diff options
Diffstat (limited to 'lib/ruby_vm/rjit')
-rw-r--r-- | lib/ruby_vm/rjit/.document | 1 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/assembler.rb | 1140 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/block.rb | 11 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/branch_stub.rb | 24 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/c_pointer.rb | 394 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/c_type.rb | 99 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/code_block.rb | 91 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/compiler.rb | 518 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/context.rb | 377 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/entry_stub.rb | 7 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/exit_compiler.rb | 164 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/hooks.rb | 36 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/insn_compiler.rb | 6002 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/invariants.rb | 155 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/jit_state.rb | 65 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/stats.rb | 191 | ||||
-rw-r--r-- | lib/ruby_vm/rjit/type.rb | 221 |
17 files changed, 9496 insertions, 0 deletions
diff --git a/lib/ruby_vm/rjit/.document b/lib/ruby_vm/rjit/.document new file mode 100644 index 0000000000..0a603afe3d --- /dev/null +++ b/lib/ruby_vm/rjit/.document @@ -0,0 +1 @@ +stats.rb diff --git a/lib/ruby_vm/rjit/assembler.rb b/lib/ruby_vm/rjit/assembler.rb new file mode 100644 index 0000000000..645072d11b --- /dev/null +++ b/lib/ruby_vm/rjit/assembler.rb @@ -0,0 +1,1140 @@ +# frozen_string_literal: true +module RubyVM::RJIT + # 8-bit memory access + class BytePtr < Data.define(:reg, :disp); end + + # 32-bit memory access + class DwordPtr < Data.define(:reg, :disp); end + + # 64-bit memory access + QwordPtr = Array + + # SystemV x64 calling convention + C_ARGS = [:rdi, :rsi, :rdx, :rcx, :r8, :r9] + C_RET = :rax + + # https://cdrdv2.intel.com/v1/dl/getContent/671110 + # Mostly an x86_64 assembler, but this also has some stuff that is useful for any architecture. + class Assembler + # rel8 jumps are made with labels + class Label < Data.define(:id, :name); end + + # rel32 is inserted as [Rel32, Rel32Pad..] and converted on #resolve_rel32 + class Rel32 < Data.define(:addr); end + Rel32Pad = Object.new + + # A set of ModR/M values encoded on #insn + class ModRM < Data.define(:mod, :reg, :rm); end + Mod00 = 0b00 # Mod 00: [reg] + Mod01 = 0b01 # Mod 01: [reg]+disp8 + Mod10 = 0b10 # Mod 10: [reg]+disp32 + Mod11 = 0b11 # Mod 11: reg + + # REX = 0100WR0B + REX_B = 0b01000001 + REX_R = 0b01000100 + REX_W = 0b01001000 + + # Operand matchers + R32 = -> (op) { op.is_a?(Symbol) && r32?(op) } + R64 = -> (op) { op.is_a?(Symbol) && r64?(op) } + IMM8 = -> (op) { op.is_a?(Integer) && imm8?(op) } + IMM32 = -> (op) { op.is_a?(Integer) && imm32?(op) } + IMM64 = -> (op) { op.is_a?(Integer) && imm64?(op) } + + def initialize + @bytes = [] + @labels = {} + @label_id = 0 + @comments = Hash.new { |h, k| h[k] = [] } + @blocks = Hash.new { |h, k| h[k] = [] } + @stub_starts = Hash.new { |h, k| h[k] = [] } + @stub_ends = Hash.new { |h, k| h[k] = [] } + @pos_markers = Hash.new { |h, k| h[k] = [] } + end + + def assemble(addr) + set_code_addrs(addr) + resolve_rel32(addr) + resolve_labels + + write_bytes(addr) + + @pos_markers.each do |write_pos, markers| + markers.each { |marker| marker.call(addr + write_pos) } + end + @bytes.size + ensure + @bytes.clear + end + + def size + @bytes.size + end + + # + # Instructions + # + + def add(dst, src) + case [dst, src] + # ADD r/m64, imm8 (Mod 00: [reg]) + in [QwordPtr[R64 => dst_reg], IMM8 => src_imm] + # REX.W + 83 /0 ib + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod00, reg: 0, rm: dst_reg], + imm: imm8(src_imm), + ) + # ADD r/m64, imm8 (Mod 11: reg) + in [R64 => dst_reg, IMM8 => src_imm] + # REX.W + 83 /0 ib + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod11, reg: 0, rm: dst_reg], + imm: imm8(src_imm), + ) + # ADD r/m64 imm32 (Mod 11: reg) + in [R64 => dst_reg, IMM32 => src_imm] + # REX.W + 81 /0 id + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x81, + mod_rm: ModRM[mod: Mod11, reg: 0, rm: dst_reg], + imm: imm32(src_imm), + ) + # ADD r/m64, r64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 01 /r + # MR: Operand 1: ModRM:r/m (r, w), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x01, + mod_rm: ModRM[mod: Mod11, reg: src_reg, rm: dst_reg], + ) + end + end + + def and(dst, src) + case [dst, src] + # AND r/m64, imm8 (Mod 11: reg) + in [R64 => dst_reg, IMM8 => src_imm] + # REX.W + 83 /4 ib + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod11, reg: 4, rm: dst_reg], + imm: imm8(src_imm), + ) + # AND r/m64, imm32 (Mod 11: reg) + in [R64 => dst_reg, IMM32 => src_imm] + # REX.W + 81 /4 id + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x81, + mod_rm: ModRM[mod: Mod11, reg: 4, rm: dst_reg], + imm: imm32(src_imm), + ) + # AND r64, r/m64 (Mod 01: [reg]+disp8) + in [R64 => dst_reg, QwordPtr[R64 => src_reg, IMM8 => src_disp]] + # REX.W + 23 /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x23, + mod_rm: ModRM[mod: Mod01, reg: dst_reg, rm: src_reg], + disp: imm8(src_disp), + ) + end + end + + def call(dst) + case dst + # CALL rel32 + in Integer => dst_addr + # E8 cd + # D: Operand 1: Offset + insn(opcode: 0xe8, imm: rel32(dst_addr)) + # CALL r/m64 (Mod 11: reg) + in R64 => dst_reg + # FF /2 + # M: Operand 1: ModRM:r/m (r) + insn( + opcode: 0xff, + mod_rm: ModRM[mod: Mod11, reg: 2, rm: dst_reg], + ) + end + end + + def cmove(dst, src) + case [dst, src] + # CMOVE r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 44 /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x44], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + end + end + + def cmovg(dst, src) + case [dst, src] + # CMOVG r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 4F /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x4f], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + end + end + + def cmovge(dst, src) + case [dst, src] + # CMOVGE r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 4D /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x4d], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + end + end + + def cmovl(dst, src) + case [dst, src] + # CMOVL r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 4C /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x4c], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + end + end + + def cmovle(dst, src) + case [dst, src] + # CMOVLE r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 4E /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x4e], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + end + end + + def cmovne(dst, src) + case [dst, src] + # CMOVNE r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 45 /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x45], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + end + end + + def cmovnz(dst, src) + case [dst, src] + # CMOVNZ r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 45 /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x45], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + end + end + + def cmovz(dst, src) + case [dst, src] + # CMOVZ r64, r/m64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 0F 44 /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x44], + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + # CMOVZ r64, r/m64 (Mod 01: [reg]+disp8) + in [R64 => dst_reg, QwordPtr[R64 => src_reg, IMM8 => src_disp]] + # REX.W + 0F 44 /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: [0x0f, 0x44], + mod_rm: ModRM[mod: Mod01, reg: dst_reg, rm: src_reg], + disp: imm8(src_disp), + ) + end + end + + def cmp(left, right) + case [left, right] + # CMP r/m8, imm8 (Mod 01: [reg]+disp8) + in [BytePtr[R64 => left_reg, IMM8 => left_disp], IMM8 => right_imm] + # 80 /7 ib + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + opcode: 0x80, + mod_rm: ModRM[mod: Mod01, reg: 7, rm: left_reg], + disp: left_disp, + imm: imm8(right_imm), + ) + # CMP r/m32, imm32 (Mod 01: [reg]+disp8) + in [DwordPtr[R64 => left_reg, IMM8 => left_disp], IMM32 => right_imm] + # 81 /7 id + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + opcode: 0x81, + mod_rm: ModRM[mod: Mod01, reg: 7, rm: left_reg], + disp: left_disp, + imm: imm32(right_imm), + ) + # CMP r/m64, imm8 (Mod 01: [reg]+disp8) + in [QwordPtr[R64 => left_reg, IMM8 => left_disp], IMM8 => right_imm] + # REX.W + 83 /7 ib + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod01, reg: 7, rm: left_reg], + disp: left_disp, + imm: imm8(right_imm), + ) + # CMP r/m64, imm32 (Mod 01: [reg]+disp8) + in [QwordPtr[R64 => left_reg, IMM8 => left_disp], IMM32 => right_imm] + # REX.W + 81 /7 id + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x81, + mod_rm: ModRM[mod: Mod01, reg: 7, rm: left_reg], + disp: left_disp, + imm: imm32(right_imm), + ) + # CMP r/m64, imm8 (Mod 10: [reg]+disp32) + in [QwordPtr[R64 => left_reg, IMM32 => left_disp], IMM8 => right_imm] + # REX.W + 83 /7 ib + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod10, reg: 7, rm: left_reg], + disp: imm32(left_disp), + imm: imm8(right_imm), + ) + # CMP r/m64, imm8 (Mod 11: reg) + in [R64 => left_reg, IMM8 => right_imm] + # REX.W + 83 /7 ib + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod11, reg: 7, rm: left_reg], + imm: imm8(right_imm), + ) + # CMP r/m64, imm32 (Mod 11: reg) + in [R64 => left_reg, IMM32 => right_imm] + # REX.W + 81 /7 id + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x81, + mod_rm: ModRM[mod: Mod11, reg: 7, rm: left_reg], + imm: imm32(right_imm), + ) + # CMP r/m64, r64 (Mod 01: [reg]+disp8) + in [QwordPtr[R64 => left_reg, IMM8 => left_disp], R64 => right_reg] + # REX.W + 39 /r + # MR: Operand 1: ModRM:r/m (r), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x39, + mod_rm: ModRM[mod: Mod01, reg: right_reg, rm: left_reg], + disp: left_disp, + ) + # CMP r/m64, r64 (Mod 10: [reg]+disp32) + in [QwordPtr[R64 => left_reg, IMM32 => left_disp], R64 => right_reg] + # REX.W + 39 /r + # MR: Operand 1: ModRM:r/m (r), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x39, + mod_rm: ModRM[mod: Mod10, reg: right_reg, rm: left_reg], + disp: imm32(left_disp), + ) + # CMP r/m64, r64 (Mod 11: reg) + in [R64 => left_reg, R64 => right_reg] + # REX.W + 39 /r + # MR: Operand 1: ModRM:r/m (r), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x39, + mod_rm: ModRM[mod: Mod11, reg: right_reg, rm: left_reg], + ) + end + end + + def jbe(dst) + case dst + # JBE rel8 + in Label => dst_label + # 76 cb + insn(opcode: 0x76, imm: dst_label) + # JBE rel32 + in Integer => dst_addr + # 0F 86 cd + insn(opcode: [0x0f, 0x86], imm: rel32(dst_addr)) + end + end + + def je(dst) + case dst + # JE rel8 + in Label => dst_label + # 74 cb + insn(opcode: 0x74, imm: dst_label) + # JE rel32 + in Integer => dst_addr + # 0F 84 cd + insn(opcode: [0x0f, 0x84], imm: rel32(dst_addr)) + end + end + + def jl(dst) + case dst + # JL rel32 + in Integer => dst_addr + # 0F 8C cd + insn(opcode: [0x0f, 0x8c], imm: rel32(dst_addr)) + end + end + + def jmp(dst) + case dst + # JZ rel8 + in Label => dst_label + # EB cb + insn(opcode: 0xeb, imm: dst_label) + # JMP rel32 + in Integer => dst_addr + # E9 cd + insn(opcode: 0xe9, imm: rel32(dst_addr)) + # JMP r/m64 (Mod 01: [reg]+disp8) + in QwordPtr[R64 => dst_reg, IMM8 => dst_disp] + # FF /4 + insn(opcode: 0xff, mod_rm: ModRM[mod: Mod01, reg: 4, rm: dst_reg], disp: dst_disp) + # JMP r/m64 (Mod 11: reg) + in R64 => dst_reg + # FF /4 + insn(opcode: 0xff, mod_rm: ModRM[mod: Mod11, reg: 4, rm: dst_reg]) + end + end + + def jne(dst) + case dst + # JNE rel8 + in Label => dst_label + # 75 cb + insn(opcode: 0x75, imm: dst_label) + # JNE rel32 + in Integer => dst_addr + # 0F 85 cd + insn(opcode: [0x0f, 0x85], imm: rel32(dst_addr)) + end + end + + def jnz(dst) + case dst + # JE rel8 + in Label => dst_label + # 75 cb + insn(opcode: 0x75, imm: dst_label) + # JNZ rel32 + in Integer => dst_addr + # 0F 85 cd + insn(opcode: [0x0f, 0x85], imm: rel32(dst_addr)) + end + end + + def jo(dst) + case dst + # JO rel32 + in Integer => dst_addr + # 0F 80 cd + insn(opcode: [0x0f, 0x80], imm: rel32(dst_addr)) + end + end + + def jz(dst) + case dst + # JZ rel8 + in Label => dst_label + # 74 cb + insn(opcode: 0x74, imm: dst_label) + # JZ rel32 + in Integer => dst_addr + # 0F 84 cd + insn(opcode: [0x0f, 0x84], imm: rel32(dst_addr)) + end + end + + def lea(dst, src) + case [dst, src] + # LEA r64,m (Mod 01: [reg]+disp8) + in [R64 => dst_reg, QwordPtr[R64 => src_reg, IMM8 => src_disp]] + # REX.W + 8D /r + # RM: Operand 1: ModRM:reg (w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x8d, + mod_rm: ModRM[mod: Mod01, reg: dst_reg, rm: src_reg], + disp: imm8(src_disp), + ) + # LEA r64,m (Mod 10: [reg]+disp32) + in [R64 => dst_reg, QwordPtr[R64 => src_reg, IMM32 => src_disp]] + # REX.W + 8D /r + # RM: Operand 1: ModRM:reg (w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x8d, + mod_rm: ModRM[mod: Mod10, reg: dst_reg, rm: src_reg], + disp: imm32(src_disp), + ) + end + end + + def mov(dst, src) + case dst + in R32 => dst_reg + case src + # MOV r32 r/m32 (Mod 01: [reg]+disp8) + in DwordPtr[R64 => src_reg, IMM8 => src_disp] + # 8B /r + # RM: Operand 1: ModRM:reg (w), Operand 2: ModRM:r/m (r) + insn( + opcode: 0x8b, + mod_rm: ModRM[mod: Mod01, reg: dst_reg, rm: src_reg], + disp: src_disp, + ) + # MOV r32, imm32 (Mod 11: reg) + in IMM32 => src_imm + # B8+ rd id + # OI: Operand 1: opcode + rd (w), Operand 2: imm8/16/32/64 + insn( + opcode: 0xb8, + rd: dst_reg, + imm: imm32(src_imm), + ) + end + in R64 => dst_reg + case src + # MOV r64, r/m64 (Mod 00: [reg]) + in QwordPtr[R64 => src_reg] + # REX.W + 8B /r + # RM: Operand 1: ModRM:reg (w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x8b, + mod_rm: ModRM[mod: Mod00, reg: dst_reg, rm: src_reg], + ) + # MOV r64, r/m64 (Mod 01: [reg]+disp8) + in QwordPtr[R64 => src_reg, IMM8 => src_disp] + # REX.W + 8B /r + # RM: Operand 1: ModRM:reg (w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x8b, + mod_rm: ModRM[mod: Mod01, reg: dst_reg, rm: src_reg], + disp: src_disp, + ) + # MOV r64, r/m64 (Mod 10: [reg]+disp32) + in QwordPtr[R64 => src_reg, IMM32 => src_disp] + # REX.W + 8B /r + # RM: Operand 1: ModRM:reg (w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x8b, + mod_rm: ModRM[mod: Mod10, reg: dst_reg, rm: src_reg], + disp: imm32(src_disp), + ) + # MOV r64, r/m64 (Mod 11: reg) + in R64 => src_reg + # REX.W + 8B /r + # RM: Operand 1: ModRM:reg (w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x8b, + mod_rm: ModRM[mod: Mod11, reg: dst_reg, rm: src_reg], + ) + # MOV r/m64, imm32 (Mod 11: reg) + in IMM32 => src_imm + # REX.W + C7 /0 id + # MI: Operand 1: ModRM:r/m (w), Operand 2: imm8/16/32/64 + insn( + prefix: REX_W, + opcode: 0xc7, + mod_rm: ModRM[mod: Mod11, reg: 0, rm: dst_reg], + imm: imm32(src_imm), + ) + # MOV r64, imm64 + in IMM64 => src_imm + # REX.W + B8+ rd io + # OI: Operand 1: opcode + rd (w), Operand 2: imm8/16/32/64 + insn( + prefix: REX_W, + opcode: 0xb8, + rd: dst_reg, + imm: imm64(src_imm), + ) + end + in DwordPtr[R64 => dst_reg, IMM8 => dst_disp] + case src + # MOV r/m32, imm32 (Mod 01: [reg]+disp8) + in IMM32 => src_imm + # C7 /0 id + # MI: Operand 1: ModRM:r/m (w), Operand 2: imm8/16/32/64 + insn( + opcode: 0xc7, + mod_rm: ModRM[mod: Mod01, reg: 0, rm: dst_reg], + disp: dst_disp, + imm: imm32(src_imm), + ) + end + in QwordPtr[R64 => dst_reg] + case src + # MOV r/m64, imm32 (Mod 00: [reg]) + in IMM32 => src_imm + # REX.W + C7 /0 id + # MI: Operand 1: ModRM:r/m (w), Operand 2: imm8/16/32/64 + insn( + prefix: REX_W, + opcode: 0xc7, + mod_rm: ModRM[mod: Mod00, reg: 0, rm: dst_reg], + imm: imm32(src_imm), + ) + # MOV r/m64, r64 (Mod 00: [reg]) + in R64 => src_reg + # REX.W + 89 /r + # MR: Operand 1: ModRM:r/m (w), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x89, + mod_rm: ModRM[mod: Mod00, reg: src_reg, rm: dst_reg], + ) + end + in QwordPtr[R64 => dst_reg, IMM8 => dst_disp] + # Optimize encoding when disp is 0 + return mov([dst_reg], src) if dst_disp == 0 + + case src + # MOV r/m64, imm32 (Mod 01: [reg]+disp8) + in IMM32 => src_imm + # REX.W + C7 /0 id + # MI: Operand 1: ModRM:r/m (w), Operand 2: imm8/16/32/64 + insn( + prefix: REX_W, + opcode: 0xc7, + mod_rm: