&... args) const noexcept { return m_func(std::forward(args)...); } }; #else template class built_function { alignas(4096) uchar m_data[Size]; public: built_function(const built_function&) = delete; built_function& operator=(const built_function&) = delete; template built_function(std::string_view name, F&& builder) { using namespace asmjit; inline_runtime rt(m_data, Size); CodeHolder code; code.init(rt.environment()); #if defined(ARCH_X64) native_args args; #ifdef _WIN32 args[0] = x86::rcx; args[1] = x86::rdx; args[2] = x86::r8; args[3] = x86::r9; #else args[0] = x86::rdi; args[1] = x86::rsi; args[2] = x86::rdx; args[3] = x86::rcx; #endif #elif defined(ARCH_ARM64) native_args args; args[0] = a64::x0; args[1] = a64::x1; args[2] = a64::x2; args[3] = a64::x3; #endif native_asm compiler(&code); compiler.addEncodingOptions(EncodingOptions::kOptimizedAlign); builder(compiler, args); rt.dump_name = name; jit_announce(rt._add(&code), code.codeSize(), name); } operator FT() const noexcept { return FT(+m_data); } template auto operator()(Args&&... args) const noexcept { return FT(+m_data)(std::forward(args)...); } }; #endif #ifdef LLVM_AVAILABLE namespace llvm { class LLVMContext; class ExecutionEngine; class Module; } // Temporary compiler interface class jit_compiler final { // Local LLVM context std::unique_ptr m_context{}; // Execution instance std::unique_ptr m_engine{}; // Arch std::string m_cpu{}; public: jit_compiler(const std::unordered_map& _link, const std::string& _cpu, u32 flags = 0); ~jit_compiler(); // Get LLVM context auto& get_context() { return *m_context; } auto& get_engine() const { return *m_engine; } // Add module (path to obj cache dir) void add(std::unique_ptr _module, const std::string& path); // Add module (not cached) void add(std::unique_ptr _module); // Add object (path to obj file) void add(const std::string& path); // Check object file static bool check(const std::string& path); // Finalize void fin(); // Get compiled function address u64 get(const std::string& name); // Get CPU info static std::string cpu(const std::string& _cpu); }; #endif