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# Available variables and macros in JIT-ed function: # ec: the first argument of _mjitXXX # reg_cfp: the second argument of _mjitXXX # GET_CFP(): refers to `reg_cfp` # GET_EP(): refers to `reg_cfp->ep` # GET_SP(): refers to `reg_cfp->sp`, or `(stack + stack_size)` if local_stack_p # GET_SELF(): refers to `cfp_self` # GET_LEP(): refers to `VM_EP_LEP(reg_cfp->ep)` # EXEC_EC_CFP(): refers to `val = vm_exec(ec, true)` with frame setup # CALL_METHOD(): using `GET_CFP()` and `EXEC_EC_CFP()` # TOPN(): refers to `reg_cfp->sp`, or `*(stack + (stack_size - num - 1))` if local_stack_p # STACK_ADDR_FROM_TOP(): refers to `reg_cfp->sp`, or `stack + (stack_size - num)` if local_stack_p # DISPATCH_ORIGINAL_INSN(): expanded in _mjit_compile_insn.erb # THROW_EXCEPTION(): specially defined for JIT # RESTORE_REGS(): specially defined for `leave` class RubyVM::MJIT::Compiler # :nodoc: all C = RubyVM::MJIT.const_get(:C, false) INSNS = RubyVM::MJIT.const_get(:INSNS, false) UNSUPPORTED_INSNS = [ :defineclass, # low priority ] def initialize = freeze # @param iseq [RubyVM::MJIT::CPointer::Struct] # @param funcname [String] # @param id [Integer] # @return [String,NilClass] def compile(iseq, funcname, id) status = C.compile_status.new # not freed for now status.compiled_iseq = iseq.body status.compiled_id = id init_compile_status(status, iseq.body, true) # not freed for now if iseq.body.ci_size > 0 && status.cc_entries_index == -1 return nil end src = +'' if !status.compile_info.disable_send_cache && !status.compile_info.disable_inlining unless precompile_inlinable_iseqs(src, iseq, status) return nil end end src << "VALUE\n#{funcname}(rb_execution_context_t *ec, rb_control_frame_t *reg_cfp)\n{\n" success = compile_body(src, iseq, status) src << "\n} // end of #{funcname}\n" return success ? src : nil rescue Exception => e # should we use rb_rescue in C instead? if C.mjit_opts.warnings || C.mjit_opts.verbose > 0 $stderr.puts "MJIT error: #{e.full_message}" end return nil end private def compile_body(src, iseq, status) status.success = true status.local_stack_p = !iseq.body.catch_except_p if status.local_stack_p src << " VALUE stack[#{iseq.body.stack_max}];\n" else src << " VALUE *stack = reg_cfp->sp;\n" end unless status.inlined_iseqs.nil? # i.e. compile root src << " static const rb_iseq_t *original_iseq = (const rb_iseq_t *)#{iseq};\n" end src << " static const VALUE *const original_body_iseq = (VALUE *)#{iseq.body.iseq_encoded};\n" src << " VALUE cfp_self = reg_cfp->self;\n" # cache self across the method src << "#undef GET_SELF\n" src << "#define GET_SELF() cfp_self\n" # Generate merged ivar guards first if needed if !status.compile_info.disable_ivar_cache && using_ivar?(iseq.body) src << " if (UNLIKELY(!RB_TYPE_P(GET_SELF(), T_OBJECT))) {" src << " goto ivar_cancel;\n" src << " }\n" end # Simulate `opt_pc` in setup_parameters_complex. Other PCs which may be passed by catch tables # are not considered since vm_exec doesn't call jit_exec for catch tables. if iseq.body.param.flags.has_opt src << "\n" src << " switch (reg_cfp->pc - ISEQ_BODY(reg_cfp->iseq)->iseq_encoded) {\n" (0..iseq.body.param.opt_num).each do |i| pc_offset = iseq.body.param.opt_table[i] src << " case #{pc_offset}:\n" src << " goto label_#{pc_offset};\n" end src << " }\n" end compile_insns(0, 0, status, iseq.body, src) compile_cancel_handler(src, iseq.body, status) src << "#undef GET_SELF\n" return status.success end # Compile one conditional branch. If it has branchXXX insn, this should be # called multiple times for each branch. def compile_insns(stack_size, pos, status, body, src) branch = C.compile_branch.new # not freed for now branch.stack_size = stack_size branch.finish_p = false while pos < body.iseq_size && !already_compiled?