ModRM[mod: Mod01, reg: 0, rm: dst_reg], + disp: dst_disp, + imm: imm32(src_imm), + ) + # MOV r/m64, r64 (Mod 01: [reg]+disp8) + in R64 => src_reg + # REX.W + 89 /r + # MR: Operand 1: ModRM:r/m (w), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x89, + mod_rm: ModRM[mod: Mod01, reg: src_reg, rm: dst_reg], + disp: dst_disp, + ) + end + in QwordPtr[R64 => dst_reg, IMM32 => dst_disp] + case src + # MOV r/m64, imm32 (Mod 10: [reg]+disp32) + in IMM32 => src_imm + # REX.W + C7 /0 id + # MI: Operand 1: ModRM:r/m (w), Operand 2: imm8/16/32/64 + insn( + prefix: REX_W, + opcode: 0xc7, + mod_rm: ModRM[mod: Mod10, reg: 0, rm: dst_reg], + disp: imm32(dst_disp), + imm: imm32(src_imm), + ) + # MOV r/m64, r64 (Mod 10: [reg]+disp32) + in R64 => src_reg + # REX.W + 89 /r + # MR: Operand 1: ModRM:r/m (w), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x89, + mod_rm: ModRM[mod: Mod10, reg: src_reg, rm: dst_reg], + disp: imm32(dst_disp), + ) + end + end + end + + def or(dst, src) + case [dst, src] + # OR r/m64, imm8 (Mod 11: reg) + in [R64 => dst_reg, IMM8 => src_imm] + # REX.W + 83 /1 ib + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod11, reg: 1, rm: dst_reg], + imm: imm8(src_imm), + ) + # OR r/m64, imm32 (Mod 11: reg) + in [R64 => dst_reg, IMM32 => src_imm] + # REX.W + 81 /1 id + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x81, + mod_rm: ModRM[mod: Mod11, reg: 1, rm: dst_reg], + imm: imm32(src_imm), + ) + # OR r64, r/m64 (Mod 01: [reg]+disp8) + in [R64 => dst_reg, QwordPtr[R64 => src_reg, IMM8 => src_disp]] + # REX.W + 0B /r + # RM: Operand 1: ModRM:reg (r, w), Operand 2: ModRM:r/m (r) + insn( + prefix: REX_W, + opcode: 0x0b, + mod_rm: ModRM[mod: Mod01, reg: dst_reg, rm: src_reg], + disp: imm8(src_disp), + ) + end + end + + def push(src) + case src + # PUSH r64 + in R64 => src_reg + # 50+rd + # O: Operand 1: opcode + rd (r) + insn(opcode: 0x50, rd: src_reg) + end + end + + def pop(dst) + case dst + # POP r64 + in R64 => dst_reg + # 58+ rd + # O: Operand 1: opcode + rd (r) + insn(opcode: 0x58, rd: dst_reg) + end + end + + def ret + # RET + # Near return: A return to a procedure within the current code segment + insn(opcode: 0xc3) + end + + def sar(dst, src) + case [dst, src] + in [R64 => dst_reg, IMM8 => src_imm] + # REX.W + C1 /7 ib + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8 + insn( + prefix: REX_W, + opcode: 0xc1, + mod_rm: ModRM[mod: Mod11, reg: 7, rm: dst_reg], + imm: imm8(src_imm), + ) + end + end + + def sub(dst, src) + case [dst, src] + # SUB r/m64, imm8 (Mod 11: reg) + in [R64 => dst_reg, IMM8 => src_imm] + # REX.W + 83 /5 ib + # MI: Operand 1: ModRM:r/m (r, w), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0x83, + mod_rm: ModRM[mod: Mod11, reg: 5, rm: dst_reg], + imm: imm8(src_imm), + ) + # SUB r/m64, r64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 29 /r + # MR: Operand 1: ModRM:r/m (r, w), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x29, + mod_rm: ModRM[mod: Mod11, reg: src_reg, rm: dst_reg], + ) + end + end + + def test(left, right) + case [left, right] + # TEST r/m8*, imm8 (Mod 01: [reg]+disp8) + in [BytePtr[R64 => left_reg, IMM8 => left_disp], IMM8 => right_imm] + # REX + F6 /0 ib + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + opcode: 0xf6, + mod_rm: ModRM[mod: Mod01, reg: 0, rm: left_reg], + disp: left_disp, + imm: imm8(right_imm), + ) + # TEST r/m64, imm32 (Mod 01: [reg]+disp8) + in [QwordPtr[R64 => left_reg, IMM8 => left_disp], IMM32 => right_imm] + # REX.W + F7 /0 id + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0xf7, + mod_rm: ModRM[mod: Mod01, reg: 0, rm: left_reg], + disp: left_disp, + imm: imm32(right_imm), + ) + # TEST r/m64, imm32 (Mod 10: [reg]+disp32) + in [QwordPtr[R64 => left_reg, IMM32 => left_disp], IMM32 => right_imm] + # REX.W + F7 /0 id + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0xf7, + mod_rm: ModRM[mod: Mod10, reg: 0, rm: left_reg], + disp: imm32(left_disp), + imm: imm32(right_imm), + ) + # TEST r/m64, imm32 (Mod 11: reg) + in [R64 => left_reg, IMM32 => right_imm] + # REX.W + F7 /0 id + # MI: Operand 1: ModRM:r/m (r), Operand 2: imm8/16/32 + insn( + prefix: REX_W, + opcode: 0xf7, + mod_rm: ModRM[mod: Mod11, reg: 0, rm: left_reg], + imm: imm32(right_imm), + ) + # TEST r/m32, r32 (Mod 11: reg) + in [R32 => left_reg, R32 => right_reg] + # 85 /r + # MR: Operand 1: ModRM:r/m (r), Operand 2: ModRM:reg (r) + insn( + opcode: 0x85, + mod_rm: ModRM[mod: Mod11, reg: right_reg, rm: left_reg], + ) + # TEST r/m64, r64 (Mod 11: reg) + in [R64 => left_reg, R64 => right_reg] + # REX.W + 85 /r + # MR: Operand 1: ModRM:r/m (r), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x85, + mod_rm: ModRM[mod: Mod11, reg: right_reg, rm: left_reg], + ) + end + end + + def xor(dst, src) + case [dst, src] + # XOR r/m64, r64 (Mod 11: reg) + in [R64 => dst_reg, R64 => src_reg] + # REX.W + 31 /r + # MR: Operand 1: ModRM:r/m (r, w), Operand 2: ModRM:reg (r) + insn( + prefix: REX_W, + opcode: 0x31, + mod_rm: ModRM[mod: Mod11, reg: src_reg, rm: dst_reg], + ) + end + end + + # + # Utilities + # + + attr_reader :comments + + def comment(message) + @comments[@bytes.size] << message + end + + # Mark the starting address of a block + def block(block) + @blocks[@bytes.size] << block + end + + # Mark the starting/ending addresses of a stub + def stub(stub) + @stub_starts[@bytes.size] << stub + yield + ensure + @stub_ends[@bytes.size] << stub + end + + def pos_marker(&block) + @pos_markers[@bytes.size] << block + end + + def new_label(name) + Label.new(id: @label_id += 1, name:) + end + + # @param [RubyVM::RJIT::Assembler::Label] label + def write_label(label) + @labels[label] = @bytes.size + end + + def incr_counter(name) + if C.rjit_opts.stats + comment("increment counter #{name}") + mov(:rax, C.rb_rjit_counters[name].to_i) + add([:rax], 1) # TODO: lock + end + end + + private + + def insn(prefix: 0, opcode:, rd: nil, mod_rm: nil, disp: nil, imm: nil) + # Determine prefix + if rd + prefix |= REX_B if extended_reg?(rd) + opcode += reg_code(rd) + end + if mod_rm + prefix |= REX_R if mod_rm.reg.is_a?(Symbol) && extended_reg?(mod_rm.reg) + prefix |= REX_B if mod_rm.rm.is_a?(Symbol) && extended_reg?(mod_rm.rm) + end + + # Encode insn + if prefix > 0 + @bytes.push(prefix) + end + @bytes.push(*Array(opcode)) + if mod_rm + mod_rm_byte = encode_mod_rm( + mod: mod_rm.mod, + reg: mod_rm.reg.is_a?(Symbol) ? reg_code(mod_rm.reg) : mod_rm.reg, + rm: mod_rm.rm.is_a?(Symbol) ? reg_code(mod_rm.rm) : mod_rm.rm, + ) + @bytes.push(mod_rm_byte) + end + if disp + @bytes.push(*Array(disp)) + end + if imm + @bytes.push(*imm) + end + end + + def reg_code(reg) + reg_code_extended(reg).first + end + + # Table 2-2. 32-Bit Addressing Forms with the ModR/M Byte + # + # 7 6 5 4 3 2 1 0 + # +--+--+--+--+--+--+--+--+ + # | Mod | Reg/ | R/M | + # | | Opcode | | + # +--+--+--+--+--+--+--+--+ + # + # The r/m field can specify a register as an operand or it can be combined + # with the mod field to encode an addressing mode. + # + # /0: R/M is 0 (not used) + # /r: R/M is a register + def encode_mod_rm(mod:, reg: 0, rm: 0) + if mod > 0b11 + raise ArgumentError, "too large Mod: #{mod}" + end + if reg > 0b111 + raise ArgumentError, "too large Reg/Opcode: #{reg}" + end + if rm > 0b111 + raise ArgumentError, "too large R/M: #{rm}" + end + (mod << 6) + (reg << 3) + rm + end + + # ib: 1 byte + def imm8(imm) + unless imm8?(imm) + raise ArgumentError, "unexpected imm8: #{imm}" + end + [imm].pack('c').unpack('c*') # TODO: consider uimm + end + + # id: 4 bytes + def imm32(imm) + unless imm32?(imm) + raise ArgumentError, "unexpected imm32: #{imm}" + end + [imm].pack('l').unpack('c*') # TODO: consider uimm + end + + # io: 8 bytes + def imm64(imm) + unless imm64?(imm) + raise ArgumentError, "unexpected imm64: #{imm}" + end + imm_bytes(imm, 8) + end + + def imm_bytes(imm, num_bytes) + bytes = [] + bits = imm + num_bytes.times do + bytes << (bits & 0xff) + bits >>= 8 + end + if bits != 0 + raise ArgumentError, "unexpected imm with #{num_bytes} bytes: #{imm}" + end + bytes + end + + def rel32(addr) + [Rel32.new(addr), Rel32Pad, Rel32Pad, Rel32Pad] + end + + def set_code_addrs(write_addr) + (@bytes.size + 1).times do |index| + @blocks.fetch(index, []).each do |block| + block.start_addr = write_addr + index + end + @stub_starts.fetch(index, []).each do |stub| + stub.start_addr = write_addr + index + end + @stub_ends.fetch(index, []).each do |stub| + stub.end_addr = write_addr + index + end + end + end + + def resolve_rel32(write_addr) + @bytes.each_with_index do |byte, index| + if byte.is_a?(Rel32) + src_addr = write_addr + index + 4 # offset 4 bytes for rel32 itself + dst_addr = byte.addr + rel32 = dst_addr - src_addr + raise "unexpected offset: #{rel32}" unless imm32?(rel32) + imm32(rel32).each_with_index do |rel_byte, rel_index| + @bytes[index + rel_index] = rel_byte + end + end + end + end + + def resolve_labels + @bytes.each_with_index do |byte, index| + if byte.is_a?(Label) + src_index = index + 1 # offset 1 byte for rel8 itself + dst_index = @labels.fetch(byte) + rel8 = dst_index - src_index + raise "unexpected offset: #{rel8}" unless imm8?(rel8) + @bytes[index] = rel8 + end + end + end + + def write_bytes(addr) + Fiddle::Pointer.new(addr)[0, @bytes.size] = @bytes.pack('c*') + end + end + + module OperandMatcher + def imm8?(imm) + (-0x80..0x7f).include?(imm) + end + + def imm32?(imm) + (-0x8000_0000..0x7fff_ffff).include?(imm) # TODO: consider uimm + end + + def imm64?(imm) + (-0x8000_0000_0000_0000..0xffff_ffff_ffff_ffff).include?(imm) + end + + def r32?(reg) + if extended_reg?(reg) + reg.end_with?('d') + else + reg.start_with?('e') + end + end + + def r64?(reg) + if extended_reg?(reg) + reg.match?(/\Ar\d+\z/) + else + reg.start_with?('r') + end + end + + def extended_reg?(reg) + reg_code_extended(reg).last + end + + def reg_code_extended(reg) + case reg + # Not extended + when :al, :ax, :eax, :rax then [0, false] + when :cl, :cx, :ecx, :rcx then [1, false] + when :dl, :dx, :edx, :rdx then [2, false] + when :bl, :bx, :ebx, :rbx then [3, false] + when :ah, :sp, :esp, :rsp then [4, false] + when :ch, :bp, :ebp, :rbp then [5, false] + when :dh, :si, :esi, :rsi then [6, false] + when :bh, :di, :edi, :rdi then [7, false] + # Extended + when :r8b, :r8w, :r8d, :r8 then [0, true] + when :r9b, :r9w, :r9d, :r9 then [1, true] + when :r10b, :r10w, :r10d, :r10 then [2, true] + when :r11b, :r11w, :r11d, :r11 then [3, true] + when :r12b, :r12w, :r12d, :r12 then [4, true] + when :r13b, :r13w, :r13d, :r13 then [5, true] + when :r14b, :r14w, :r14d, :r14 then [6, true] + when :r15b, :r15w, :r15d, :r15 then [7, true] + else raise ArgumentError, "unexpected reg: #{reg.inspect}" + end + end + end + + class Assembler + include OperandMatcher + extend OperandMatcher + end +end diff --git a/lib/ruby_vm/rjit/block.rb b/lib/ruby_vm/rjit/block.rb new file mode 100644 index 0000000000..cfdaade8b1 --- /dev/null +++ b/lib/ruby_vm/rjit/block.rb @@ -0,0 +1,11 @@ +class RubyVM::RJIT::Block < Struct.new( + :iseq, # @param `` + :pc, # @param [Integer] Starting PC + :ctx, # @param [RubyVM::RJIT::Context] **Starting** Context (TODO: freeze?) + :start_addr, # @param [Integer] Starting address of this block's JIT code + :entry_exit, # @param [Integer] Address of entry exit (optional) + :incoming, # @param [Array<RubyVM::RJIT::BranchStub>] Incoming branches + :invalidated, # @param [TrueClass,FalseClass] true if already invalidated +) + def initialize(incoming: [], invalidated: false, **) = super +end diff --git a/lib/ruby_vm/rjit/branch_stub.rb b/lib/ruby_vm/rjit/branch_stub.rb new file mode 100644 index 0000000000..b9fe78b744 --- /dev/null +++ b/lib/ruby_vm/rjit/branch_stub.rb @@ -0,0 +1,24 @@ +module RubyVM::RJIT + # Branch shapes + Next0 = :Next0 # target0 is a fallthrough + Next1 = :Next1 # target1 is a fallthrough + Default = :Default # neither targets is a fallthrough + + class BranchStub < Struct.new( + :iseq, # @param [RubyVM::RJIT::CPointer::Struct_rb_iseq_struct] Branch target ISEQ + :shape, # @param [Symbol] Next0, Next1, or Default + :target0, # @param [RubyVM::RJIT::BranchTarget] First branch target + :target1, # @param [RubyVM::RJIT::BranchTarget,NilClass] Second branch target (optional) + :compile, # @param [Proc] A callback to (re-)generate this branch stub + :start_addr, # @param [Integer] Stub source start address to be re-generated + :end_addr, # @param [Integer] Stub source end address to be re-generated + ) + end + + class BranchTarget < Struct.new( + :pc, + :ctx, + :address, + ) + end +end diff --git a/lib/ruby_vm/rjit/c_pointer.rb b/lib/ruby_vm/rjit/c_pointer.rb new file mode 100644 index 0000000000..db00c4cd11 --- /dev/null +++ b/lib/ruby_vm/rjit/c_pointer.rb @@ -0,0 +1,394 @@ +module RubyVM::RJIT + # Every class under this namespace is a pointer. Even if the type is + # immediate, it shouldn't be dereferenced until `*` is called. + module CPointer + # Note: We'd like to avoid alphabetic method names to avoid a conflict + # with member methods. to_i and to_s are considered an exception. + class Struct + # @param name [String] + # @param sizeof [Integer] + # @param members [Hash{ Symbol => [RubyVM::RJIT::CType::*, Integer, TrueClass] }] + def initialize(addr, sizeof, members) + @addr = addr + @sizeof = sizeof + @members = members + end + + # Get a raw address + def to_i + @addr + end + + # Serialized address for generated code + def to_s + "0x#{@addr.to_s(16)}" + end + + # Pointer diff + def -(struct) + raise ArgumentError if self.class != struct.class + (@addr - struct.to_i) / @sizeof + end + + # Primitive API that does no automatic dereference + # TODO: remove this? + # @param member [Symbol] + def [](member) + type, offset = @members.fetch(member) + type.new(@addr + offset / 8) + end + + private + + # @param member [Symbol] + # @param value [Object] + def []=(member, value) + type, offset = @members.fetch(member) + type[@addr + offset / 8] = value + end + + # @param size [Integer] + # @param members [Hash{ Symbol => [Integer, RubyVM::RJIT::CType::*] }] + def self.define(size, members) + Class.new(self) do + # Return the size of this type + define_singleton_method(:size) { size } + + # Return the offset to a field + define_singleton_method(:offsetof) do |field, *fields| + member, offset = members.fetch(field) + offset /= 8 + unless fields.empty? + offset += member.offsetof(*fields) + end + offset + end + + # Return member names + define_singleton_method(:members) { members.keys } + + define_method(:initialize) do |addr = nil| + if addr.nil? # TODO: get rid of this feature later + addr = Fiddle.malloc(size) + end + super(addr, size, members) + end + + members.each do |member, (type, offset, to_ruby)| + # Intelligent API that does automatic dereference + define_method(member) do + value = self[member] + if value.respond_to?(:*) + value = value.* + end + if to_ruby + value = C.to_ruby(value) + end + value + end + + define_method("#{member}=") do |value| + if to_ruby + value = C.to_value(value) + end + self[member] = value + end + end + end + end + end + + # Note: We'd like to avoid alphabetic method names to avoid a conflict + # with member methods. to_i is considered an exception. + class Union + # @param _name [String] To be used when it starts defining a union pointer class + # @param sizeof [Integer] + # @param members [Hash{ Symbol => RubyVM::RJIT::CType::* }] + def initialize(addr, sizeof, members) + @addr = addr + @sizeof = sizeof + @members = members + end + + # Get a raw address + def to_i + @addr + end + + # Move addr to access this pointer like an array + def +(index) + raise ArgumentError unless index.is_a?(Integer) + self.class.new(@addr + index * @sizeof) + end + + # Pointer diff + def -(union) + raise ArgumentError if self.class != union.class + (@addr - union.instance_variable_get(:@addr)) / @sizeof + end + + # @param sizeof [Integer] + # @param members [Hash{ Symbol => RubyVM::RJIT::CType::* }] + def self.define(sizeof, members) + Class.new(self) do + # Return the size of this type + define_singleton_method(:sizeof) { sizeof } + + # Part of Struct's offsetof implementation + define_singleton_method(:offsetof) do |field, *fields| + member = members.fetch(field) + offset = 0 + unless fields.empty? + offset += member.offsetof(*fields) + end + offset + end + + define_method(:initialize) do |addr| + super(addr, sizeof, members) + end + + members.each do |member, type| + # Intelligent API that does automatic dereference + define_method(member) do + value = type.new(@addr) + if value.respond_to?(:*) + value = value.* + end + value + end + end + end + end + end + + class Immediate + # @param addr [Integer] + # @param size [Integer] + # @param pack [String] + def initialize(addr, size, pack) + @addr = addr + @size = size + @pack = pack + end + + # Get a raw address + def to_i + @addr + end + + # Move addr to addess this pointer like an array + def +(index) + Immediate.new(@addr + index * @size, @size, @pack) + end + + # Dereference + def * + self[0] + end + + # Array access + def [](index) + return nil if @addr == 0 + Fiddle::Pointer.new(@addr + index * @size)[0, @size].unpack1(@pack) + end + + # Array set + def []=(index, value) + Fiddle::Pointer.new(@addr + index * @size)[0, @size] = [value].pack(@pack) + end + + # Serialized address for generated code. Used for embedding things like body->iseq_encoded. + def to_s + "0x#{Integer(@addr).to_s(16)}" + end + + # @param fiddle_type [Integer] Fiddle::TYPE_* + def self.define(fiddle_type) + size = Fiddle::PackInfo::SIZE_MAP.fetch(fiddle_type) + pack = Fiddle::PackInfo::PACK_MAP.fetch(fiddle_type) + + Class.new(self) do + define_method(:initialize) do |addr| + super(addr, size, pack) + end + + define_singleton_method(:size) do + size + end + + # Type-level []=: Used by struct fields + define_singleton_method(:[]=) do |addr, value| + Fiddle::Pointer.new(addr)[0, size] = [value].pack(pack) + end + end + end + end + + # -Fiddle::TYPE_CHAR Immediate with special handling of true/false + class Bool < Immediate.define(-Fiddle::TYPE_CHAR) + # Dereference + def * + return nil if @addr == 0 + super != 0 + end + + def self.[]=(addr, value) + super(addr, value ? 1 : 0) + end + end + + # Basically Immediate but without #* to skip auto-dereference of structs. + class Array + attr_reader :type + + # @param addr [Integer] + # @param type [Class] RubyVM::RJIT::CType::* + def initialize(addr, type) + @addr = addr + @type = type + end + + # Array access + def [](index) + @type.new(@addr)[index] + end + + # Array set + # @param index [Integer] + # @param value [Integer, RubyVM::RJIT::CPointer::Struct] an address itself or an object that return an address with to_i + def []=(index, value) + @type.new(@addr)[index] = value + end + + private + + def self.define(block) + Class.new(self) do + define_method(:initialize) do |addr| + super(addr, block.call) + end + end + end + end + + class Pointer + attr_reader :type + + # @param addr [Integer] + # @param type [Class] RubyVM::RJIT::CType::* + def initialize(addr, type) + @addr = addr + @type = type + end + + # Move addr to addess this pointer like an array + def +(index) + raise ArgumentError unless index.is_a?(Integer) + Pointer.new(@addr + index * Fiddle::SIZEOF_VOIDP, @type) + end + + # Dereference + def * + return nil if dest_addr == 0 + @type.new(dest_addr) + end + + # Array access + def [](index) + (self + index).* + end + + # Array set + # @param index [Integer] + # @param value [Integer, RubyVM::RJIT::CPointer::Struct] an address itself or an object that return an address with to_i + def []=(index, value) + Fiddle::Pointer.new(@addr + index * Fiddle::SIZEOF_VOIDP)[0, Fiddle::SIZEOF_VOIDP] = + [value.to_i].pack(Fiddle::PackInfo::PACK_MAP[Fiddle::TYPE_VOIDP]) + end + + # Get a raw address + def to_i + @addr + end + + private + + def dest_addr + Fiddle::Pointer.new(@addr)[0, Fiddle::SIZEOF_VOIDP].unpack1(Fiddle::PackInfo::PACK_MAP[Fiddle::TYPE_VOIDP]) + end + + def self.define(block) + Class.new(self) do + define_method(:initialize) do |addr| + super(addr, block.call) + end + + # Type-level []=: Used by struct fields + # @param addr [Integer] + # @param value [Integer, RubyVM::RJIT::CPointer::Struct] an address itself, or an object that return an address with to_i + define_singleton_method(:[]=) do |addr, value| + value = value.to_i + Fiddle::Pointer.new(addr)[0, Fiddle::SIZEOF_VOIDP] = [value].pack(Fiddle::PackInfo::PACK_MAP[Fiddle::TYPE_VOIDP]) + end + end + end + end + + class BitField + # @param addr [Integer] + # @param width [Integer] + # @param offset [Integer] + def initialize(addr, width, offset) + @addr = addr + @width = width + @offset = offset + end + + # Dereference + def * + byte = Fiddle::Pointer.new(@addr)[0, Fiddle::SIZEOF_CHAR].unpack('c').first + if @width == 1 + bit = (1 & (byte >> @offset)) + bit == 1 + elsif @width <= 8 && @offset == 0 + bitmask = @width.times.map { |i| 1 << i }.sum + byte & bitmask + else + raise NotImplementedError.new("not-implemented bit field access: width=#{@width} offset=#{@offset}") + end + end + + # @param width [Integer] + # @param offset [Integer] + def self.define(width, offset) + Class.new(self) do + define_method(:initialize) do |addr| + super(addr, width, offset) + end + end + end + end + + # Give a name to a dynamic CPointer class to see it on inspect + def self.with_class_name(prefix, name, cache: false, &block) + return block.call if !name.nil? && name.empty? + + # Use a cached result only if cache: true + class_name = "#{prefix}_#{name}" + klass = + if cache && self.const_defined?(class_name) + self.const_get(class_name) + else + block.call + end + + # Give it a name unless it's already defined + unless self.const_defined?(class_name) + self.const_set(class_name, klass) + end + + klass + end + end +end diff --git a/lib/ruby_vm/rjit/c_type.rb b/lib/ruby_vm/rjit/c_type.rb new file mode 100644 index 0000000000..3b313a658b --- /dev/null +++ b/lib/ruby_vm/rjit/c_type.rb @@ -0,0 +1,99 @@ +require 'fiddle' +require 'fiddle/pack' +require_relative 'c_pointer' + +module RubyVM::RJIT + module CType + module Struct + # @param name [String] + # @param members [Hash{ Symbol => [Integer, RubyVM::RJIT::CType::*] }] + def self.new(name, sizeof, **members) + name = members.keys.join('_') if name.empty? + CPointer.with_class_name('Struct', name) do + CPointer::Struct.define(sizeof, members) + end + end + end + + module Union + # @param name [String] + # @param members [Hash{ Symbol => RubyVM::RJIT::CType::* }] + def self.new(name, sizeof, **members) + name = members.keys.join('_') if name.empty? + CPointer.with_class_name('Union', name) do + CPointer::Union.define(sizeof, members) + end + end + end + + module Immediate + # @param fiddle_type [Integer] + def self.new(fiddle_type) + name = Fiddle.constants.find do |const| + const.start_with?('TYPE_') && Fiddle.const_get(const) == fiddle_type.abs + end&.to_s + name.delete_prefix!('TYPE_') + if fiddle_type.negative? + name.prepend('U') + end + CPointer.with_class_name('Immediate', name, cache: true) do + CPointer::Immediate.define(fiddle_type) + end + end + + # @param type [String] + def self.parse(ctype) + new(Fiddle::Importer.parse_ctype(ctype)) + end + + def self.find(size, signed) + fiddle_type = TYPE_MAP.fetch(size) + fiddle_type = -fiddle_type unless signed + new(fiddle_type) + end + + TYPE_MAP = Fiddle::PackInfo::SIZE_MAP.map { |type, size| [size, type.abs] }.to_h + private_constant :TYPE_MAP + end + + module Bool + def self.new + CPointer::Bool + end + end + + class Array + def self.new(&block) + CPointer.with_class_name('Array', block.object_id.to_s) do + CPointer::Array.define(block) + end + end + end + + class Pointer + # This takes a block to avoid "stack level too deep" on a cyclic reference + # @param block [Proc] + def self.new(&block) + CPointer.with_class_name('Pointer', block.object_id.to_s) do + CPointer::Pointer.define(block) + end + end + end + + module BitField + # @param width [Integer] + # @param offset [Integer] + def self.new(width, offset) + CPointer.with_class_name('BitField', "#{offset}_#{width}") do + CPointer::BitField.define(width, offset) + end + end + end + + # Types that are referenced but not part of code generation targets + Stub = ::Struct.new(:name) + + # Types that it failed to figure out from the header + Unknown = Module.new + end +end diff --git a/lib/ruby_vm/rjit/code_block.rb b/lib/ruby_vm/rjit/code_block.rb new file mode 100644 index 0000000000..260bd98671 --- /dev/null +++ b/lib/ruby_vm/rjit/code_block.rb @@ -0,0 +1,91 @@ +module RubyVM::RJIT + class CodeBlock + # @param mem_block [Integer] JIT buffer address + # @param mem_size [Integer] JIT buffer size + # @param outliend [TrueClass,FalseClass] true for outlined CodeBlock + def initialize(mem_block:, mem_size:, outlined: false) + @comments = Hash.new { |h, k| h[k] = [] } if dump_disasm? + @mem_block = mem_block + @mem_size = mem_size + @write_pos = 0 + @outlined = outlined + end + + # @param asm [RubyVM::RJIT::Assembler] + def write(asm) + return 0 if @write_pos + asm.size >= @mem_size + + start_addr = write_addr + + # Write machine code + C.mprotect_write(@mem_block, @mem_size) + @write_pos += asm.assemble(start_addr) + C.mprotect_exec(@mem_block, @mem_size) + + end_addr = write_addr + + # Convert comment indexes to addresses + asm.comments.each do |index, comments| + @comments[start_addr + index] += comments if dump_disasm? + end + asm.comments.clear + + # Dump disasm if --rjit-dump-disasm + if C.rjit_opts.dump_disasm && start_addr < end_addr + dump_disasm(start_addr, end_addr) + end + start_addr + end + + def set_write_addr(addr) + @write_pos = addr - @mem_block + @comments.delete(addr) if dump_disasm? + end + + def with_write_addr(addr) + old_write_pos = @write_pos + set_write_addr(addr) + yield + ensure + @write_pos = old_write_pos + end + + def write_addr + @mem_block + @write_pos + end + + def include?(addr) + (@mem_block...(@mem_block + @mem_size)).include?(addr) + end + + def dump_disasm(from, to, io: STDOUT, color: true, test: false) + C.dump_disasm(from, to, test:).each do |address, mnemonic, op_str| + @comments.fetch(address, []).each do |comment| + io.puts colorize(" # #{comment}", bold: true, color:) + end + io.puts colorize(" 0x#{format("%x", address)}: #{mnemonic} #{op_str}", color:) + end + io.puts + end + + private + + def colorize(text, bold: false, color:) + return text unless color + buf = +'' + buf << "\e[1m" if bold + buf << "\e[34m" if @outlined + buf << text + buf << "\e[0m" + buf + end + + def bold(text) + "\e[1m#{text}\e[0m" + end + + def dump_disasm? + C.rjit_opts.dump_disasm + end + end +end diff --git a/lib/ruby_vm/rjit/compiler.rb b/lib/ruby_vm/rjit/compiler.rb new file mode 100644 index 0000000000..e5c3adf0ec --- /dev/null +++ b/lib/ruby_vm/rjit/compiler.rb @@ -0,0 +1,518 @@ +require 'ruby_vm/rjit/assembler' +require 'ruby_vm/rjit/block' +require 'ruby_vm/rjit/branch_stub' +require 'ruby_vm/rjit/code_block' +require 'ruby_vm/rjit/context' +require 'ruby_vm/rjit/entry_stub' +require 'ruby_vm/rjit/exit_compiler' +require 'ruby_vm/rjit/insn_compiler' +require 'ruby_vm/rjit/instruction' +require 'ruby_vm/rjit/invariants' +require 'ruby_vm/rjit/jit_state' +require 'ruby_vm/rjit/type' + +module RubyVM::RJIT + # Compilation status + KeepCompiling = :KeepCompiling + CantCompile = :CantCompile + EndBlock = :EndBlock + + # Ruby constants + Qtrue = Fiddle::Qtrue + Qfalse = Fiddle::Qfalse + Qnil = Fiddle::Qnil + Qundef = Fiddle::Qundef + + # Callee-saved registers + # TODO: support using r12/r13 here + EC = :r14 + CFP = :r15 + SP = :rbx + + # Scratch registers: rax, rcx, rdx + + # Mark objects in this Array during GC + GC_REFS = [] + + # Maximum number of versions per block + # 1 means always create generic versions + MAX_VERSIONS = 4 + + class Compiler + attr_accessor :write_pos + + def self.decode_insn(encoded) + INSNS.fetch(C.rb_vm_insn_decode(encoded)) + end + + def initialize + mem_size = C.rjit_opts.exec_mem_size * 1024 * 1024 + mem_block = C.mmap(mem_size) + @cb = CodeBlock.new(mem_block: mem_block, mem_size: mem_size / 2) + @ocb = CodeBlock.new(mem_block: mem_block + mem_size / 2, mem_size: mem_size / 2, outlined: true) + @exit_compiler = ExitCompiler.new + @insn_compiler = InsnCompiler.new(@cb, @ocb, @exit_compiler) + Invariants.initialize(@cb, @ocb, self, @exit_compiler) + end + + # Compile an ISEQ from its entry point. + # @param iseq `RubyVM::RJIT::CPointer::Struct_rb_iseq_t` + # @param cfp `RubyVM::RJIT::CPointer::Struct_rb_control_frame_t` + def compile(iseq, cfp) + return unless supported_platform? + pc = cfp.pc.to_i + jit = JITState.new(iseq:, cfp:) + asm = Assembler.new + compile_prologue(asm, iseq, pc) + compile_block(asm, jit:, pc:) + iseq.body.jit_entry = @cb.write(asm) + rescue Exception => e + STDERR.puts "#{e.class}: #{e.message}" + STDERR.puts e.backtrace + exit 1 + end + + # Compile an entry. + # @param entry [RubyVM::RJIT::EntryStub] + def entry_stub_hit(entry_stub, cfp) + # Compile a new entry guard as a next entry + pc = cfp.pc.to_i + next_entry = Assembler.new.then do |asm| + compile_entry_chain_guard(asm, cfp.iseq, pc) + @cb.write(asm) + end + + # Try to find an existing compiled version of this block + ctx = Context.new + block = find_block(cfp.iseq, pc, ctx) + if block + # If an existing block is found, generate a jump to the block. + asm = Assembler.new + asm.jmp(block.start_addr) + @cb.write(asm) + else + # If this block hasn't yet been compiled, generate blocks after the entry guard. + asm = Assembler.new + jit = JITState.new(iseq: cfp.iseq, cfp:) + compile_block(asm, jit:, pc:, ctx:) + @cb.write(asm) + + block = jit.block + end + + # Regenerate the previous entry + @cb.with_write_addr(entry_stub.start_addr) do + # The last instruction of compile_entry_chain_guard is jne + asm = Assembler.new + asm.jne(next_entry) + @cb.write(asm) + end + + return block.start_addr + rescue Exception => e + STDERR.puts e.full_message + exit 1 + end + + # Compile a branch stub. + # @param branch_stub [RubyVM::RJIT::BranchStub] + # @param cfp `RubyVM::RJIT::CPointer::Struct_rb_control_frame_t` + # @param target0_p [TrueClass,FalseClass] + # @return [Integer] The starting address of the compiled branch stub + def branch_stub_hit(branch_stub, cfp, target0_p) + # Update cfp->pc for `jit.at_current_insn?` + target = target0_p ? branch_stub.target0 : branch_stub.target1 + cfp.pc = target.pc + + # Reuse an existing block if it already exists + block = find_block(branch_stub.iseq, target.pc, target.ctx) + + # If the branch stub's jump is the last code, allow overwriting part of + # the old branch code with the new block code. + fallthrough = block.nil? && @cb.write_addr == branch_stub.end_addr + if fallthrough + # If the branch stub's jump is the last code, allow overwriting part of + # the old branch code with the new block code. + @cb.set_write_addr(branch_stub.start_addr) + branch_stub.shape = target0_p ? Next0 : Next1 + Assembler.new.tap do |branch_asm| + branch_stub.compile.call(branch_asm) + @cb.write(branch_asm) + end + end + + # Reuse or generate a block + if block + target.address = block.start_addr + else + jit = JITState.new(iseq: branch_stub.iseq, cfp:) + target.address = Assembler.new.then do |asm| + compile_block(asm, jit:, pc: target.pc, ctx: target.ctx.dup) + @cb.write(asm) + end + block = jit.block + end + block.incoming << branch_stub # prepare for invalidate_block + + # Re-generate the branch code for non-fallthrough cases + unless fallthrough + @cb.with_write_addr(branch_stub.start_addr) do + branch_asm = Assembler.new + branch_stub.compile.call(branch_asm) + @cb.write(branch_asm) + end + end + + return target.address + rescue Exception => e + STDERR.puts e.full_message + exit 1 + end + + # @param iseq `RubyVM::RJIT::CPointer::Struct_rb_iseq_t` + # @param pc [Integer] + def invalidate_blocks(iseq, pc) + list_blocks(iseq, pc).each do |block| + invalidate_block(block) + end + + # If they were the ISEQ's first blocks, re-compile RJIT entry as well + if iseq.body.iseq_encoded.to_i == pc + iseq.body.jit_entry = 0 + iseq.body.jit_entry_calls = 0 + end + end + + def invalidate_block(block) + iseq = block.iseq + # Avoid touching GCed ISEQs. We assume it won't be re-entered. + return unless C.imemo_type_p(iseq, C.imemo_iseq) + + # Remove this block from the version array + remove_block(iseq, block) + + # Invalidate the block with entry exit + unless block.invalidated + @cb.with_write_addr(block.start_addr) do + asm = Assembler.new + asm.comment('invalidate_block') + asm.jmp(block.entry_exit) + @cb.write(asm) + end + block.invalidated = true + end + + # Re-stub incoming branches + block.incoming.each do |branch_stub| + target = [branch_stub.target0, branch_stub.target1].compact.find do |target| + target.pc == block.pc && target.ctx == block.ctx + end + next if target.nil? + # TODO: Could target.address be a stub address? Is invalidation not needed in that case? + + # If the target being re-generated is currently a fallthrough block, + # the fallthrough code must be rewritten with a jump to the stub. + if target.address == branch_stub.end_addr + branch_stub.shape = Default + end + + target.