(status, pos) && !branch.finish_p insn = INSNS.fetch(C.rb_vm_insn_decode(body.iseq_encoded[pos])) status.stack_size_for_pos[pos] = branch.stack_size src << "\nlabel_#{pos}: /* #{insn.name} */\n" pos = compile_insn(insn, pos, status, body.iseq_encoded + (pos+1), body, branch, src) if status.success && branch.stack_size > body.stack_max if mjit_opts.warnings || mjit_opts.verbose > 0 $stderr.puts "MJIT warning: JIT stack size (#{branch.stack_size}) exceeded its max size (#{body.stack_max})" end status.success = false end break unless status.success end end # Main function of JIT compilation, vm_exec_core counterpart for JIT. Compile one insn to `f`, may modify # b->stack_size and return next position. # # When you add a new instruction to insns.def, it would be nice to have JIT compilation support here but # it's optional. This JIT compiler just ignores ISeq which includes unknown instruction, and ISeq which # does not have it can be compiled as usual. def compile_insn(insn, pos, status, operands, body, b, src) sp_inc = C.mjit_call_attribute_sp_inc(insn.bin, operands) next_pos = pos + insn.len result = compile_insn_entry(insn, b.stack_size, sp_inc, status.local_stack_p, pos, next_pos, insn.len, status.inlined_iseqs.nil?, status, operands, body) if result.nil? if C.mjit_opts.warnings || C.mjit_opts.verbose > 0 $stderr.puts "MJIT warning: Skipped to compile unsupported instruction: #{insn.name}" end status.success = false else result_src, next_pos, finish_p, compile_insns_p = result src << result_src b.stack_size += sp_inc if finish_p b.finish_p = true end if compile_insns_p if already_compiled?(status, pos + insn.len) src << "goto label_#{pos + insn.len};\n" else compile_insns(b.stack_size, pos + insn.len, status, body, src) end end end # If next_pos is already compiled and this branch is not finished yet, # next instruction won't be compiled in C code next and will need `goto`. if !b.finish_p && next_pos < body.iseq_size && already_compiled?(status, next_pos) src << "goto label_#{next_pos};\n" # Verify stack size assumption is the same among multiple branches if status.stack_size_for_pos[next_pos] != b.stack_size if mjit_opts.warnings || mjit_opts.verbose > 0 $stderr.puts "MJIT warning: JIT stack assumption is not the same between branches (#{status.stack_size_for_pos[next_pos]} != #{b.stack_size})\n" end status.success = false end end return next_pos end def compile_insn_entry(insn, stack_size, sp_inc, local_stack_p, pos, next_pos, insn_len, inlined_iseq_p, status, operands, body) finish_p = false compile_insns = false # TODO: define this outside this method, or at least cache it opt_send_without_block = INSNS.values.find { |i| i.name == :opt_send_without_block } if opt_send_without_block.nil? raise 'opt_send_without_block not found' end send_compatible_opt_insns = INSNS.values.select do |insn| insn.name.start_with?('opt_') && opt_send_without_block.opes == insn.opes && insn.expr.lines.any? { |l| l.match(/\A\s+CALL_SIMPLE_METHOD\(\);\s+\z/) } end.map(&:name) case insn.name when *UNSUPPORTED_INSNS return nil when :opt_send_without_block, :send if src = compile_send(insn, stack_size, sp_inc, local_stack_p, pos, next_pos, status, operands, body) return src, next_pos, finish_p, compile_insns end when *send_compatible_opt_insns if C.has_cache_for_send(captured_cc_entries(status)[call_data_index(C.CALL_DATA.new(operands[0]), body)], insn.bin) && src = compile_send(opt_send_without_block, stack_size, sp_inc, local_stack_p, pos, next_pos, status, operands, body) return src, next_pos, finish_p, compile_insns end when :getinstancevariable, :setinstancevariable if src = compile_ivar(insn.name, stack_size, pos, status, operands, body) return src, next_pos, finish_p, compile_insns end when :opt_getconstant_path if src = compile_getconstant_path(stack_size, pos, insn_len, operands, status) return src, next_pos, finish_p, compile_insns end when :invokebuiltin, :opt_invokebuiltin_delegate, :opt_invokebuiltin_delegate_leave if src = compile_invokebuiltin(insn, stack_size, sp_inc, body, operands) if insn.name == :opt_invokebuiltin_delegate_leave src << compile_leave(stack_size, pos, inlined_iseq_p) finish_p = true end return src, next_pos, finish_p, compile_insns end when :leave if stack_size != 1 raise "Unexpected JIT stack_size on leave: #{stack_size}" end src = compile_leave(stack_size, pos, inlined_iseq_p) finish_p = true return src, next_pos, finish_p, compile_insns end return compile_insn_default(insn, stack_size, sp_inc, local_stack_p, pos, next_pos, insn_len, inlined_iseq_p, operands) end # Optimized case of send / opt_send_without_block instructions. def compile_send(insn, stack_size, sp_inc, local_stack_p, pos, next_pos, status, operands, body) # compiler: Use captured cc to avoid race condition cd = C.CALL_DATA.new(operands[0]) cd_index = call_data_index(cd, body) captured_cc = captured_cc_entries(status)[cd_index] # compiler: Inline send insn where some supported fastpath is used. ci = cd.ci kw_splat = (C.vm_ci_flag(ci) & C.VM_CALL_KW_SPLAT) > 0 if !status.compile_info.disable_send_cache && has_valid_method_type?(captured_cc) && ( # `CC_SET_FASTPATH(cd->cc, vm_call_cfunc_with_frame, ...)` in `vm_call_cfunc` (vm_cc_cme(captured_cc).def.type == C.VM_METHOD_TYPE_CFUNC && !C.rb_splat_or_kwargs_p(ci) && !kw_splat) || # `CC_SET_FASTPATH(cc, vm_call_iseq_setup_func(...), vm_call_iseq_optimizable_p(...))` in `vm_callee_setup_arg`, # and support only non-VM_CALL_TAILCALL path inside it (vm_cc_cme(captured_cc).def.type == C.VM_METHOD_TYPE_ISEQ && C.fastpath_applied_iseq_p(ci, captured_cc, iseq = def_iseq_ptr(vm_cc_cme(captured_cc).def)) && (C.vm_ci_flag(ci) & C.VM_CALL_TAILCALL) == 0) ) src = +"{\n" # JIT: Invalidate call cache if it requires vm_search_method. This allows to inline some of following things. src << " const struct rb_callcache *cc = (struct rb_callcache *)#{captured_cc};\n" src << " const rb_callable_method_entry_t *cc_cme = (rb_callable_method_entry_t *)#{vm_cc_cme(captured_cc)};\n" src << " const VALUE recv = stack[#{stack_size + sp_inc - 1}];\n" # If opt_class_of is true, use RBASIC_CLASS instead of CLASS_OF to reduce code size opt_class_of = !maybe_special_const?(captured_cc.klass) src << " if (UNLIKELY(#{opt_class_of ? 'RB_SPECIAL_CONST_P(recv)' : 'false'} || !vm_cc_valid_p(cc, cc_cme, #{opt_class_of ? 'RBASIC_CLASS' : 'CLASS_OF'}(recv)))) {\n" src << " reg_cfp->pc = original_body_iseq + #{pos};\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" src << " goto send_cancel;\n" src << " }\n" # JIT: move sp and pc if necessary pc_moved_p = compile_pc_and_sp(src, insn, stack_size, sp_inc, local_stack_p, next_pos) # JIT: If ISeq is inlinable, call the inlined method without pushing a frame. if iseq && status.inlined_iseqs && iseq.body.to_i == status.inlined_iseqs[pos]&.to_i src << " {\n" src << " VALUE orig_self = reg_cfp->self;\n" src << " reg_cfp->self = stack[#{stack_size + sp_inc - 1}];\n" src << " stack[#{stack_size + sp_inc - 1}] = _mjit#{status.compiled_id}_inlined_#{pos}(ec, reg_cfp, orig_self, original_iseq);\n" src << " reg_cfp->self = orig_self;\n" src << " }\n" else # JIT: Forked `vm_sendish` (except method_explorer = vm_search_method_wrap) to inline various things src << " {\n" src << " VALUE val;\n" src << " struct rb_calling_info calling;\n" if insn.name == :send src << " calling.block_handler = vm_caller_setup_arg_block(ec, reg_cfp, (const struct rb_callinfo *)#{ci}, (rb_iseq_t *)0x#{operands[1].to_s(16)}, FALSE);\n" else src << " calling.block_handler = VM_BLOCK_HANDLER_NONE;\n" end src << " calling.kw_splat = #{kw_splat ? 1 : 0};\n" src << " calling.recv = stack[#{stack_size + sp_inc - 1}];\n" src << " calling.argc = #{C.vm_ci_argc(ci)};\n" if vm_cc_cme(captured_cc).def.type == C.VM_METHOD_TYPE_CFUNC # TODO: optimize this more src << " calling.ci = (const struct rb_callinfo *)#{ci};\n" # creating local cd here because operand's cd->cc may not be the same as inlined cc. src << " calling.cc = cc;" src << " val = vm_call_cfunc_with_frame(ec, reg_cfp, &calling);\n" else # :iseq # fastpath_applied_iseq_p checks rb_simple_iseq_p, which ensures has_opt == FALSE src << " vm_call_iseq_setup_normal(ec, reg_cfp, &calling, cc_cme, 0, #{iseq.body.param.size}, #{iseq.body.local_table_size});\n" if iseq.body.catch_except_p src << " VM_ENV_FLAGS_SET(ec->cfp->ep, VM_FRAME_FLAG_FINISH);\n" src << " val = vm_exec(ec, true);\n" else src << " if ((val = jit_exec(ec)) == Qundef) {\n" src << " VM_ENV_FLAGS_SET(ec->cfp->ep, VM_FRAME_FLAG_FINISH);\n" # This is vm_call0_body's code after vm_call_iseq_setup src << " val = vm_exec(ec, false);\n" src << " }\n" end end src << " stack[#{stack_size + sp_inc - 1}] = val;\n" src << " }\n" # JIT: We should evaluate ISeq modified for TracePoint if it's enabled. Note: This is slow. src << " if (UNLIKELY(!mjit_call_p)) {\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size + sp_inc};\n" if !pc_moved_p src << " reg_cfp->pc = original_body_iseq + #{next_pos};\n" end src << " goto cancel;\n" src << " }\n" end src << "}\n" return src else return nil end end def compile_ivar(insn_name, stack_size, pos, status, operands, body) iv_cache = C.iseq_inline_storage_entry.new(operands[1]).iv_cache