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(block.ctx, ocb_asm, branch_stub, target == branch_stub.target0) + @ocb.write(ocb_asm) + end + @cb.with_write_addr(branch_stub.start_addr) do + branch_asm = Assembler.new + branch_stub.compile.call(branch_asm) + @cb.write(branch_asm) + end + end + end + + private + + # Callee-saved: rbx, rsp, rbp, r12, r13, r14, r15 + # Caller-saved: rax, rdi, rsi, rdx, rcx, r8, r9, r10, r11 + # + # @param asm [RubyVM::RJIT::Assembler] + def compile_prologue(asm, iseq, pc) + asm.comment('RJIT entry point') + + # Save callee-saved registers used by JITed code + asm.push(CFP) + asm.push(EC) + asm.push(SP) + + # Move arguments EC and CFP to dedicated registers + asm.mov(EC, :rdi) + asm.mov(CFP, :rsi) + + # Load sp to a dedicated register + asm.mov(SP, [CFP, C.rb_control_frame_t.offsetof(:sp)]) # rbx = cfp->sp + + # Setup cfp->jit_return + asm.mov(:rax, leave_exit) + asm.mov([CFP, C.rb_control_frame_t.offsetof(:jit_return)], :rax) + + # We're compiling iseqs that we *expect* to start at `insn_idx`. But in + # the case of optional parameters, the interpreter can set the pc to a + # different location depending on the optional parameters. If an iseq + # has optional parameters, we'll add a runtime check that the PC we've + # compiled for is the same PC that the interpreter wants us to run with. + # If they don't match, then we'll take a side exit. + if iseq.body.param.flags.has_opt + compile_entry_chain_guard(asm, iseq, pc) + end + end + + def compile_entry_chain_guard(asm, iseq, pc) + entry_stub = EntryStub.new + stub_addr = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_entry_stub(ocb_asm, entry_stub) + @ocb.write(ocb_asm) + end + + asm.comment('guard expected PC') + asm.mov(:rax, pc) + asm.cmp([CFP, C.rb_control_frame_t.offsetof(:pc)], :rax) + + asm.stub(entry_stub) do + asm.jne(stub_addr) + end + end + + # @param asm [RubyVM::RJIT::Assembler] + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + def compile_block(asm, jit:, pc:, ctx: Context.new) + # Mark the block start address and prepare an exit code storage + ctx = limit_block_versions(jit.iseq, pc, ctx) + block = Block.new(iseq: jit.iseq, pc:, ctx: ctx.dup) + jit.block = block + asm.block(block) + + iseq = jit.iseq + asm.comment("Block: #{iseq.body.location.label}@#{C.rb_iseq_path(iseq)}:#{iseq_lineno(iseq, pc)}") + + # Compile each insn + index = (pc - iseq.body.iseq_encoded.to_i) / C.VALUE.size + while index < iseq.body.iseq_size + # Set the current instruction + insn = self.class.decode_insn(iseq.body.iseq_encoded[index]) + jit.pc = (iseq.body.iseq_encoded + index).to_i + jit.stack_size_for_pc = ctx.stack_size + jit.side_exit_for_pc.clear + + # If previous instruction requested to record the boundary + if jit.record_boundary_patch_point + # Generate an exit to this instruction and record it + exit_pos = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_side_exit(jit.pc, ctx, ocb_asm) + @ocb.write(ocb_asm) + end + Invariants.record_global_inval_patch(asm, exit_pos) + jit.record_boundary_patch_point = false + end + + # In debug mode, verify our existing assumption + if C.rjit_opts.verify_ctx && jit.at_current_insn? + verify_ctx(jit, ctx) + end + + case status = @insn_compiler.compile(jit, ctx, asm, insn) + when KeepCompiling + # For now, reset the chain depth after each instruction as only the + # first instruction in the block can concern itself with the depth. + ctx.chain_depth = 0 + + index += insn.len + when EndBlock + # TODO: pad nops if entry exit exists (not needed for x86_64?) + break + when CantCompile + # Rewind stack_size using ctx.with_stack_size to allow stack_size changes + # before you return CantCompile. + @exit_compiler.compile_side_exit(jit.pc, ctx.with_stack_size(jit.stack_size_for_pc), asm) + + # If this is the first instruction, this block never needs to be invalidated. + if block.pc == iseq.body.iseq_encoded.to_i + index * C.VALUE.size + block.invalidated = true + end + + break + else + raise "compiling #{insn.name} returned unexpected status: #{status.inspect}" + end + end + + incr_counter(:compiled_block_count) + add_block(iseq, block) + end + + def leave_exit + @leave_exit ||= Assembler.new.then do |asm| + @exit_compiler.compile_leave_exit(asm) + @ocb.write(asm) + end + end + + def incr_counter(name) + if C.rjit_opts.stats + C.rb_rjit_counters[name][0] += 1 + end + end + + # Produce a generic context when the block version limit is hit for the block + def limit_block_versions(iseq, pc, ctx) + # Guard chains implement limits separately, do nothing + if ctx.chain_depth > 0 + return ctx.dup + end + + # If this block version we're about to add will hit the version limit + if list_blocks(iseq, pc).size + 1 >= MAX_VERSIONS + # Produce a generic context that stores no type information, + # but still respects the stack_size and sp_offset constraints. + # This new context will then match all future requests. + generic_ctx = Context.new + generic_ctx.stack_size = ctx.stack_size + generic_ctx.sp_offset = ctx.sp_offset + + if ctx.diff(generic_ctx) == TypeDiff::Incompatible + raise 'should substitute a compatible context' + end + + return generic_ctx + end + + return ctx.dup + end + + def list_blocks(iseq, pc) + rjit_blocks(iseq)[pc] + end + + # @param [Integer] pc + # @param [RubyVM::RJIT::Context] ctx + # @return [RubyVM::RJIT::Block,NilClass] + def find_block(iseq, pc, ctx) + versions = rjit_blocks(iseq)[pc] + + best_version = nil + best_diff = Float::INFINITY + + versions.each do |block| + # Note that we always prefer the first matching + # version found because of inline-cache chains + case ctx.diff(block.ctx) + in TypeDiff::Compatible[diff] if diff < best_diff + best_version = block + best_diff = diff + else + end + end + + return best_version + end + + # @param [RubyVM::RJIT::Block] block + def add_block(iseq, block) + rjit_blocks(iseq)[block.pc] << block + end + + # @param [RubyVM::RJIT::Block] block + def remove_block(iseq, block) + rjit_blocks(iseq)[block.pc].delete(block) + end + + def rjit_blocks(iseq) + # Guard against ISEQ GC at random moments + + unless C.imemo_type_p(iseq, C.imemo_iseq) + return Hash.new { |h, k| h[k] = [] } + end + + unless iseq.body.rjit_blocks + iseq.body.rjit_blocks = Hash.new { |blocks, pc| blocks[pc] = [] } + # For some reason, rb_rjit_iseq_mark didn't protect this Hash + # from being freed. So we rely on GC_REFS to keep the Hash. + GC_REFS << iseq.body.rjit_blocks + end + iseq.body.rjit_blocks + end + + def iseq_lineno(iseq, pc) + C.rb_iseq_line_no(iseq, (pc - iseq.body.iseq_encoded.to_i) / C.VALUE.size) + rescue RangeError # bignum too big to convert into `unsigned long long' (RangeError) + -1 + end + + # Verify the ctx's types and mappings against the compile-time stack, self, and locals. + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + def verify_ctx(jit, ctx) + # Only able to check types when at current insn + assert(jit.at_current_insn?) + + self_val = jit.peek_at_self + self_val_type = Type.from(self_val) + + # Verify self operand type + assert_compatible(self_val_type, ctx.get_opnd_type(SelfOpnd)) + + # Verify stack operand types + [ctx.stack_size, MAX_TEMP_TYPES].min.times do |i| + learned_mapping, learned_type = ctx.get_opnd_mapping(StackOpnd[i]) + stack_val = jit.peek_at_stack(i) + val_type = Type.from(stack_val) + + case learned_mapping + in MapToSelf + if C.to_value(self_val) != C.to_value(stack_val) + raise "verify_ctx: stack value was mapped to self, but values did not match:\n"\ + "stack: #{stack_val.inspect}, self: #{self_val.inspect}" + end + in MapToLocal[local_idx] + local_val = jit.peek_at_local(local_idx) + if C.to_value(local_val) != C.to_value(stack_val) + raise "verify_ctx: stack value was mapped to local, but values did not match:\n"\ + "stack: #{stack_val.inspect}, local: #{local_val.inspect}" + end + in MapToStack + # noop + end + + # If the actual type differs from the learned type + assert_compatible(val_type, learned_type) + end + + # Verify local variable types + local_table_size = jit.iseq.body.local_table_size + [local_table_size, MAX_TEMP_TYPES].min.times do |i| + learned_type = ctx.get_local_type(i) + local_val = jit.peek_at_local(i) + local_type = Type.from(local_val) + + assert_compatible(local_type, learned_type) + end + end + + def assert_compatible(actual_type, ctx_type) + if actual_type.diff(ctx_type) == TypeDiff::Incompatible + raise "verify_ctx: ctx type (#{ctx_type.type.inspect}) is incompatible with actual type (#{actual_type.type.inspect})" + end + end + + def assert(cond) + unless cond + raise "'#{cond.inspect}' was not true" + end + end + + def supported_platform? + return @supported_platform if defined?(@supported_platform) + @supported_platform = RUBY_PLATFORM.match?(/x86_64/).tap do |supported| + warn "warning: RJIT does not support #{RUBY_PLATFORM} yet" unless supported + end + end + end +end diff --git a/lib/ruby_vm/rjit/context.rb b/lib/ruby_vm/rjit/context.rb new file mode 100644 index 0000000000..a2a7ecc6dc --- /dev/null +++ b/lib/ruby_vm/rjit/context.rb @@ -0,0 +1,377 @@ +module RubyVM::RJIT + # Maximum number of temp value types we keep track of + MAX_TEMP_TYPES = 8 + # Maximum number of local variable types we keep track of + MAX_LOCAL_TYPES = 8 + + # Operand to a YARV bytecode instruction + SelfOpnd = :SelfOpnd # The value is self + StackOpnd = Data.define(:index) # Temporary stack operand with stack index + + # Potential mapping of a value on the temporary stack to self, + # a local variable, or constant so that we can track its type + MapToStack = :MapToStack # Normal stack value + MapToSelf = :MapToSelf # Temp maps to the self operand + MapToLocal = Data.define(:local_index) # Temp maps to a local variable with index + + class Context < Struct.new( + :stack_size, # @param [Integer] The number of values on the stack + :sp_offset, # @param [Integer] JIT sp offset relative to the interpreter's sp + :chain_depth, # @param [Integer] jit_chain_guard depth + :local_types, # @param [Array<RubyVM::RJIT::Type>] Local variable types we keep track of + :temp_types, # @param [Array<RubyVM::RJIT::Type>] Temporary variable types we keep track of + :self_type, # @param [RubyVM::RJIT::Type] Type we track for self + :temp_mapping, # @param [Array<Symbol>] Mapping of temp stack entries to types we track + ) + def initialize( + stack_size: 0, + sp_offset: 0, + chain_depth: 0, + local_types: [Type::Unknown] * MAX_LOCAL_TYPES, + temp_types: [Type::Unknown] * MAX_TEMP_TYPES, + self_type: Type::Unknown, + temp_mapping: [MapToStack] * MAX_TEMP_TYPES + ) = super + + # Deep dup by default for safety + def dup + ctx = super + ctx.local_types = ctx.local_types.dup + ctx.temp_types = ctx.temp_types.dup + ctx.temp_mapping = ctx.temp_mapping.dup + ctx + end + + # Create a new Context instance with a given stack_size and sp_offset adjusted + # accordingly. This is useful when you want to virtually rewind a stack_size for + # generating a side exit while considering past sp_offset changes on gen_save_sp. + def with_stack_size(stack_size) + ctx = self.dup + ctx.sp_offset -= ctx.stack_size - stack_size + ctx.stack_size = stack_size + ctx + end + + def stack_opnd(depth_from_top) + [SP, C.VALUE.size * (self.sp_offset - 1 - depth_from_top)] + end + + def sp_opnd(offset_bytes = 0) + [SP, (C.VALUE.size * self.sp_offset) + offset_bytes] + end + + # Push one new value on the temp stack with an explicit mapping + # Return a pointer to the new stack top + def stack_push_mapping(mapping_temp_type) + stack_size = self.stack_size + + # Keep track of the type and mapping of the value + if stack_size < MAX_TEMP_TYPES + mapping, temp_type = mapping_temp_type + self.temp_mapping[stack_size] = mapping + self.temp_types[stack_size] = temp_type + + case mapping + in MapToLocal[idx] + assert(idx < MAX_LOCAL_TYPES) + else + end + end + + self.stack_size += 1 + self.sp_offset += 1 + + return self.stack_opnd(0) + end + + # Push one new value on the temp stack + # Return a pointer to the new stack top + def stack_push(val_type) + return self.stack_push_mapping([MapToStack, val_type]) + end + + # Push the self value on the stack + def stack_push_self + return self.stack_push_mapping([MapToStack, Type::Unknown]) + end + + # Push a local variable on the stack + def stack_push_local(local_idx) + if local_idx >= MAX_LOCAL_TYPES + return self.stack_push(Type::Unknown) + end + + return self.stack_push_mapping([MapToLocal[local_idx], Type::Unknown]) + end + + # Pop N values off the stack + # Return a pointer to the stack top before the pop operation + def stack_pop(n = 1) + assert(n <= self.stack_size) + + top = self.stack_opnd(0) + + # Clear the types of the popped values + n.times do |i| + idx = self.stack_size - i - 1 + + if idx < MAX_TEMP_TYPES + self.temp_types[idx] = Type::Unknown + self.temp_mapping[idx] = MapToStack + end + end + + self.stack_size -= n + self.sp_offset -= n + + return top + end + + def shift_stack(argc) + assert(argc < self.stack_size) + + method_name_index = self.stack_size - argc - 1 + + (method_name_index...(self.stack_size - 1)).each do |i| + if i + 1 < MAX_TEMP_TYPES + self.temp_types[i] = self.temp_types[i + 1] + self.temp_mapping[i] = self.temp_mapping[i + 1] + end + end + self.stack_pop(1) + end + + # Get the type of an instruction operand + def get_opnd_type(opnd) + case opnd + in SelfOpnd + self.self_type + in StackOpnd[idx] + assert(idx < self.stack_size) + stack_idx = self.stack_size - 1 - idx + + # If outside of tracked range, do nothing + if stack_idx >= MAX_TEMP_TYPES + return Type::Unknown + end + + mapping = self.temp_mapping[stack_idx] + + case mapping + in MapToSelf + self.self_type + in MapToStack + self.temp_types[self.stack_size - 1 - idx] + in MapToLocal[idx] + assert(idx < MAX_LOCAL_TYPES) + self.local_types[idx] + end + end + end + + # Get the currently tracked type for a local variable + def get_local_type(idx) + self.local_types[idx] || Type::Unknown + end + + # Upgrade (or "learn") the type of an instruction operand + # This value must be compatible and at least as specific as the previously known type. + # If this value originated from self, or an lvar, the learned type will be + # propagated back to its source. + def upgrade_opnd_type(opnd, opnd_type) + case opnd + in SelfOpnd + self.self_type = self.self_type.upgrade(opnd_type) + in StackOpnd[idx] + assert(idx < self.stack_size) + stack_idx = self.stack_size - 1 - idx + + # If outside of tracked range, do nothing + if stack_idx >= MAX_TEMP_TYPES + return + end + + mapping = self.temp_mapping[stack_idx] + + case mapping + in MapToSelf + self.self_type = self.self_type.upgrade(opnd_type) + in MapToStack + self.temp_types[stack_idx] = self.temp_types[stack_idx].upgrade(opnd_type) + in MapToLocal[idx] + assert(idx < MAX_LOCAL_TYPES) + self.local_types[idx] = self.local_types[idx].upgrade(opnd_type) + end + end + end + + # Get both the type and mapping (where the value originates) of an operand. + # This is can be used with stack_push_mapping or set_opnd_mapping to copy + # a stack value's type while maintaining the mapping. + def get_opnd_mapping(opnd) + opnd_type = self.get_opnd_type(opnd) + + case opnd + in SelfOpnd + return [MapToSelf, opnd_type] + in StackOpnd[idx] + assert(idx < self.stack_size) + stack_idx = self.stack_size - 1 - idx + + if stack_idx < MAX_TEMP_TYPES + return [self.temp_mapping[stack_idx], opnd_type] + else + # We can't know the source of this stack operand, so we assume it is + # a stack-only temporary. type will be UNKNOWN + assert(opnd_type == Type::Unknown) + return [MapToStack, opnd_type] + end + end + end + + # Overwrite both the type and mapping of a stack operand. + def set_opnd_mapping(opnd, mapping_opnd_type) + case opnd + in SelfOpnd + raise 'self always maps to self' + in StackOpnd[idx] + assert(idx < self.stack_size) + stack_idx = self.stack_size - 1 - idx + + # If outside of tracked range, do nothing + if stack_idx >= MAX_TEMP_TYPES + return + end + + mapping, opnd_type = mapping_opnd_type + self.temp_mapping[stack_idx] = mapping + + # Only used when mapping == MAP_STACK + self.temp_types[stack_idx] = opnd_type + end + end + + # Set the type of a local variable + def set_local_type(local_idx, local_type) + if local_idx >= MAX_LOCAL_TYPES + return + end + + # If any values on the stack map to this local we must detach them + MAX_TEMP_TYPES.times do |stack_idx| + case self.temp_mapping[stack_idx] + in MapToStack + # noop + in MapToSelf + # noop + in MapToLocal[idx] + if idx == local_idx + self.temp_types[stack_idx] = self.local_types[idx] + self.temp_mapping[stack_idx] = MapToStack + else + # noop + end + end + end + + self.local_types[local_idx] = local_type + end + + # Erase local variable type information + # eg: because of a call we can't track + def clear_local_types + # When clearing local types we must detach any stack mappings to those + # locals. Even if local values may have changed, stack values will not. + MAX_TEMP_TYPES.times do |stack_idx| + case self.temp_mapping[stack_idx] + in MapToStack + # noop + in MapToSelf + # noop + in MapToLocal[local_idx] + self.temp_types[stack_idx] = self.local_types[local_idx] + self.temp_mapping[stack_idx] = MapToStack + end + end + + # Clear the local types + self.local_types = [Type::Unknown] * MAX_LOCAL_TYPES + end + + # Compute a difference score for two context objects + def diff(dst) + # Self is the source context (at the end of the predecessor) + src = self + + # Can only lookup the first version in the chain + if dst.chain_depth != 0 + return TypeDiff::Incompatible + end + + # Blocks with depth > 0 always produce new versions + # Sidechains cannot overlap + if src.chain_depth != 0 + return TypeDiff::Incompatible + end + + if dst.stack_size != src.stack_size + return TypeDiff::Incompatible + end + + if dst.sp_offset != src.sp_offset + return TypeDiff::Incompatible + end + + # Difference sum + diff = 0 + + # Check the type of self + diff += case src.self_type.diff(dst.self_type) + in TypeDiff::Compatible[diff] then diff + in TypeDiff::Incompatible then return TypeDiff::Incompatible + end + + # For each local type we track + src.local_types.size.times do |i| + t_src = src.local_types[i] + t_dst = dst.local_types[i] + diff += case t_src.diff(t_dst) + in TypeDiff::Compatible[diff] then diff + in TypeDiff::Incompatible then return TypeDiff::Incompatible + end + end + + # For each value on the temp stack + src.stack_size.times do |i| + src_mapping, src_type = src.get_opnd_mapping(StackOpnd[i]) + dst_mapping, dst_type = dst.get_opnd_mapping(StackOpnd[i]) + + # If the two mappings aren't the same + if src_mapping != dst_mapping + if dst_mapping == MapToStack + # We can safely drop information about the source of the temp + # stack operand. + diff += 1 + else + return TypeDiff::Incompatible + end + end + + diff += case src_type.diff(dst_type) + in TypeDiff::Compatible[diff] then diff + in TypeDiff::Incompatible then return TypeDiff::Incompatible + end + end + + return TypeDiff::Compatible[diff] + end + + private + + def assert(cond) + unless cond + raise "'#{cond.inspect}' was not true" + end + end + end +end diff --git a/lib/ruby_vm/rjit/entry_stub.rb b/lib/ruby_vm/rjit/entry_stub.rb new file mode 100644 index 0000000000..9bcef14053 --- /dev/null +++ b/lib/ruby_vm/rjit/entry_stub.rb @@ -0,0 +1,7 @@ +module RubyVM::RJIT + class EntryStub < Struct.new( + :start_addr, # @param [Integer] Stub source start address to be re-generated + :end_addr, # @param [Integer] Stub source end address to be re-generated + ) + end +end diff --git a/lib/ruby_vm/rjit/exit_compiler.rb b/lib/ruby_vm/rjit/exit_compiler.rb new file mode 100644 index 0000000000..1ced2141a4 --- /dev/null +++ b/lib/ruby_vm/rjit/exit_compiler.rb @@ -0,0 +1,164 @@ +module RubyVM::RJIT + class ExitCompiler + def initialize = freeze + + # Used for invalidating a block on entry. + # @param pc [Integer] + # @param asm [RubyVM::RJIT::Assembler] + def compile_entry_exit(pc, ctx, asm, cause:) + # Fix pc/sp offsets for the interpreter + save_pc_and_sp(pc, ctx, asm, reset_sp_offset: false) + + # Increment per-insn exit counter + count_insn_exit(pc, asm) + + # Restore callee-saved registers + asm.comment("#{cause}: entry exit") + asm.pop(SP) + asm.pop(EC) + asm.pop(CFP) + + asm.mov(C_RET, Qundef) + asm.ret + end + + # Set to cfp->jit_return by default for leave insn + # @param asm [RubyVM::RJIT::Assembler] + def compile_leave_exit(asm) + asm.comment('default cfp->jit_return') + + # Restore callee-saved registers + asm.pop(SP) + asm.pop(EC) + asm.pop(CFP) + + # :rax is written by #leave + asm.ret + end + + # Fire cfunc events on invalidation by TracePoint + # @param asm [RubyVM::RJIT::Assembler] + def compile_full_cfunc_return(asm) + # This chunk of code expects REG_EC to be filled properly and + # RAX to contain the return value of the C method. + + asm.comment('full cfunc return') + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], :rax) + asm.call(C.rjit_full_cfunc_return) + + # TODO: count the exit + + # Restore callee-saved registers + asm.pop(SP) + asm.pop(EC) + asm.pop(CFP) + + asm.mov(C_RET, Qundef) + asm.ret + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def compile_side_exit(pc, ctx, asm) + # Fix pc/sp offsets for the interpreter + save_pc_and_sp(pc, ctx.dup, asm) # dup to avoid sp_offset update + + # Increment per-insn exit counter + count_insn_exit(pc, asm) + + # Restore callee-saved registers + asm.comment("exit to interpreter on #{pc_to_insn(pc).name}") + asm.pop(SP) + asm.pop(EC) + asm.pop(CFP) + + asm.mov(C_RET, Qundef) + asm.ret + end + + # @param asm [RubyVM::RJIT::Assembler] + # @param entry_stub [RubyVM::RJIT::EntryStub] + def compile_entry_stub(asm, entry_stub) + # Call rb_rjit_entry_stub_hit + asm.comment('entry stub hit') + asm.mov(C_ARGS[0], to_value(entry_stub)) + asm.call(C.rb_rjit_entry_stub_hit) + + # Jump to the address returned by rb_rjit_entry_stub_hit + asm.jmp(:rax) + end + + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + # @param branch_stub [RubyVM::RJIT::BranchStub] + # @param target0_p [TrueClass,FalseClass] + def compile_branch_stub(ctx, asm, branch_stub, target0_p) + # Call rb_rjit_branch_stub_hit + iseq = branch_stub.iseq + if C.rjit_opts.dump_disasm && C.imemo_type_p(iseq, C.imemo_iseq) # Guard against ISEQ GC at random moments + asm.comment("branch stub hit: #{iseq.body.location.label}@#{C.rb_iseq_path(iseq)}:#{iseq_lineno(iseq, target0_p ? branch_stub.target0.pc : branch_stub.target1.pc)}") + end + asm.mov(:rdi, to_value(branch_stub)) + asm.mov(:esi, ctx.sp_offset) + asm.mov(:edx, target0_p ? 1 : 0) + asm.call(C.rb_rjit_branch_stub_hit) + + # Jump to the address returned by rb_rjit_branch_stub_hit + asm.jmp(:rax) + end + + private + + def pc_to_insn(pc) + Compiler.decode_insn(C.VALUE.new(pc).*) + end + + # @param pc [Integer] + # @param asm [RubyVM::RJIT::Assembler] + def count_insn_exit(pc, asm) + if C.rjit_opts.stats + insn = Compiler.decode_insn(C.VALUE.new(pc).*) + asm.comment("increment insn exit: #{insn.name}") + asm.mov(:rax, (C.rjit_insn_exits + insn.bin).to_i) + asm.add([:rax], 1) # TODO: lock + end + if C.rjit_opts.trace_exits + asm.comment('rjit_record_exit_stack') + asm.mov(C_ARGS[0], pc) + asm.call(C.rjit_record_exit_stack) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def save_pc_and_sp(pc, ctx, asm, reset_sp_offset: true) + # Update pc (TODO: manage PC offset?) + asm.comment("save PC#{' and SP' if ctx.sp_offset != 0} to CFP") + asm.mov(:rax, pc) # rax = jit.pc + asm.mov([CFP, C.rb_control_frame_t.offsetof(:pc)], :rax) # cfp->pc = rax + + # Update sp + if ctx.sp_offset != 0 + asm.add(SP, C.VALUE.size * ctx.sp_offset) # sp += stack_size + asm.mov([CFP, C.rb_control_frame_t.offsetof(:sp)], SP) # cfp->sp = sp + if reset_sp_offset + ctx.sp_offset = 0 + end + end + end + + def to_value(obj) + GC_REFS << obj + C.to_value(obj) + end + + def iseq_lineno(iseq, pc) + C.rb_iseq_line_no(iseq, (pc - iseq.body.iseq_encoded.to_i) / C.VALUE.size) + rescue RangeError # bignum too big to convert into `unsigned long long' (RangeError) + -1 + end + end +end diff --git a/lib/ruby_vm/rjit/hooks.rb b/lib/ruby_vm/rjit/hooks.rb new file mode 100644 index 0000000000..ea9d7bf5a8 --- /dev/null +++ b/lib/ruby_vm/rjit/hooks.rb @@ -0,0 +1,36 @@ +module RubyVM::RJIT + module Hooks # :nodoc: all + def self.on_bop_redefined(_redefined_flag, _bop) + # C.rjit_cancel_all("BOP is redefined") + end + + def self.on_cme_invalidate(cme) + cme = C.rb_callable_method_entry_struct.new(cme) + Invariants.on_cme_invalidate(cme) + end + + def self.on_ractor_spawn + # C.rjit_cancel_all("Ractor is spawned") + end + + # Global constant changes like const_set + def self.on_constant_state_changed(id) + Invariants.on_constant_state_changed(id) + end + + # ISEQ-specific constant invalidation + def self.on_constant_ic_update(iseq, ic, insn_idx) + iseq = C.rb_iseq_t.new(iseq) + ic = C.IC.new(ic) + Invariants.on_constant_ic_update(iseq, ic, insn_idx) + end + + def self.on_tracing_invalidate_all(_new_iseq_events) + Invariants.on_tracing_invalidate_all + end + + def self.on_update_references + Invariants.on_update_references + end + end +end diff --git a/lib/ruby_vm/rjit/insn_compiler.rb b/lib/ruby_vm/rjit/insn_compiler.rb new file mode 100644 index 0000000000..f9450241c9 --- /dev/null +++ b/lib/ruby_vm/rjit/insn_compiler.rb @@ -0,0 +1,6002 @@ +# frozen_string_literal: true +module RubyVM::RJIT + class InsnCompiler + # struct rb_calling_info. Storing flags instead of ci. + CallingInfo = Struct.new(:argc, :flags, :kwarg, :ci_addr, :send_shift, :block_handler) do + def kw_splat = flags & C::VM_CALL_KW_SPLAT != 0 + end + + # @param ocb [CodeBlock] + # @param exit_compiler [RubyVM::RJIT::ExitCompiler] + def initialize(cb, ocb, exit_compiler) + @ocb = ocb + @exit_compiler = exit_compiler + + @cfunc_codegen_table = {} + register_cfunc_codegen_funcs + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + # @param insn `RubyVM::RJIT::Instruction` + def compile(jit, ctx, asm, insn) + asm.incr_counter(:rjit_insns_count) + + stack = ctx.stack_size.times.map do |stack_idx| + ctx.get_opnd_type(StackOpnd[ctx.stack_size - stack_idx - 1]).type + end + locals = jit.iseq.body.local_table_size.times.map do |local_idx| + (ctx.local_types[local_idx] || Type::Unknown).type + end + + insn_idx = format('%04d', (jit.pc.to_i - jit.iseq.body.iseq_encoded.to_i) / C.VALUE.size) + asm.comment("Insn: #{insn_idx} #{insn.name} (stack: [#{stack.join(', ')}], locals: [#{locals.join(', ')}])") + + # 83/102 + case insn.name + when :nop then nop(jit, ctx, asm) + when :getlocal then getlocal(jit, ctx, asm) + when :setlocal then setlocal(jit, ctx, asm) + when :getblockparam then getblockparam(jit, ctx, asm) + # setblockparam + when :getblockparamproxy then getblockparamproxy(jit, ctx, asm) + when :getspecial then getspecial(jit, ctx, asm) + # setspecial + when :getinstancevariable then getinstancevariable(jit, ctx, asm) + when :setinstancevariable then setinstancevariable(jit, ctx, asm) + when :getclassvariable then getclassvariable(jit, ctx, asm) + when :setclassvariable then setclassvariable(jit, ctx, asm) + when :opt_getconstant_path then opt_getconstant_path(jit, ctx, asm) + when :getconstant then getconstant(jit, ctx, asm) + # setconstant + when :getglobal then getglobal(jit, ctx, asm) + # setglobal + when :putnil then putnil(jit, ctx, asm) + when :putself then putself(jit, ctx, asm) + when :putobject then putobject(jit, ctx, asm) + when :putspecialobject then putspecialobject(jit, ctx, asm) + when :putstring then putstring(jit, ctx, asm) + when :putchilledstring then putchilledstring(jit, ctx, asm) + when :concatstrings then concatstrings(jit, ctx, asm) + when :anytostring then anytostring(jit, ctx, asm) + when :toregexp then toregexp(jit, ctx, asm) + when :intern then intern(jit, ctx, asm) + when :newarray then newarray(jit, ctx, asm) + # newarraykwsplat + when :duparray then duparray(jit, ctx, asm) + # duphash + when :expandarray then expandarray(jit, ctx, asm) + when :concatarray then concatarray(jit, ctx, asm) + when :splatarray then splatarray(jit, ctx, asm) + when :newhash then newhash(jit, ctx, asm) + when :newrange then newrange(jit, ctx, asm) + when :pop then pop(jit, ctx, asm) + when :dup then dup(jit, ctx, asm) + when :dupn then dupn(jit, ctx, asm) + when :swap then swap(jit, ctx, asm) + # opt_reverse + when :topn then topn(jit, ctx, asm) + when :setn then setn(jit, ctx, asm) + when :adjuststack then adjuststack(jit, ctx, asm) + when :defined then defined(jit, ctx, asm) + when :definedivar then definedivar(jit, ctx, asm) + # checkmatch + when :checkkeyword then checkkeyword(jit, ctx, asm) + # checktype + # defineclass + # definemethod + # definesmethod + when :send then send(jit, ctx, asm) + when :opt_send_without_block then opt_send_without_block(jit, ctx, asm) + when :objtostring then objtostring(jit, ctx, asm) + when :opt_str_freeze then opt_str_freeze(jit, ctx, asm) + when :opt_nil_p then opt_nil_p(jit, ctx, asm) + # opt_str_uminus + when :opt_newarray_send then opt_newarray_send(jit, ctx, asm) + when :invokesuper then invokesuper(jit, ctx, asm) + when :invokeblock then invokeblock(jit, ctx, asm) + when :leave then leave(jit, ctx, asm) + when :throw then throw(jit, ctx, asm) + when :jump then jump(jit, ctx, asm) + when :branchif then branchif(jit, ctx, asm) + when :branchunless then branchunless(jit, ctx, asm) + when :branchnil then branchnil(jit, ctx, asm) + # once + when :opt_case_dispatch then opt_case_dispatch(jit, ctx, asm) + when :opt_plus then opt_plus(jit, ctx, asm) + when :opt_minus then opt_minus(jit, ctx, asm) + when :opt_mult then opt_mult(jit, ctx, asm) + when :opt_div then opt_div(jit, ctx, asm) + when :opt_mod then opt_mod(jit, ctx, asm) + when :opt_eq then opt_eq(jit, ctx, asm) + when :opt_neq then opt_neq(jit, ctx, asm) + when :opt_lt then opt_lt(jit, ctx, asm) + when :opt_le then opt_le(jit, ctx, asm) + when :opt_gt then opt_gt(jit, ctx, asm) + when :opt_ge then opt_ge(jit, ctx, asm) + when :opt_ltlt then opt_ltlt(jit, ctx, asm) + when :opt_and then opt_and(jit, ctx, asm) + when :opt_or then opt_or(jit, ctx, asm) + when :opt_aref then opt_aref(jit, ctx, asm) + when :opt_aset then opt_aset(jit, ctx, asm) + # opt_aset_with + # opt_aref_with + when :opt_length then opt_length(jit, ctx, asm) + when :opt_size then opt_size(jit, ctx, asm) + when :opt_empty_p then opt_empty_p(jit, ctx, asm) + when :opt_succ then opt_succ(jit, ctx, asm) + when :opt_not then opt_not(jit, ctx, asm) + when :opt_regexpmatch2 then opt_regexpmatch2(jit, ctx, asm) + # invokebuiltin + when :opt_invokebuiltin_delegate then opt_invokebuiltin_delegate(jit, ctx, asm) + when :opt_invokebuiltin_delegate_leave then opt_invokebuiltin_delegate_leave(jit, ctx, asm) + when :getlocal_WC_0 then getlocal_WC_0(jit, ctx, asm) + when :getlocal_WC_1 then getlocal_WC_1(jit, ctx, asm) + when :setlocal_WC_0 then setlocal_WC_0(jit, ctx, asm) + when :setlocal_WC_1 then setlocal_WC_1(jit, ctx, asm) + when :putobject_INT2FIX_0_ then putobject_INT2FIX_0_(jit, ctx, asm) + when :putobject_INT2FIX_1_ then putobject_INT2FIX_1_(jit, ctx, asm) + else CantCompile + end + end + + private + + # + # Insns + # + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def nop(jit, ctx, asm) + # Do nothing + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getlocal(jit, ctx, asm) + idx = jit.operand(0) + level = jit.operand(1) + jit_getlocal_generic(jit, ctx, asm, idx:, level:) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getlocal_WC_0(jit, ctx, asm) + idx = jit.operand(0) + jit_getlocal_generic(jit, ctx, asm, idx:, level: 0) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getlocal_WC_1(jit, ctx, asm) + idx = jit.operand(0) + jit_getlocal_generic(jit, ctx, asm, idx:, level: 1) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def setlocal(jit, ctx, asm) + idx = jit.operand(0) + level = jit.operand(1) + jit_setlocal_generic(jit, ctx, asm, idx:, level:) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def setlocal_WC_0(jit, ctx, asm) + idx = jit.operand(0) + jit_setlocal_generic(jit, ctx, asm, idx:, level: 0) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def setlocal_WC_1(jit, ctx, asm) + idx = jit.operand(0) + jit_setlocal_generic(jit, ctx, asm, idx:, level: 1) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getblockparam(jit, ctx, asm) + # EP level + level = jit.operand(1) + + # Save the PC and SP because we might allocate + jit_prepare_routine_call(jit, ctx, asm) + + # A mirror of the interpreter code. Checking for the case + # where it's pushing rb_block_param_proxy. + side_exit = side_exit(jit, ctx) + + # Load environment pointer EP from CFP + ep_reg = :rax + jit_get_ep(asm, level, reg: ep_reg) + + # Bail when VM_ENV_FLAGS(ep, VM_FRAME_FLAG_MODIFIED_BLOCK_PARAM) is non zero + # FIXME: This is testing bits in the same place that the WB check is testing. + # We should combine these at some point + asm.test([ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_FLAGS], C::VM_FRAME_FLAG_MODIFIED_BLOCK_PARAM) + + # If the frame flag has been modified, then the actual proc value is + # already in the EP and we should just use the value. + frame_flag_modified = asm.new_label('frame_flag_modified') + asm.jnz(frame_flag_modified) + + # This instruction writes the block handler to the EP. If we need to + # fire a write barrier for the write, then exit (we'll let the + # interpreter handle it so it can fire the write barrier). + # flags & VM_ENV_FLAG_WB_REQUIRED + asm.test([ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_FLAGS], C::VM_ENV_FLAG_WB_REQUIRED) + + # if (flags & VM_ENV_FLAG_WB_REQUIRED) != 0 + asm.jnz(side_exit) + + # Convert the block handler in to a proc + # call rb_vm_bh_to_procval(const rb_execution_context_t *ec, VALUE block_handler) + asm.mov(C_ARGS[0], EC) + # The block handler for the current frame + # note, VM_ASSERT(VM_ENV_LOCAL_P(ep)) + asm.mov(C_ARGS[1], [ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) + asm.call(C.rb_vm_bh_to_procval) + + # Load environment pointer EP from CFP (again) + ep_reg = :rcx + jit_get_ep(asm, level, reg: ep_reg) + + # Write the value at the environment pointer + idx = jit.operand(0) + offs = -(C.VALUE.size * idx) + asm.mov([ep_reg, offs], C_RET); + + # Set the frame modified flag + asm.mov(:rax, [ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_FLAGS]) # flag_check + asm.or(:rax, C::VM_FRAME_FLAG_MODIFIED_BLOCK_PARAM) # modified_flag + asm.mov([ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_FLAGS], :rax) + + asm.write_label(frame_flag_modified) + + # Push the proc on the stack + stack_ret = ctx.stack_push(Type::Unknown) + ep_reg = :rax + jit_get_ep(asm, level, reg: ep_reg) + asm.mov(:rax, [ep_reg, offs]) + asm.mov(stack_ret, :rax) + + KeepCompiling + end + + # setblockparam + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getblockparamproxy(jit, ctx, asm) + # To get block_handler + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + starting_context = ctx.dup # make a copy for use with jit_chain_guard + + # A mirror of the interpreter code. Checking for the case + # where it's pushing rb_block_param_proxy. + side_exit = side_exit(jit, ctx) + + # EP level + level = jit.operand(1) + + # Peek at the block handler so we can check whether it's nil + comptime_handler = jit.peek_at_block_handler(level) + + # When a block handler is present, it should always be a GC-guarded + # pointer (VM_BH_ISEQ_BLOCK_P) + if comptime_handler != 0 && comptime_handler & 0x3 != 0x1 + asm.incr_counter(:getblockpp_not_gc_guarded) + return CantCompile + end + + # Load environment pointer EP from CFP + ep_reg = :rax + jit_get_ep(asm, level, reg: ep_reg) + + # Bail when VM_ENV_FLAGS(ep, VM_FRAME_FLAG_MODIFIED_BLOCK_PARAM) is non zero + asm.test([ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_FLAGS], C::VM_FRAME_FLAG_MODIFIED_BLOCK_PARAM) + asm.jnz(counted_exit(side_exit, :getblockpp_block_param_modified)) + + # Load the block handler for the current frame + # note, VM_ASSERT(VM_ENV_LOCAL_P(ep)) + block_handler = :rax + asm.mov(block_handler, [ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) + + # Specialize compilation for the case where no block handler is present + if comptime_handler == 0 + # Bail if there is a block handler + asm.cmp(block_handler, 0) + + jit_chain_guard(:jnz, jit, starting_context, asm, counted_exit(side_exit, :getblockpp_block_handler_none)) + + putobject(jit, ctx, asm, val: Qnil) + else + # Block handler is a tagged pointer. Look at the tag. 0x03 is from VM_BH_ISEQ_BLOCK_P(). + asm.and(block_handler, 0x3) + + # Bail unless VM_BH_ISEQ_BLOCK_P(bh). This also checks for null. + asm.cmp(block_handler, 0x1) + + jit_chain_guard(:jnz, jit, starting_context, asm, counted_exit(side_exit, :getblockpp_not_iseq_block)) + + # Push rb_block_param_proxy. It's a root, so no need to use jit_mov_gc_ptr. + top = ctx.stack_push(Type::BlockParamProxy) + asm.mov(:rax, C.rb_block_param_proxy) + asm.mov(top, :rax) + end + + jump_to_next_insn(jit, ctx, asm) + + EndBlock + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getspecial(jit, ctx, asm) + # This takes two arguments, key and type + # key is only used when type == 0 + # A non-zero type determines which type of backref to fetch + #rb_num_t key = jit.jit_get_arg(0); + rtype = jit.operand(1) + + if rtype == 0 + # not yet implemented + return CantCompile; + elsif rtype & 0x01 != 0 + # Fetch a "special" backref based on a char encoded by shifting by 1 + + # Can raise if matchdata uninitialized + jit_prepare_routine_call(jit, ctx, asm) + + # call rb_backref_get() + asm.comment('rb_backref_get') + asm.call(C.rb_backref_get) + + asm.mov(C_ARGS[0], C_RET) # backref + case [rtype >> 1].pack('c') + in ?& + asm.comment("rb_reg_last_match") + asm.call(C.rb_reg_last_match) + in ?` + asm.comment("rb_reg_match_pre") + asm.call(C.rb_reg_match_pre) + in ?' + asm.comment("rb_reg_match_post") + asm.call(C.rb_reg_match_post) + in ?+ + asm.comment("rb_reg_match_last") + asm.call(C.rb_reg_match_last) + end + + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + KeepCompiling + else + # Fetch the N-th match from the last backref based on type shifted by 1 + + # Can raise if matchdata uninitialized + jit_prepare_routine_call(jit, ctx, asm) + + # call rb_backref_get() + asm.comment('rb_backref_get') + asm.call(C.rb_backref_get) + + # rb_reg_nth_match((int)(type >> 1), backref); + asm.comment('rb_reg_nth_match') + asm.mov(C_ARGS[0], rtype >> 1) + asm.mov(C_ARGS[1], C_RET) # backref + asm.call(C.rb_reg_nth_match) + + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + end + + # setspecial + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getinstancevariable(jit, ctx, asm) + # Specialize on a compile-time receiver, and split a block for chain guards + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + id = jit.operand(0) + comptime_obj = jit.peek_at_self + + jit_getivar(jit, ctx, asm, comptime_obj, id, nil, SelfOpnd) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def setinstancevariable(jit, ctx, asm) + starting_context = ctx.dup # make a copy for use with jit_chain_guard + + # Defer compilation so we can specialize on a runtime `self` + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + ivar_name = jit.operand(0) + comptime_receiver = jit.peek_at_self + + # If the comptime receiver is frozen, writing an IV will raise an exception + # and we don't want to JIT code to deal with that situation. + if C.rb_obj_frozen_p(comptime_receiver) + asm.incr_counter(:setivar_frozen) + return CantCompile + end + + # Check if the comptime receiver is a T_OBJECT + receiver_t_object = C::BUILTIN_TYPE(comptime_receiver) == C::T_OBJECT + + # If the receiver isn't a T_OBJECT, or uses a custom allocator, + # then just write out the IV write as a function call. + # too-complex shapes can't use index access, so we use rb_ivar_get for them too. + if !receiver_t_object || shape_too_complex?(comptime_receiver) || ctx.chain_depth >= 10 + asm.comment('call rb_vm_setinstancevariable') + + ic = jit.operand(1) + + # The function could raise exceptions. + # Note that this modifies REG_SP, which is why we do it first + jit_prepare_routine_call(jit, ctx, asm) + + # Get the operands from the stack + val_opnd = ctx.stack_pop(1) + + # Call rb_vm_setinstancevariable(iseq, obj, id, val, ic); + asm.mov(:rdi, jit.iseq.to_i) + asm.mov(:rsi, [CFP, C.rb_control_frame_t.offsetof(:self)]) + asm.mov(:rdx, ivar_name) + asm.mov(:rcx, val_opnd) + asm.mov(:r8, ic) + asm.call(C.rb_vm_setinstancevariable) + else + # Get the iv index + shape_id = C.rb_shape_get_shape_id(comptime_receiver) + ivar_index = C.rb_shape_get_iv_index(shape_id, ivar_name) + + # Get the receiver + asm.mov(:rax, [CFP, C.rb_control_frame_t.offsetof(:self)]) + + # Generate a side exit + side_exit = side_exit(jit, ctx) + + # Upgrade type + guard_object_is_heap(jit, ctx, asm, :rax, SelfOpnd, :setivar_not_heap) + + asm.comment('guard shape') + asm.cmp(DwordPtr[:rax, C.rb_shape_id_offset], shape_id) + megamorphic_side_exit = counted_exit(side_exit, :setivar_megamorphic) + jit_chain_guard(:jne, jit, starting_context, asm, megamorphic_side_exit) + + # If we don't have an instance variable index, then we need to + # transition out of the current shape. + if ivar_index.nil? + shape = C.rb_shape_get_shape_by_id(shape_id) + + current_capacity = shape.capacity + dest_shape = C.rb_shape_get_next(shape, comptime_receiver, ivar_name) + new_shape_id = C.rb_shape_id(dest_shape) + + if new_shape_id == C::OBJ_TOO_COMPLEX_SHAPE_ID + asm.incr_counter(:setivar_too_complex) + return CantCompile + end + + ivar_index = shape.next_iv_index + + # If the new shape has a different capacity, we need to + # reallocate the object. + needs_extension = dest_shape.capacity != shape.capacity + + if needs_extension + # Generate the C call so that runtime code will increase + # the capacity and set the buffer. + asm.mov(C_ARGS[0], :rax) + asm.mov(C_ARGS[1], current_capacity) + asm.mov(C_ARGS[2], dest_shape.capacity) + asm.call(C.rb_ensure_iv_list_size) + + # Load the receiver again after the function call + asm.mov(:rax, [CFP, C.rb_control_frame_t.offsetof(:self)]) + end + + write_val = ctx.stack_pop(1) + jit_write_iv(asm, comptime_receiver, :rax, :rcx, ivar_index, write_val, needs_extension) + + # Store the new shape + asm.comment('write shape') + asm.mov(:rax, [CFP, C.rb_control_frame_t.offsetof(:self)]) # reload after jit_write_iv + asm.mov(DwordPtr[:rax, C.rb_shape_id_offset], new_shape_id) + else + # If the iv index already exists, then we don't need to + # transition to a new shape. The reason is because we find + # the iv index by searching up the shape tree. If we've + # made the transition already, then there's no reason to + # update the shape on the object. Just set the IV. + write_val = ctx.stack_pop(1) + jit_write_iv(asm, comptime_receiver, :rax, :rcx, ivar_index, write_val, false) + end + + skip_wb = asm.new_label('skip_wb') + # If the value we're writing is an immediate, we don't need to WB + asm.test(write_val, C::RUBY_IMMEDIATE_MASK) + asm.jnz(skip_wb) + + # If the value we're writing is nil or false, we don't need to WB + asm.cmp(write_val, Qnil) + asm.jbe(skip_wb) + + asm.comment('write barrier') + asm.mov(C_ARGS[0], [CFP, C.rb_control_frame_t.offsetof(:self)]) # reload after jit_write_iv + asm.mov(C_ARGS[1], write_val) + asm.call(C.rb_gc_writebarrier) + + asm.write_label(skip_wb) + end + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getclassvariable(jit, ctx, asm) + # rb_vm_getclassvariable can raise exceptions. + jit_prepare_routine_call(jit, ctx, asm) + + asm.mov(C_ARGS[0], [CFP, C.rb_control_frame_t.offsetof(:iseq)]) + asm.mov(C_ARGS[1], CFP) + asm.mov(C_ARGS[2], jit.operand(0)) + asm.mov(C_ARGS[3], jit.operand(1)) + asm.call(C.rb_vm_getclassvariable) + + top = ctx.stack_push(Type::Unknown) + asm.mov(top, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def setclassvariable(jit, ctx, asm) + # rb_vm_setclassvariable can raise exceptions. + jit_prepare_routine_call(jit, ctx, asm) + + asm.mov(C_ARGS[0], [CFP, C.rb_control_frame_t.offsetof(:iseq)]) + asm.mov(C_ARGS[1], CFP) + asm.mov(C_ARGS[2], jit.operand(0)) + asm.mov(C_ARGS[3], ctx.stack_pop(1)) + asm.mov(C_ARGS[4], jit.operand(1)) + asm.call(C.rb_vm_setclassvariable) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_getconstant_path(jit, ctx, asm) + # Cut the block for invalidation + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + ic = C.iseq_inline_constant_cache.new(jit.operand(0)) + idlist = ic.segments + + # Make sure there is an exit for this block as the interpreter might want + # to invalidate this block from rb_rjit_constant_ic_update(). + # For now, we always take an entry exit even if it was a side exit. + Invariants.ensure_block_entry_exit(jit, cause: 'opt_getconstant_path') + + # See vm_ic_hit_p(). The same conditions are checked in yjit_constant_ic_update(). + ice = ic.entry + if ice.nil? + # In this case, leave a block that unconditionally side exits + # for the interpreter to invalidate. + asm.incr_counter(:optgetconst_not_cached) + return CantCompile + end + + if ice.ic_cref # with cref + # Cache is keyed on a certain lexical scope. Use the interpreter's cache. + side_exit = side_exit(jit, ctx) + + # Call function to verify the cache. It doesn't allocate or call methods. + asm.mov(C_ARGS[0], ic.to_i) + asm.mov(C_ARGS[1], [CFP, C.rb_control_frame_t.offsetof(:ep)]) + asm.call(C.rb_vm_ic_hit_p) + + # Check the result. SysV only specifies one byte for _Bool return values, + # so it's important we only check one bit to ignore the higher bits in the register. + asm.test(C_RET, 1) + asm.jz(counted_exit(side_exit, :optgetconst_cache_miss)) + + asm.mov(:rax, ic.to_i) # inline_cache + asm.mov(:rax, [:rax, C.iseq_inline_constant_cache.offsetof(:entry)]) # ic_entry + asm.mov(:rax, [:rax, C.iseq_inline_constant_cache_entry.offsetof(:value)]) # ic_entry_val + + # Push ic->entry->value + stack_top = ctx.stack_push(Type::Unknown) + asm.mov(stack_top, :rax) + else # without cref + # TODO: implement this + # Optimize for single ractor mode. + # if !assume_single_ractor_mode(jit, ocb) + # return CantCompile + # end + + # Invalidate output code on any constant writes associated with + # constants referenced within the current block. + Invariants.assume_stable_constant_names(jit, idlist) + + putobject(jit, ctx, asm, val: ice.value) + end + + jump_to_next_insn(jit, ctx, asm) + EndBlock + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getconstant(jit, ctx, asm) + id = jit.operand(0) + + # vm_get_ev_const can raise exceptions. + jit_prepare_routine_call(jit, ctx, asm) + + allow_nil_opnd = ctx.stack_pop(1) + klass_opnd = ctx.stack_pop(1) + + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], klass_opnd) + asm.mov(C_ARGS[2], id) + asm.mov(C_ARGS[3], allow_nil_opnd) + asm.call(C.rb_vm_get_ev_const) + + top = ctx.stack_push(Type::Unknown) + asm.mov(top, C_RET) + + KeepCompiling + end + + # setconstant + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def getglobal(jit, ctx, asm) + gid = jit.operand(0) + + # Save the PC and SP because we might make a Ruby call for warning + jit_prepare_routine_call(jit, ctx, asm) + + asm.mov(C_ARGS[0], gid) + asm.call(C.rb_gvar_get) + + top = ctx.stack_push(Type::Unknown) + asm.mov(top, C_RET) + + KeepCompiling + end + + # setglobal + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putnil(jit, ctx, asm) + putobject(jit, ctx, asm, val: Qnil) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putself(jit, ctx, asm) + stack_top = ctx.stack_push_self + asm.mov(:rax, [CFP, C.rb_control_frame_t.offsetof(:self)]) + asm.mov(stack_top, :rax) + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putobject(jit, ctx, asm, val: jit.operand(0)) + # Push it to the stack + val_type = Type.from(C.to_ruby(val)) + stack_top = ctx.stack_push(val_type) + if asm.imm32?