dest_shape_id = iv_cache.value >> C.SHAPE_FLAG_SHIFT source_shape_id = parent_shape_id(dest_shape_id) attr_index = iv_cache.value & ((1 << C.SHAPE_FLAG_SHIFT) - 1) src = +'' if !status.compile_info.disable_ivar_cache && source_shape_id != C.INVALID_SHAPE_ID # JIT: optimize away motion of sp and pc. This path does not call rb_warning() and so it's always leaf and not `handles_sp`. # compile_pc_and_sp(src, insn, stack_size, sp_inc, local_stack_p, next_pos) # JIT: prepare vm_getivar/vm_setivar arguments and variables src << "{\n" src << " VALUE obj = GET_SELF();\n" # T_OBJECT guaranteed by compile_body # JIT: cache hit path of vm_getivar/vm_setivar, or cancel JIT (recompile it with exivar) if insn_name == :setinstancevariable src << " const uint32_t index = #{attr_index - 1};\n" src << " const shape_id_t dest_shape_id = (shape_id_t)#{dest_shape_id};\n" src << " if (dest_shape_id == ROBJECT_SHAPE_ID(obj)) {\n" src << " VALUE *ptr = ROBJECT_IVPTR(obj);\n" src << " RB_OBJ_WRITE(obj, &ptr[index], stack[#{stack_size - 1}]);\n" src << " }\n" else src << " const shape_id_t source_shape_id = (shape_id_t)#{dest_shape_id};\n" if attr_index == 0 # cache hit, but uninitialized iv src << " /* Uninitialized instance variable */\n" src << " if (source_shape_id == ROBJECT_SHAPE_ID(obj)) {\n" src << " stack[#{stack_size}] = Qnil;\n" src << " }\n" else src << " const uint32_t index = #{attr_index - 1};\n" src << " if (source_shape_id == ROBJECT_SHAPE_ID(obj)) {\n" src << " stack[#{stack_size}] = ROBJECT_IVPTR(obj)[index];\n" src << " }\n" end end src << " else {\n" src << " reg_cfp->pc = original_body_iseq + #{pos};\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" src << " goto ivar_cancel;\n" src << " }\n" src << "}\n" return src elsif insn_name == :getinstancevariable && !status.compile_info.disable_exivar_cache && source_shape_id != C.INVALID_SHAPE_ID # JIT: optimize away motion of sp and pc. This path does not call rb_warning() and so it's always leaf and not `handles_sp`. # compile_pc_and_sp(src, insn, stack_size, sp_inc, local_stack_p, next_pos) # JIT: prepare vm_getivar's arguments and variables src << "{\n" src << " VALUE obj = GET_SELF();\n" src << " const shape_id_t source_shape_id = (shape_id_t)#{dest_shape_id};\n" src << " const uint32_t index = #{attr_index - 1};\n" # JIT: cache hit path of vm_getivar, or cancel JIT (recompile it without any ivar optimization) src << " struct gen_ivtbl *ivtbl;\n" src << " if (LIKELY(FL_TEST_RAW(GET_SELF(), FL_EXIVAR) && source_shape_id == rb_shape_get_shape_id(obj) && rb_ivar_generic_ivtbl_lookup(obj, &ivtbl))) {\n" src << " stack[#{stack_size}] = ivtbl->ivptr[index];\n" src << " }\n" src << " else {\n" src << " reg_cfp->pc = original_body_iseq + #{pos};\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" src << " goto exivar_cancel;\n" src << " }\n" src << "}\n" return src else return nil end end def compile_invokebuiltin(insn, stack_size, sp_inc, body, operands) bf = C.RB_BUILTIN.new(operands[0]) if bf.compiler > 0 index = (insn.name == :invokebuiltin ? -1 : operands[1]) src = +"{\n" src << " VALUE val;\n" C.builtin_compiler(src, bf, index, stack_size, body.builtin_inline_p) src << " stack[#{stack_size + sp_inc - 1}] = val;\n" src << "}\n" return src else return nil end end def compile_leave(stack_size, pos, inlined_iseq_p) src = +'' # Skip vm_pop_frame for inlined call unless inlined_iseq_p # Cancel on interrupts to make leave insn leaf src << " if (UNLIKELY(RUBY_VM_INTERRUPTED_ANY(ec))) {\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" src << " reg_cfp->pc = original_body_iseq + #{pos};\n" src << " rb_threadptr_execute_interrupts(rb_ec_thread_ptr(ec), 0);\n" src << " }\n" src << " ec->cfp = RUBY_VM_PREVIOUS_CONTROL_FRAME(reg_cfp);\n" # vm_pop_frame end src << " return stack[0];\n" end def compile_getconstant_path(stack_size, pos, insn_len, operands, status) ice = C.IC.new(operands[0]).entry if !status.compile_info.disable_const_cache && ice # JIT: Inline everything in IC, and cancel the slow path src = +" if (vm_inlined_ic_hit_p(#{ice.flags}, #{ice.value}, (const rb_cref_t *)#{to_addr(ice.ic_cref)}, reg_cfp->ep)) {\n" src << " stack[#{stack_size}] = #{ice.value};\n" src << " }\n" src << " else {\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" src << " reg_cfp->pc = original_body_iseq + #{pos};\n" src << " goto const_cancel;\n" src << " }\n" return src else return nil end end def compile_insn_default(insn, stack_size, sp_inc, local_stack_p, pos, next_pos, insn_len, inlined_iseq_p, operands) src = +'' finish_p = false compile_insns = false # JIT: Declare stack_size to be used in some macro of _mjit_compile_insn_body.erb src << "{\n" if local_stack_p src << " MAYBE_UNUSED(unsigned int) stack_size = #{stack_size};\n" end # JIT: Declare variables for operands, popped values and return values insn.declarations.each do |decl| src << " #{decl};\n" end # JIT: Set const expressions for `RubyVM::OperandsUnifications` insn insn.preamble.each do |amble| src << "#{amble.sub(/const \S+\s+/, '')}\n" end # JIT: Initialize operands insn.opes.each_with_index do |ope, i| src << " #{ope.fetch(:name)} = (#{ope.fetch(:type)})#{operands[i]};\n" # TODO: resurrect comment_id end # JIT: Initialize popped values insn.pops.reverse_each.with_index.reverse_each do |pop, i| src << " #{pop.fetch(:name)} = stack[#{stack_size - (i + 1)}];\n" end # JIT: move sp and pc if necessary pc_moved_p = compile_pc_and_sp(src, insn, stack_size, sp_inc, local_stack_p, next_pos) # JIT: Print insn body in insns.def next_pos = compile_insn_body(src, insn, pos, next_pos, insn_len, local_stack_p, stack_size, sp_inc, operands) # JIT: Set return values insn.rets.reverse_each.with_index do |ret, i| # TOPN(n) = ... src << " stack[#{stack_size + sp_inc - (i + 1)}] = #{ret.fetch(:name)};\n" end # JIT: We should evaluate ISeq modified for TracePoint if it's enabled. Note: This is slow. # leaf insn may not cancel JIT. leaf_without_check_ints is covered in RUBY_VM_CHECK_INTS of _mjit_compile_insn_body.erb. unless insn.always_leaf? || insn.leaf_without_check_ints? src << " if (UNLIKELY(!mjit_call_p)) {\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size + sp_inc};\n" if !pc_moved_p src << " reg_cfp->pc = original_body_iseq + #{next_pos};\n" end src << " goto cancel;\n" src << " }\n" end src << "}\n" # compiler: If insn has conditional JUMP, the code should go to the branch not targeted by JUMP next. if insn.expr.match?(/if\s+\([^{}]+\)\s+\{[^{}]+JUMP\([^)]+\);[^{}]+\}/) compile_insns = true end # compiler: If insn returns (leave) or does longjmp (throw), the branch should no longer be compiled. TODO: create attr for it? if insn.expr.match?(/\sTHROW_EXCEPTION\([^)]+\);/) || insn.expr.match?(/\bvm_pop_frame\(/) finish_p = true end return src, next_pos, finish_p, compile_insns end def compile_insn_body(src, insn, pos, next_pos, insn_len, local_stack_p, stack_size, sp_inc, operands) # Print a body of insn, but with macro expansion. expand_simple_macros(insn.expr).each_line do |line| # Expand dynamic macro here # TODO: support combination of following macros in the same line case line when /\A\s+RUBY_VM_CHECK_INTS\(ec\);\s+\z/ if insn.leaf_without_check_ints? # lazily move PC and optionalize mjit_call_p here src << " if (UNLIKELY(RUBY_VM_INTERRUPTED_ANY(ec))) {\n" src << " reg_cfp->pc = original_body_iseq + #{next_pos};\n" # ADD_PC(INSN_ATTR(width)); src << " rb_threadptr_execute_interrupts(rb_ec_thread_ptr(ec), 0);\n" src << " if (UNLIKELY(!mjit_call_p)) {\n" src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" src << " goto cancel;\n" src << " }\n" src << " }\n" else src << to_cstr(line) end when /\A\s+JUMP\((?<dest>[^)]+)\);\s+\z/ dest = Regexp.last_match[:dest] if insn.name == :opt_case_dispatch # special case... TODO: use another macro to avoid checking name hash_offsets = C.rb_hash_values(operands[0]).uniq else_offset = cast_offset(operands[1]) base_pos = pos + insn_len src << " switch (#{dest}) {\n" hash_offsets.each do |offset| src << " case #{offset}:\n" src << " goto label_#{base_pos + offset};\n" end src << " case #{else_offset}:\n" src << " goto label_#{base_pos + else_offset};\n" src << " }\n" else # Before we `goto` next insn, we need to set return values, especially for getinlinecache insn.rets.reverse_each.with_index do |ret, i| # TOPN(n) = ... src << " stack[#{stack_size + sp_inc - (i + 1)}] = #{ret.fetch(:name)};\n" end next_pos = pos + insn_len + cast_offset(operands[0]) # workaround: assuming dest == operands[0]. TODO: avoid relying on it src << " goto label_#{next_pos};\n" end when /\A\s+CALL_SIMPLE_METHOD\(\);\s+\z/ # For `opt_xxx`'s fallbacks. if local_stack_p src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" end src << " reg_cfp->pc = original_body_iseq + #{pos};\n" src << " goto cancel;\n" when /\A(?<prefix>.+\b)INSN_LABEL\((?<name>[^)]+)\)(?<suffix>.+)\z/m prefix, name, suffix = Regexp.last_match[:prefix], Regexp.last_match[:name], Regexp.last_match[:suffix] src << "#{prefix}INSN_LABEL(#{name}_#{pos})#{suffix}" else if insn.handles_sp? # If insn.handles_sp? is true, cfp->sp might be changed inside insns (like vm_caller_setup_arg_block) # and thus we need to use cfp->sp, even when local_stack_p is TRUE. When insn.handles_sp? is true, # cfp->sp should be available too because _mjit_compile_pc_and_sp.erb sets it. src << to_cstr(line) else # If local_stack_p is TRUE and insn.handles_sp? is false, stack values are only available in local variables # for stack. So we need to replace those macros if local_stack_p is TRUE here. case line when /\bGET_SP\(\)/ # reg_cfp->sp src << to_cstr(line.sub(/\bGET_SP\(\)/, local_stack_p ? '(stack + stack_size)' : 'GET_SP()')) when /\bSTACK_ADDR_FROM_TOP\((?<num>[^)]+)\)/ # #define STACK_ADDR_FROM_TOP(n) (GET_SP()-(n)) num = Regexp.last_match[:num] src << to_cstr(line.sub(/\bSTACK_ADDR_FROM_TOP\(([^)]+)\)/, local_stack_p ? "(stack + (stack_size - (#{num})))" : "STACK_ADDR_FROM_TOP(#{num})")) when /\bTOPN\((?<num>[^)]+)\)/ # #define TOPN(n) (*(GET_SP()-(n)-1)) num = Regexp.last_match[:num] src << to_cstr(line.sub(/\bTOPN\(([^)]+)\)/, local_stack_p ? "*(stack + (stack_size - (#{num}) - 1))" : "TOPN(#{num})")) else src << to_cstr(line) end end end end return next_pos end def compile_pc_and_sp(src, insn, stack_size, sp_inc, local_stack_p, next_pos) # JIT: When an insn is leaf, we don't need to Move pc for a catch table on catch_except_p, #caller_locations, # and rb_profile_frames. For check_ints, we lazily move PC when we have interruptions. pc_moved_p = false unless insn.always_leaf? || insn.leaf_without_check_ints? src << " reg_cfp->pc = original_body_iseq + #{next_pos};\n" # ADD_PC(INSN_ATTR(width)); pc_moved_p = true end # JIT: move sp to use or preserve stack variables if local_stack_p # sp motion is optimized away for `handles_sp? #=> false` case. # Thus sp should be set properly before `goto cancel`. if insn.handles_sp? # JIT-only behavior (pushing JIT's local variables to VM's stack): push_size = -sp_inc + insn.rets.size - insn.pops.size src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{push_size};\n" push_size.times do |i| src << " *(reg_cfp->sp + #{i - push_size}) = stack[#{stack_size - push_size + i}];\n" end end else if insn.handles_sp? src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size - insn.pops.size};\n" # POPN(INSN_ATTR(popn)); else src << " reg_cfp->sp = vm_base_ptr(reg_cfp) + #{stack_size};\n" end end return pc_moved_p end # Print the block to cancel inlined method call. It's supporting only `opt_send_without_block` for now. def compile_inlined_cancel_handler(src, body, inline_context) src << "\ncancel:\n" src << " rb_mjit_recompile_inlining(original_iseq);\n" # Swap pc/sp set on cancel with original pc/sp. src << " const VALUE *current_pc = reg_cfp->pc;\n" src << " VALUE *current_sp = reg_cfp->sp;\n" src << " reg_cfp->pc = orig_pc;\n" src << " reg_cfp->sp = orig_sp;\n\n" # Lazily push the current call frame. src << " struct rb_calling_info calling;\n" src << " calling.block_handler = VM_BLOCK_HANDLER_NONE;\n" # assumes `opt_send_without_block` src << " calling.argc = #{inline_context.orig_argc};\n" src << " calling.recv = reg_cfp->self;\n" src << " reg_cfp->self = orig_self;\n" # fastpath_applied_iseq_p checks rb_simple_iseq_p, which ensures has_opt == FALSE src << " vm_call_iseq_setup_normal(ec, reg_cfp, &calling, (const rb_callable_method_entry_t *)#{inline_context.me}, 0, #{inline_context.param_size}, #{inline_context.local_size});\n\n" # Start usual cancel from here. src << " reg_cfp = ec->cfp;\n" # work on the new frame src << " reg_cfp->pc = current_pc;\n" src << " reg_cfp->sp = current_sp;\n" (0...body.stack_max).each do |i| # should be always `status->local_stack_p` src << " *(vm_base_ptr(reg_cfp) + #{i}) = stack[#{i}];\n" end # We're not just returning Qundef here so that caller's normal cancel handler can # push back `stack` to `cfp->sp`. src << " return vm_exec(ec, false);\n" end # Print the block to cancel