(val) + asm.mov(stack_top, val) + else # 64-bit immediates can't be directly written to memory + asm.mov(:rax, val) + asm.mov(stack_top, :rax) + end + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putspecialobject(jit, ctx, asm) + object_type = jit.operand(0) + if object_type == C::VM_SPECIAL_OBJECT_VMCORE + stack_top = ctx.stack_push(Type::UnknownHeap) + asm.mov(:rax, C.rb_mRubyVMFrozenCore) + asm.mov(stack_top, :rax) + KeepCompiling + else + # TODO: implement for VM_SPECIAL_OBJECT_CBASE and + # VM_SPECIAL_OBJECT_CONST_BASE + CantCompile + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putstring(jit, ctx, asm) + put_val = jit.operand(0, ruby: true) + + # Save the PC and SP because the callee will allocate + jit_prepare_routine_call(jit, ctx, asm) + + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], to_value(put_val)) + asm.mov(C_ARGS[2], 0) + asm.call(C.rb_ec_str_resurrect) + + stack_top = ctx.stack_push(Type::TString) + asm.mov(stack_top, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putchilledstring(jit, ctx, asm) + put_val = jit.operand(0, ruby: true) + + # Save the PC and SP because the callee will allocate + jit_prepare_routine_call(jit, ctx, asm) + + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], to_value(put_val)) + asm.mov(C_ARGS[2], 1) + asm.call(C.rb_ec_str_resurrect) + + stack_top = ctx.stack_push(Type::TString) + asm.mov(stack_top, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def concatstrings(jit, ctx, asm) + n = jit.operand(0) + + # Save the PC and SP because we are allocating + jit_prepare_routine_call(jit, ctx, asm) + + asm.lea(:rax, ctx.sp_opnd(-C.VALUE.size * n)) + + # call rb_str_concat_literals(size_t n, const VALUE *strings); + asm.mov(C_ARGS[0], n) + asm.mov(C_ARGS[1], :rax) + asm.call(C.rb_str_concat_literals) + + ctx.stack_pop(n) + stack_ret = ctx.stack_push(Type::TString) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def anytostring(jit, ctx, asm) + # Save the PC and SP since we might call #to_s + jit_prepare_routine_call(jit, ctx, asm) + + str = ctx.stack_pop(1) + val = ctx.stack_pop(1) + + asm.mov(C_ARGS[0], str) + asm.mov(C_ARGS[1], val) + asm.call(C.rb_obj_as_string_result) + + # Push the return value + stack_ret = ctx.stack_push(Type::TString) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def toregexp(jit, ctx, asm) + opt = jit.operand(0, signed: true) + cnt = jit.operand(1) + + # Save the PC and SP because this allocates an object and could + # raise an exception. + jit_prepare_routine_call(jit, ctx, asm) + + asm.lea(:rax, ctx.sp_opnd(-C.VALUE.size * cnt)) # values_ptr + ctx.stack_pop(cnt) + + asm.mov(C_ARGS[0], 0) + asm.mov(C_ARGS[1], cnt) + asm.mov(C_ARGS[2], :rax) # values_ptr + asm.call(C.rb_ary_tmp_new_from_values) + + # Save the array so we can clear it later + asm.push(C_RET) + asm.push(C_RET) # Alignment + + asm.mov(C_ARGS[0], C_RET) + asm.mov(C_ARGS[1], opt) + asm.call(C.rb_reg_new_ary) + + # The actual regex is in RAX now. Pop the temp array from + # rb_ary_tmp_new_from_values into C arg regs so we can clear it + asm.pop(:rcx) # Alignment + asm.pop(:rcx) # ary + + # The value we want to push on the stack is in RAX right now + stack_ret = ctx.stack_push(Type::UnknownHeap) + asm.mov(stack_ret, C_RET) + + # Clear the temp array. + asm.mov(C_ARGS[0], :rcx) # ary + asm.call(C.rb_ary_clear) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def intern(jit, ctx, asm) + # Save the PC and SP because we might allocate + jit_prepare_routine_call(jit, ctx, asm); + + str = ctx.stack_pop(1) + asm.mov(C_ARGS[0], str) + asm.call(C.rb_str_intern) + + # Push the return value + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def newarray(jit, ctx, asm) + n = jit.operand(0) + + # Save the PC and SP because we are allocating + jit_prepare_routine_call(jit, ctx, asm) + + # If n is 0, then elts is never going to be read, so we can just pass null + if n == 0 + values_ptr = 0 + else + asm.comment('load pointer to array elts') + offset_magnitude = C.VALUE.size * n + values_opnd = ctx.sp_opnd(-(offset_magnitude)) + asm.lea(:rax, values_opnd) + values_ptr = :rax + end + + # call rb_ec_ary_new_from_values(struct rb_execution_context_struct *ec, long n, const VALUE *elts); + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], n) + asm.mov(C_ARGS[2], values_ptr) + asm.call(C.rb_ec_ary_new_from_values) + + ctx.stack_pop(n) + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # newarraykwsplat + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def duparray(jit, ctx, asm) + ary = jit.operand(0) + + # Save the PC and SP because we are allocating + jit_prepare_routine_call(jit, ctx, asm) + + # call rb_ary_resurrect(VALUE ary); + asm.comment('call rb_ary_resurrect') + asm.mov(C_ARGS[0], ary) + asm.call(C.rb_ary_resurrect) + + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # duphash + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def expandarray(jit, ctx, asm) + # Both arguments are rb_num_t which is unsigned + num = jit.operand(0) + flag = jit.operand(1) + + # If this instruction has the splat flag, then bail out. + if flag & 0x01 != 0 + asm.incr_counter(:expandarray_splat) + return CantCompile + end + + # If this instruction has the postarg flag, then bail out. + if flag & 0x02 != 0 + asm.incr_counter(:expandarray_postarg) + return CantCompile + end + + side_exit = side_exit(jit, ctx) + + array_opnd = ctx.stack_opnd(0) + array_stack_opnd = StackOpnd[0] + + # num is the number of requested values. If there aren't enough in the + # array then we're going to push on nils. + if ctx.get_opnd_type(array_stack_opnd) == Type::Nil + ctx.stack_pop(1) # pop after using the type info + # special case for a, b = nil pattern + # push N nils onto the stack + num.times do + push_opnd = ctx.stack_push(Type::Nil) + asm.mov(push_opnd, Qnil) + end + return KeepCompiling + end + + # Move the array from the stack and check that it's an array. + asm.mov(:rax, array_opnd) + guard_object_is_array(jit, ctx, asm, :rax, :rcx, array_stack_opnd, :expandarray_not_array) + ctx.stack_pop(1) # pop after using the type info + + # If we don't actually want any values, then just return. + if num == 0 + return KeepCompiling + end + + jit_array_len(asm, :rax, :rcx) + + # Only handle the case where the number of values in the array is greater + # than or equal to the number of values requested. + asm.cmp(:rcx, num) + asm.jl(counted_exit(side_exit, :expandarray_rhs_too_small)) + + # Conditionally load the address of the heap array into REG1. + # (struct RArray *)(obj)->as.heap.ptr + #asm.mov(:rax, array_opnd) + asm.mov(:rcx, [:rax, C.RBasic.offsetof(:flags)]) + asm.test(:rcx, C::RARRAY_EMBED_FLAG); + asm.mov(:rcx, [:rax, C.RArray.offsetof(:as, :heap, :ptr)]) + + # Load the address of the embedded array into REG1. + # (struct RArray *)(obj)->as.ary + asm.lea(:rax, [:rax, C.RArray.offsetof(:as, :ary)]) + + asm.cmovnz(:rcx, :rax) + + # Loop backward through the array and push each element onto the stack. + (num - 1).downto(0).each do |i| + top = ctx.stack_push(Type::Unknown) + asm.mov(:rax, [:rcx, i * C.VALUE.size]) + asm.mov(top, :rax) + end + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def concatarray(jit, ctx, asm) + # Save the PC and SP because the callee may allocate + # Note that this modifies REG_SP, which is why we do it first + jit_prepare_routine_call(jit, ctx, asm) + + # Get the operands from the stack + ary2st_opnd = ctx.stack_pop(1) + ary1_opnd = ctx.stack_pop(1) + + # Call rb_vm_concat_array(ary1, ary2st) + asm.mov(C_ARGS[0], ary1_opnd) + asm.mov(C_ARGS[1], ary2st_opnd) + asm.call(C.rb_vm_concat_array) + + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def splatarray(jit, ctx, asm) + flag = jit.operand(0) + + # Save the PC and SP because the callee may allocate + # Note that this modifies REG_SP, which is why we do it first + jit_prepare_routine_call(jit, ctx, asm) + + # Get the operands from the stack + ary_opnd = ctx.stack_pop(1) + + # Call rb_vm_splat_array(flag, ary) + asm.mov(C_ARGS[0], flag) + asm.mov(C_ARGS[1], ary_opnd) + asm.call(C.rb_vm_splat_array) + + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def newhash(jit, ctx, asm) + num = jit.operand(0) + + # Save the PC and SP because we are allocating + jit_prepare_routine_call(jit, ctx, asm) + + if num != 0 + # val = rb_hash_new_with_size(num / 2); + asm.mov(C_ARGS[0], num / 2) + asm.call(C.rb_hash_new_with_size) + + # Save the allocated hash as we want to push it after insertion + asm.push(C_RET) + asm.push(C_RET) # x86 alignment + + # Get a pointer to the values to insert into the hash + asm.lea(:rcx, ctx.stack_opnd(num - 1)) + + # rb_hash_bulk_insert(num, STACK_ADDR_FROM_TOP(num), val); + asm.mov(C_ARGS[0], num) + asm.mov(C_ARGS[1], :rcx) + asm.mov(C_ARGS[2], C_RET) + asm.call(C.rb_hash_bulk_insert) + + asm.pop(:rax) + asm.pop(:rax) + + ctx.stack_pop(num) + stack_ret = ctx.stack_push(Type::Hash) + asm.mov(stack_ret, :rax) + else + # val = rb_hash_new(); + asm.call(C.rb_hash_new) + stack_ret = ctx.stack_push(Type::Hash) + asm.mov(stack_ret, C_RET) + end + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def newrange(jit, ctx, asm) + flag = jit.operand(0) + + # rb_range_new() allocates and can raise + jit_prepare_routine_call(jit, ctx, asm) + + # val = rb_range_new(low, high, (int)flag); + asm.mov(C_ARGS[0], ctx.stack_opnd(1)) + asm.mov(C_ARGS[1], ctx.stack_opnd(0)) + asm.mov(C_ARGS[2], flag) + asm.call(C.rb_range_new) + + ctx.stack_pop(2) + stack_ret = ctx.stack_push(Type::UnknownHeap) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def pop(jit, ctx, asm) + ctx.stack_pop + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def dup(jit, ctx, asm) + dup_val = ctx.stack_opnd(0) + mapping, tmp_type = ctx.get_opnd_mapping(StackOpnd[0]) + + loc0 = ctx.stack_push_mapping([mapping, tmp_type]) + asm.mov(:rax, dup_val) + asm.mov(loc0, :rax) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def dupn(jit, ctx, asm) + n = jit.operand(0) + + # In practice, seems to be only used for n==2 + if n != 2 + return CantCompile + end + + opnd1 = ctx.stack_opnd(1) + opnd0 = ctx.stack_opnd(0) + + mapping1 = ctx.get_opnd_mapping(StackOpnd[1]) + mapping0 = ctx.get_opnd_mapping(StackOpnd[0]) + + dst1 = ctx.stack_push_mapping(mapping1) + asm.mov(:rax, opnd1) + asm.mov(dst1, :rax) + + dst0 = ctx.stack_push_mapping(mapping0) + asm.mov(:rax, opnd0) + asm.mov(dst0, :rax) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def swap(jit, ctx, asm) + stack_swap(jit, ctx, asm, 0, 1) + KeepCompiling + end + + # opt_reverse + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def topn(jit, ctx, asm) + n = jit.operand(0) + + top_n_val = ctx.stack_opnd(n) + mapping = ctx.get_opnd_mapping(StackOpnd[n]) + loc0 = ctx.stack_push_mapping(mapping) + asm.mov(:rax, top_n_val) + asm.mov(loc0, :rax) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def setn(jit, ctx, asm) + n = jit.operand(0) + + top_val = ctx.stack_pop(0) + dst_opnd = ctx.stack_opnd(n) + asm.mov(:rax, top_val) + asm.mov(dst_opnd, :rax) + + mapping = ctx.get_opnd_mapping(StackOpnd[0]) + ctx.set_opnd_mapping(StackOpnd[n], mapping) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def adjuststack(jit, ctx, asm) + n = jit.operand(0) + ctx.stack_pop(n) + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def defined(jit, ctx, asm) + op_type = jit.operand(0) + obj = jit.operand(1, ruby: true) + pushval = jit.operand(2, ruby: true) + + # Save the PC and SP because the callee may allocate + # Note that this modifies REG_SP, which is why we do it first + jit_prepare_routine_call(jit, ctx, asm) + + # Get the operands from the stack + v_opnd = ctx.stack_pop(1) + + # Call vm_defined(ec, reg_cfp, op_type, obj, v) + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], CFP) + asm.mov(C_ARGS[2], op_type) + asm.mov(C_ARGS[3], to_value(obj)) + asm.mov(C_ARGS[4], v_opnd) + asm.call(C.rb_vm_defined) + + asm.test(C_RET, 255) + asm.mov(:rax, Qnil) + asm.mov(:rcx, to_value(pushval)) + asm.cmovnz(:rax, :rcx) + + # Push the return value onto the stack + out_type = if C::SPECIAL_CONST_P(pushval) + Type::UnknownImm + else + Type::Unknown + end + stack_ret = ctx.stack_push(out_type) + asm.mov(stack_ret, :rax) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def definedivar(jit, ctx, asm) + # Defer compilation so we can specialize base on a runtime receiver + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + ivar_name = jit.operand(0) + # Value that will be pushed on the stack if the ivar is defined. In practice this is always the + # string "instance-variable". If the ivar is not defined, nil will be pushed instead. + pushval = jit.operand(2, ruby: true) + + # Get the receiver + recv = :rcx + asm.mov(recv, [CFP, C.rb_control_frame_t.offsetof(:self)]) + + # Specialize base on compile time values + comptime_receiver = jit.peek_at_self + + if shape_too_complex?(comptime_receiver) + # Fall back to calling rb_ivar_defined + + # Save the PC and SP because the callee may allocate + # Note that this modifies REG_SP, which is why we do it first + jit_prepare_routine_call(jit, ctx, asm) # clobbers :rax + + # Call rb_ivar_defined(recv, ivar_name) + asm.mov(C_ARGS[0], recv) + asm.mov(C_ARGS[1], ivar_name) + asm.call(C.rb_ivar_defined) + + # if (rb_ivar_defined(recv, ivar_name)) { + # val = pushval; + # } + asm.test(C_RET, 255) + asm.mov(:rax, Qnil) + asm.mov(:rcx, to_value(pushval)) + asm.cmovnz(:rax, :rcx) + + # Push the return value onto the stack + out_type = C::SPECIAL_CONST_P(pushval) ? Type::UnknownImm : Type::Unknown + stack_ret = ctx.stack_push(out_type) + asm.mov(stack_ret, :rax) + + return KeepCompiling + end + + shape_id = C.rb_shape_get_shape_id(comptime_receiver) + ivar_exists = C.rb_shape_get_iv_index(shape_id, ivar_name) + + side_exit = side_exit(jit, ctx) + + # Guard heap object (recv_opnd must be used before stack_pop) + guard_object_is_heap(jit, ctx, asm, recv, SelfOpnd) + + shape_opnd = DwordPtr[recv, C.rb_shape_id_offset] + + asm.comment('guard shape') + asm.cmp(shape_opnd, shape_id) + jit_chain_guard(:jne, jit, ctx, asm, side_exit) + + result = ivar_exists ? C.to_value(pushval) : Qnil + putobject(jit, ctx, asm, val: result) + + # Jump to next instruction. This allows guard chains to share the same successor. + jump_to_next_insn(jit, ctx, asm) + + return EndBlock + end + + # checkmatch + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def checkkeyword(jit, ctx, asm) + # When a keyword is unspecified past index 32, a hash will be used + # instead. This can only happen in iseqs taking more than 32 keywords. + if jit.iseq.body.param.keyword.num >= 32 + return CantCompile + end + + # The EP offset to the undefined bits local + bits_offset = jit.operand(0) + + # The index of the keyword we want to check + index = jit.operand(1, signed: true) + + # Load environment pointer EP + ep_reg = :rax + jit_get_ep(asm, 0, reg: ep_reg) + + # VALUE kw_bits = *(ep - bits) + bits_opnd = [ep_reg, C.VALUE.size * -bits_offset] + + # unsigned int b = (unsigned int)FIX2ULONG(kw_bits); + # if ((b & (0x01 << idx))) { + # + # We can skip the FIX2ULONG conversion by shifting the bit we test + bit_test = 0x01 << (index + 1) + asm.test(bits_opnd, bit_test) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.cmovz(:rax, :rcx) + + stack_ret = ctx.stack_push(Type::UnknownImm) + asm.mov(stack_ret, :rax) + + KeepCompiling + end + + # checktype + # defineclass + # definemethod + # definesmethod + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def send(jit, ctx, asm) + # Specialize on a compile-time receiver, and split a block for chain guards + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + cd = C.rb_call_data.new(jit.operand(0)) + blockiseq = jit.operand(1) + + # calling->ci + mid = C.vm_ci_mid(cd.ci) + calling = build_calling(ci: cd.ci, block_handler: blockiseq) + + # vm_sendish + cme, comptime_recv_klass = jit_search_method(jit, ctx, asm, mid, calling) + if cme == CantCompile + return CantCompile + end + jit_call_general(jit, ctx, asm, mid, calling, cme, comptime_recv_klass) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_send_without_block(jit, ctx, asm, cd: C.rb_call_data.new(jit.operand(0))) + # Specialize on a compile-time receiver, and split a block for chain guards + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + # calling->ci + mid = C.vm_ci_mid(cd.ci) + calling = build_calling(ci: cd.ci, block_handler: C::VM_BLOCK_HANDLER_NONE) + + # vm_sendish + cme, comptime_recv_klass = jit_search_method(jit, ctx, asm, mid, calling) + if cme == CantCompile + return CantCompile + end + jit_call_general(jit, ctx, asm, mid, calling, cme, comptime_recv_klass) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def objtostring(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + recv = ctx.stack_opnd(0) + comptime_recv = jit.peek_at_stack(0) + + if C.RB_TYPE_P(comptime_recv, C::RUBY_T_STRING) + side_exit = side_exit(jit, ctx) + + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_recv), recv, StackOpnd[0], comptime_recv, side_exit) + # No work needed. The string value is already on the top of the stack. + KeepCompiling + else + cd = C.rb_call_data.new(jit.operand(0)) + opt_send_without_block(jit, ctx, asm, cd:) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_str_freeze(jit, ctx, asm) + unless Invariants.assume_bop_not_redefined(jit, C::STRING_REDEFINED_OP_FLAG, C::BOP_FREEZE) + return