JIT execution. def compile_cancel_handler(src, body, status) if status.inlined_iseqs.nil? # the current ISeq is being inlined compile_inlined_cancel_handler(src, body, status.inline_context) return end src << "\nsend_cancel:\n" src << " rb_mjit_recompile_send(original_iseq);\n" src << " goto cancel;\n" src << "\nivar_cancel:\n" src << " rb_mjit_recompile_ivar(original_iseq);\n" src << " goto cancel;\n" src << "\nexivar_cancel:\n" src << " rb_mjit_recompile_exivar(original_iseq);\n" src << " goto cancel;\n" src << "\nconst_cancel:\n" src << " rb_mjit_recompile_const(original_iseq);\n" src << " goto cancel;\n" src << "\ncancel:\n" if status.local_stack_p (0...body.stack_max).each do |i| src << " *(vm_base_ptr(reg_cfp) + #{i}) = stack[#{i}];\n" end end src << " return Qundef;\n" end def precompile_inlinable_child_iseq(src, child_iseq, status, ci, cc, pos) child_status = C.compile_status.new # not freed for now child_status.compiled_iseq = status.compiled_iseq child_status.compiled_id = status.compiled_id init_compile_status(child_status, child_iseq.body, false) # not freed for now child_status.inline_context.orig_argc = C.vm_ci_argc(ci) child_status.inline_context.me = vm_cc_cme(cc).to_i child_status.inline_context.param_size = child_iseq.body.param.size child_status.inline_context.local_size = child_iseq.body.local_table_size if child_iseq.body.ci_size > 0 && child_status.cc_entries_index == -1 return false end src << "ALWAYS_INLINE(static VALUE _mjit#{status.compiled_id}_inlined_#{pos}(rb_execution_context_t *ec, rb_control_frame_t *reg_cfp, const VALUE orig_self, const rb_iseq_t *original_iseq));\n" src << "static inline VALUE\n_mjit#{status.compiled_id}_inlined_#{pos}(rb_execution_context_t *ec, rb_control_frame_t *reg_cfp, const VALUE orig_self, const rb_iseq_t *original_iseq)\n{\n" src << " const VALUE *orig_pc = reg_cfp->pc;\n" src << " VALUE *orig_sp = reg_cfp->sp;\n" success = compile_body(src, child_iseq, child_status) src << "\n} /* end of _mjit#{status.compiled_id}_inlined_#{pos} */\n\n" return success; end def precompile_inlinable_iseqs(src, iseq, status) body = iseq.body pos = 0 while pos < body.iseq_size insn = INSNS.fetch(C.rb_vm_insn_decode(body.iseq_encoded[pos])) if insn.name == :opt_send_without_block || insn.name == :opt_size # `compile_inlined_cancel_handler` supports only `opt_send_without_block` cd = C.CALL_DATA.new(body.iseq_encoded[pos + 1]) ci = cd.ci cc = captured_cc_entries(status)[call_data_index(cd, body)] # use copy to avoid race condition if (child_iseq = rb_mjit_inlinable_iseq(ci, cc)) != nil status.inlined_iseqs[pos] = child_iseq.body if C.mjit_opts.verbose >= 1 # print beforehand because ISeq may be GCed during copy job. child_location = child_iseq.body.location $stderr.puts "JIT inline: #{child_location.label}@#{C.rb_iseq_path(child_iseq)}:#{C.rb_iseq_first_lineno(child_iseq)} " \ "=> #{iseq.body.location.label}@#{C.rb_iseq_path(iseq)}:#{C.rb_iseq_first_lineno(iseq)}" end if !precompile_inlinable_child_iseq(src, child_iseq, status, ci, cc, pos) return false end end end pos += insn.len end return true end def init_compile_status(status, body, compile_root_p) status.stack_size_for_pos = Fiddle.malloc(Fiddle::SIZEOF_INT * body.iseq_size) body.iseq_size.times do |i| status.stack_size_for_pos[i] = C.NOT_COMPILED_STACK_SIZE end if compile_root_p status.inlined_iseqs = Fiddle.malloc(Fiddle::SIZEOF_VOIDP * body.iseq_size) body.iseq_size.times do |i| status.inlined_iseqs[i] = nil end end if body.ci_size > 0 status.cc_entries_index = C.mjit_capture_cc_entries(status.compiled_iseq, body) else status.cc_entries_index = -1 end if compile_root_p status.compile_info = rb_mjit_iseq_compile_info(body) else status.compile_info = Fiddle.malloc(C.rb_mjit_compile_info.sizeof) status.compile_info.disable_ivar_cache = false status.compile_info.disable_exivar_cache = false status.compile_info.disable_send_cache = false status.compile_info.disable_inlining = false status.compile_info.disable_const_cache = false end end def using_ivar?(body) pos = 0 while pos < body.iseq_size insn = INSNS.fetch(C.rb_vm_insn_decode(body.iseq_encoded[pos])) case insn.name when :getinstancevariable, :setinstancevariable return true end pos += insn.len end return false end # Expand simple macro that doesn't require dynamic C code. def expand_simple_macros(arg_expr) arg_expr.dup.tap do |expr| # For `leave`. We can't proceed next ISeq in the same JIT function. expr.gsub!(/^(?<indent>\s*)RESTORE_REGS\(\);\n/) do indent = Regexp.last_match[:indent] <<-end.gsub(/^ {12}/, '') #if OPT_CALL_THREADED_CODE #{indent}rb_ec_thread_ptr(ec)->retval = val; #{indent}return 0; #else #{indent}return val; #endif end end expr.gsub!(/^(?<indent>\s*)NEXT_INSN\(\);\n/) do indent = Regexp.last_match[:indent] <<-end.gsub(/^ {12}/, '') #{indent}UNREACHABLE_RETURN(Qundef); end end end end def to_cstr(expr) expr.gsub(/^(?!#)/, ' ') # indent everything but preprocessor lines end # Interpret unsigned long as signed long (VALUE -> OFFSET) def cast_offset(offset) if offset >= 1 << 8 * Fiddle::SIZEOF_VOIDP - 1 # negative offset -= 1 << 8 * Fiddle::SIZEOF_VOIDP end offset end def captured_cc_entries(status) status.compiled_iseq.mjit_unit.cc_entries + status.cc_entries_index end def call_data_index(cd, body) cd - body.call_data end def vm_cc_cme(cc) # TODO: add VM_ASSERT like actual vm_cc_cme cc.cme_ end def def_iseq_ptr(method_def) C.rb_iseq_check(method_def.body.iseq.iseqptr) end def rb_mjit_iseq_compile_info(body) body.mjit_unit.compile_info end def ISEQ_IS_SIZE(body) body.ic_size + body.ivc_size + body.ise_size + body.icvarc_size end # Return true if an object of the class may be a special const (immediate). # It's "maybe" because Integer and Float are not guaranteed to be an immediate. # If this returns false, rb_class_of could be optimzied to RBASIC_CLASS. def maybe_special_const?(klass) [ C.rb_cFalseClass, C.rb_cNilClass, C.rb_cTrueClass, C.rb_cInteger, C.rb_cSymbol, C.rb_cFloat, ].include?(klass) end def has_valid_method_type?(cc) vm_cc_cme(cc) != nil end def already_compiled?(status, pos) status.stack_size_for_pos[pos] != C.NOT_COMPILED_STACK_SIZE end # Return an iseq pointer if cc has inlinable iseq. def rb_mjit_inlinable_iseq(ci, cc) if has_valid_method_type?(cc) && C.vm_ci_flag(ci) & C.VM_CALL_TAILCALL == 0 && # inlining only non-tailcall path vm_cc_cme(cc).def.type == C.VM_METHOD_TYPE_ISEQ && C.fastpath_applied_iseq_p(ci, cc, iseq = def_iseq_ptr(vm_cc_cme(cc).def)) && inlinable_iseq_p(iseq.body) # CC_SET_FASTPATH in vm_callee_setup_arg return iseq end return nil end # Return true if the ISeq can be inlined without pushing a new control frame. def inlinable_iseq_p(body) # 1) If catch_except_p, caller frame should be preserved when callee catches an exception. # Then we need to wrap `vm_exec()` but then we can't inline the call inside it. # # 2) If `body->catch_except_p` is false and `handles_sp?` of an insn is false, # sp is not moved as we assume `status->local_stack_p = !body->catch_except_p`. # # 3) If `body->catch_except_p` is false and `always_leaf?` of an insn is true, # pc is not moved. if body.catch_except_p return false end pos = 0 while pos < body.iseq_size insn = INSNS.fetch(C.rb_vm_insn_decode(body.iseq_encoded[pos])) # All insns in the ISeq except `leave` (to be overridden in the inlined code) # should meet following strong assumptions: # * Do not require `cfp->sp` motion # * Do not move `cfp->pc` # * Do not read any `cfp->pc` if insn.name == :invokebuiltin || insn.name == :opt_invokebuiltin_delegate || insn.name == :opt_invokebuiltin_delegate_leave # builtin insn's inlinability is handled by `Primitive.attr! 'inline'` per iseq if !body.builtin_inline_p return false; end elsif insn.name != :leave && C.insn_may_depend_on_sp_or_pc(insn.bin, body.iseq_encoded + (pos + 1)) return false end # At this moment, `cfp->ep` in an inlined method is not working. case insn.name when :getlocal, :getlocal_WC_0, :getlocal_WC_1, :setlocal, :setlocal_WC_0, :setlocal_WC_1, :getblockparam, :getblockparamproxy, :setblockparam return false end pos += insn.len end return true end # CPointer::Struct could be nil on field reference, and this is a helper to # handle that case while using CPointer::Struct#to_s in most cases. # @param struct [RubyVM::MJIT::CPointer::Struct] def to_addr(struct) struct&.to_s || 'NULL' end def parent_shape_id(shape_id) return shape_id if shape_id == C.INVALID_SHAPE_ID parent_id = C.rb_shape_get_shape_by_id(shape_id).parent_id parent = C.rb_shape_get_shape_by_id(parent_id) if parent.type == C.SHAPE_CAPACITY_CHANGE parent.parent_id else parent_id end end end
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