CantCompile; + end + + str = jit.operand(0, ruby: true) + + # Push the return value onto the stack + stack_ret = ctx.stack_push(Type::CString) + asm.mov(:rax, to_value(str)) + asm.mov(stack_ret, :rax) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_nil_p(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # opt_str_uminus + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_newarray_send(jit, ctx, asm) + type = C.ID2SYM jit.operand(1) + + case type + when :min then opt_newarray_min(jit, ctx, asm) + when :max then opt_newarray_max(jit, ctx, asm) + when :hash then opt_newarray_hash(jit, ctx, asm) + else + return CantCompile + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_newarray_min(jit, ctx, asm) + num = jit.operand(0) + + # Save the PC and SP because we may allocate + jit_prepare_routine_call(jit, ctx, asm) + + offset_magnitude = C.VALUE.size * num + values_opnd = ctx.sp_opnd(-offset_magnitude) + asm.lea(:rax, values_opnd) + + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], num) + asm.mov(C_ARGS[2], :rax) + asm.call(C.rb_vm_opt_newarray_min) + + ctx.stack_pop(num) + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_newarray_max(jit, ctx, asm) + num = jit.operand(0) + + # Save the PC and SP because we may allocate + jit_prepare_routine_call(jit, ctx, asm) + + offset_magnitude = C.VALUE.size * num + values_opnd = ctx.sp_opnd(-offset_magnitude) + asm.lea(:rax, values_opnd) + + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], num) + asm.mov(C_ARGS[2], :rax) + asm.call(C.rb_vm_opt_newarray_max) + + ctx.stack_pop(num) + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_newarray_hash(jit, ctx, asm) + num = jit.operand(0) + + # Save the PC and SP because we may allocate + jit_prepare_routine_call(jit, ctx, asm) + + offset_magnitude = C.VALUE.size * num + values_opnd = ctx.sp_opnd(-offset_magnitude) + asm.lea(:rax, values_opnd) + + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], num) + asm.mov(C_ARGS[2], :rax) + asm.call(C.rb_vm_opt_newarray_hash) + + ctx.stack_pop(num) + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def invokesuper(jit, ctx, asm) + cd = C.rb_call_data.new(jit.operand(0)) + block = jit.operand(1) + + # Defer compilation so we can specialize on class of receiver + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + me = C.rb_vm_frame_method_entry(jit.cfp) + if me.nil? + return CantCompile + end + + # FIXME: We should track and invalidate this block when this cme is invalidated + current_defined_class = me.defined_class + mid = me.def.original_id + + if me.to_i != C.rb_callable_method_entry(current_defined_class, me.called_id).to_i + # Though we likely could generate this call, as we are only concerned + # with the method entry remaining valid, assume_method_lookup_stable + # below requires that the method lookup matches as well + return CantCompile + end + + # vm_search_normal_superclass + rbasic_klass = C.to_ruby(C.RBasic.new(C.to_value(current_defined_class)).klass) + if C::BUILTIN_TYPE(current_defined_class) == C::RUBY_T_ICLASS && C::BUILTIN_TYPE(rbasic_klass) == C::RUBY_T_MODULE && \ + C::FL_TEST_RAW(rbasic_klass, C::RMODULE_IS_REFINEMENT) + return CantCompile + end + comptime_superclass = C.rb_class_get_superclass(C.RCLASS_ORIGIN(current_defined_class)) + + ci = cd.ci + argc = C.vm_ci_argc(ci) + + ci_flags = C.vm_ci_flag(ci) + + # Don't JIT calls that aren't simple + # Note, not using VM_CALL_ARGS_SIMPLE because sometimes we pass a block. + + if ci_flags & C::VM_CALL_KWARG != 0 + asm.incr_counter(:send_keywords) + return CantCompile + end + if ci_flags & C::VM_CALL_KW_SPLAT != 0 + asm.incr_counter(:send_kw_splat) + return CantCompile + end + if ci_flags & C::VM_CALL_ARGS_BLOCKARG != 0 + asm.incr_counter(:send_block_arg) + return CantCompile + end + + # Ensure we haven't rebound this method onto an incompatible class. + # In the interpreter we try to avoid making this check by performing some + # cheaper calculations first, but since we specialize on the method entry + # and so only have to do this once at compile time this is fine to always + # check and side exit. + comptime_recv = jit.peek_at_stack(argc) + unless C.obj_is_kind_of(comptime_recv, current_defined_class) + return CantCompile + end + + # Do method lookup + cme = C.rb_callable_method_entry(comptime_superclass, mid) + + if cme.nil? + return CantCompile + end + + # Check that we'll be able to write this method dispatch before generating checks + cme_def_type = cme.def.type + if cme_def_type != C::VM_METHOD_TYPE_ISEQ && cme_def_type != C::VM_METHOD_TYPE_CFUNC + # others unimplemented + return CantCompile + end + + asm.comment('guard known me') + lep_opnd = :rax + jit_get_lep(jit, asm, reg: lep_opnd) + ep_me_opnd = [lep_opnd, C.VALUE.size * C::VM_ENV_DATA_INDEX_ME_CREF] + + asm.mov(:rcx, me.to_i) + asm.cmp(ep_me_opnd, :rcx) + asm.jne(counted_exit(side_exit(jit, ctx), :invokesuper_me_changed)) + + if block == C::VM_BLOCK_HANDLER_NONE + # Guard no block passed + # rb_vm_frame_block_handler(GET_EC()->cfp) == VM_BLOCK_HANDLER_NONE + # note, we assume VM_ASSERT(VM_ENV_LOCAL_P(ep)) + # + # TODO: this could properly forward the current block handler, but + # would require changes to gen_send_* + asm.comment('guard no block given') + ep_specval_opnd = [lep_opnd, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL] + asm.cmp(ep_specval_opnd, C::VM_BLOCK_HANDLER_NONE) + asm.jne(counted_exit(side_exit(jit, ctx), :invokesuper_block)) + end + + # We need to assume that both our current method entry and the super + # method entry we invoke remain stable + Invariants.assume_method_lookup_stable(jit, me) + Invariants.assume_method_lookup_stable(jit, cme) + + # Method calls may corrupt types + ctx.clear_local_types + + calling = build_calling(ci:, block_handler: block) + case cme_def_type + in C::VM_METHOD_TYPE_ISEQ + iseq = def_iseq_ptr(cme.def) + frame_type = C::VM_FRAME_MAGIC_METHOD | C::VM_ENV_FLAG_LOCAL + jit_call_iseq(jit, ctx, asm, cme, calling, iseq, frame_type:) + in C::VM_METHOD_TYPE_CFUNC + jit_call_cfunc(jit, ctx, asm, cme, calling) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def invokeblock(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + # Get call info + cd = C.rb_call_data.new(jit.operand(0)) + calling = build_calling(ci: cd.ci, block_handler: :captured) + + # Get block_handler + cfp = jit.cfp + lep = C.rb_vm_ep_local_ep(cfp.ep) + comptime_handler = lep[C::VM_ENV_DATA_INDEX_SPECVAL] + + # Handle each block_handler type + if comptime_handler == C::VM_BLOCK_HANDLER_NONE # no block given + asm.incr_counter(:invokeblock_none) + CantCompile + elsif comptime_handler & 0x3 == 0x1 # VM_BH_ISEQ_BLOCK_P + asm.comment('get local EP') + ep_reg = :rax + jit_get_lep(jit, asm, reg: ep_reg) + asm.mov(:rax, [ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) # block_handler_opnd + + asm.comment('guard block_handler type') + side_exit = side_exit(jit, ctx) + asm.mov(:rcx, :rax) + asm.and(:rcx, 0x3) # block_handler is a tagged pointer + asm.cmp(:rcx, 0x1) # VM_BH_ISEQ_BLOCK_P + tag_changed_exit = counted_exit(side_exit, :invokeblock_tag_changed) + jit_chain_guard(:jne, jit, ctx, asm, tag_changed_exit) + + comptime_captured = C.rb_captured_block.new(comptime_handler & ~0x3) + comptime_iseq = comptime_captured.code.iseq + + asm.comment('guard known ISEQ') + asm.and(:rax, ~0x3) # captured + asm.mov(:rax, [:rax, C.VALUE.size * 2]) # captured->iseq + asm.mov(:rcx, comptime_iseq.to_i) + asm.cmp(:rax, :rcx) + block_changed_exit = counted_exit(side_exit, :invokeblock_iseq_block_changed) + jit_chain_guard(:jne, jit, ctx, asm, block_changed_exit) + + jit_call_iseq(jit, ctx, asm, nil, calling, comptime_iseq, frame_type: C::VM_FRAME_MAGIC_BLOCK) + elsif comptime_handler & 0x3 == 0x3 # VM_BH_IFUNC_P + # We aren't handling CALLER_SETUP_ARG and CALLER_REMOVE_EMPTY_KW_SPLAT yet. + if calling.flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:invokeblock_ifunc_args_splat) + return CantCompile + end + if calling.flags & C::VM_CALL_KW_SPLAT != 0 + asm.incr_counter(:invokeblock_ifunc_kw_splat) + return CantCompile + end + + asm.comment('get local EP') + jit_get_lep(jit, asm, reg: :rax) + asm.mov(:rcx, [:rax, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) # block_handler_opnd + + asm.comment('guard block_handler type'); + side_exit = side_exit(jit, ctx) + asm.mov(:rax, :rcx) # block_handler_opnd + asm.and(:rax, 0x3) # tag_opnd: block_handler is a tagged pointer + asm.cmp(:rax, 0x3) # VM_BH_IFUNC_P + tag_changed_exit = counted_exit(side_exit, :invokeblock_tag_changed) + jit_chain_guard(:jne, jit, ctx, asm, tag_changed_exit) + + # The cfunc may not be leaf + jit_prepare_routine_call(jit, ctx, asm) # clobbers :rax + + asm.comment('call ifunc') + asm.and(:rcx, ~0x3) # captured_opnd + asm.lea(:rax, ctx.sp_opnd(-calling.argc * C.VALUE.size)) # argv + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], :rcx) # captured_opnd + asm.mov(C_ARGS[2], calling.argc) + asm.mov(C_ARGS[3], :rax) # argv + asm.call(C.rb_vm_yield_with_cfunc) + + ctx.stack_pop(calling.argc) + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + # cfunc calls may corrupt types + ctx.clear_local_types + + # Share the successor with other chains + jump_to_next_insn(jit, ctx, asm) + EndBlock + elsif symbol?(comptime_handler) + asm.incr_counter(:invokeblock_symbol) + CantCompile + else # Proc + asm.incr_counter(:invokeblock_proc) + CantCompile + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def leave(jit, ctx, asm) + assert_equal(ctx.stack_size, 1) + + jit_check_ints(jit, ctx, asm) + + asm.comment('pop stack frame') + asm.lea(:rax, [CFP, C.rb_control_frame_t.size]) + asm.mov(CFP, :rax) + asm.mov([EC, C.rb_execution_context_t.offsetof(:cfp)], :rax) + + # Return a value (for compile_leave_exit) + ret_opnd = ctx.stack_pop + asm.mov(:rax, ret_opnd) + + # Set caller's SP and push a value to its stack (for JIT) + asm.mov(SP, [CFP, C.rb_control_frame_t.offsetof(:sp)]) # Note: SP is in the position after popping a receiver and arguments + asm.mov([SP], :rax) + + # Jump to cfp->jit_return + asm.jmp([CFP, -C.rb_control_frame_t.size + C.rb_control_frame_t.offsetof(:jit_return)]) + + EndBlock + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def throw(jit, ctx, asm) + throw_state = jit.operand(0) + asm.mov(:rcx, ctx.stack_pop(1)) # throwobj + + # THROW_DATA_NEW allocates. Save SP for GC and PC for allocation tracing as + # well as handling the catch table. However, not using jit_prepare_routine_call + # since we don't need a patch point for this implementation. + jit_save_pc(jit, asm) # clobbers rax + jit_save_sp(ctx, asm) + + # rb_vm_throw verifies it's a valid throw, sets ec->tag->state, and returns throw + # data, which is throwobj or a vm_throw_data wrapping it. When ec->tag->state is + # set, JIT code callers will handle the throw with vm_exec_handle_exception. + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], CFP) + asm.mov(C_ARGS[2], throw_state) + # asm.mov(C_ARGS[3], :rcx) # same reg + asm.call(C.rb_vm_throw) + + asm.comment('exit from throw') + asm.pop(SP) + asm.pop(EC) + asm.pop(CFP) + + # return C_RET as C_RET + asm.ret + EndBlock + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jump(jit, ctx, asm) + # Check for interrupts, but only on backward branches that may create loops + jump_offset = jit.operand(0, signed: true) + if jump_offset < 0 + jit_check_ints(jit, ctx, asm) + end + + pc = jit.pc + C.VALUE.size * (jit.insn.len + jump_offset) + jit_direct_jump(jit.iseq, pc, ctx, asm) + EndBlock + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def branchif(jit, ctx, asm) + # Check for interrupts, but only on backward branches that may create loops + jump_offset = jit.operand(0, signed: true) + if jump_offset < 0 + jit_check_ints(jit, ctx, asm) + end + + # Get the branch target instruction offsets + next_pc = jit.pc + C.VALUE.size * jit.insn.len + jump_pc = jit.pc + C.VALUE.size * (jit.insn.len + jump_offset) + + val_type = ctx.get_opnd_type(StackOpnd[0]) + val_opnd = ctx.stack_pop(1) + + if (result = val_type.known_truthy) != nil + target_pc = result ? jump_pc : next_pc + jit_direct_jump(jit.iseq, target_pc, ctx, asm) + else + # This `test` sets ZF only for Qnil and Qfalse, which let jz jump. + asm.test(val_opnd, ~Qnil) + + # Set stubs + branch_stub = BranchStub.new( + iseq: jit.iseq, + shape: Default, + target0: BranchTarget.new(ctx:, pc: jump_pc), # branch target + target1: BranchTarget.new(ctx:, pc: next_pc), # fallthrough + ) + branch_stub.target0.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(ctx, ocb_asm, branch_stub, true) + @ocb.write(ocb_asm) + end + branch_stub.target1.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(ctx, ocb_asm, branch_stub, false) + @ocb.write(ocb_asm) + end + + # Jump to target0 on jnz + branch_stub.compile = compile_branchif(branch_stub) + branch_stub.compile.call(asm) + end + + EndBlock + end + + def compile_branchif(branch_stub) # Proc escapes arguments in memory + proc do |branch_asm| + branch_asm.comment("branchif #{branch_stub.shape}") + branch_asm.stub(branch_stub) do + case branch_stub.shape + in Default + branch_asm.jnz(branch_stub.target0.address) + branch_asm.jmp(branch_stub.target1.address) + in Next0 + branch_asm.jz(branch_stub.target1.address) + in Next1 + branch_asm.jnz(branch_stub.target0.address) + end + end + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def branchunless(jit, ctx, asm) + # Check for interrupts, but only on backward branches that may create loops + jump_offset = jit.operand(0, signed: true) + if jump_offset < 0 + jit_check_ints(jit, ctx, asm) + end + + # Get the branch target instruction offsets + next_pc = jit.pc + C.VALUE.size * jit.insn.len + jump_pc = jit.pc + C.VALUE.size * (jit.insn.len + jump_offset) + + val_type = ctx.get_opnd_type(StackOpnd[0]) + val_opnd = ctx.stack_pop(1) + + if (result = val_type.known_truthy) != nil + target_pc = result ? next_pc : jump_pc + jit_direct_jump(jit.iseq, target_pc, ctx, asm) + else + # This `test` sets ZF only for Qnil and Qfalse, which let jz jump. + asm.test(val_opnd, ~Qnil) + + # Set stubs + branch_stub = BranchStub.new( + iseq: jit.iseq, + shape: Default, + target0: BranchTarget.new(ctx:, pc: jump_pc), # branch target + target1: BranchTarget.new(ctx:, pc: next_pc), # fallthrough + ) + branch_stub.target0.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(ctx, ocb_asm, branch_stub, true) + @ocb.write(ocb_asm) + end + branch_stub.target1.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(ctx, ocb_asm, branch_stub, false) + @ocb.write(ocb_asm) + end + + # Jump to target0 on jz + branch_stub.compile = compile_branchunless(branch_stub) + branch_stub.compile.call(asm) + end + + EndBlock + end + + def compile_branchunless(branch_stub) # Proc escapes arguments in memory + proc do |branch_asm| + branch_asm.comment("branchunless #{branch_stub.shape}") + branch_asm.stub(branch_stub) do + case branch_stub.shape + in Default + branch_asm.jz(branch_stub.target0.address) + branch_asm.jmp(branch_stub.target1.address) + in Next0 + branch_asm.jnz(branch_stub.target1.address) + in Next1 + branch_asm.jz(branch_stub.target0.address) + end + end + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def branchnil(jit, ctx, asm) + # Check for interrupts, but only on backward branches that may create loops + jump_offset = jit.operand(0, signed: true) + if jump_offset < 0 + jit_check_ints(jit, ctx, asm) + end + + # Get the branch target instruction offsets + next_pc = jit.pc + C.VALUE.size * jit.insn.len + jump_pc = jit.pc + C.VALUE.size * (jit.insn.len + jump_offset) + + val_type = ctx.get_opnd_type(StackOpnd[0]) + val_opnd = ctx.stack_pop(1) + + if (result = val_type.known_nil) != nil + target_pc = result ? jump_pc : next_pc + jit_direct_jump(jit.iseq, target_pc, ctx, asm) + else + asm.cmp(val_opnd, Qnil) + + # Set stubs + branch_stub = BranchStub.new( + iseq: jit.iseq, + shape: Default, + target0: BranchTarget.new(ctx:, pc: jump_pc), # branch target + target1: BranchTarget.new(ctx:, pc: next_pc), # fallthrough + ) + branch_stub.target0.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(ctx, ocb_asm, branch_stub, true) + @ocb.write(ocb_asm) + end + branch_stub.target1.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(ctx, ocb_asm, branch_stub, false) + @ocb.write(ocb_asm) + end + + # Jump to target0 on je + branch_stub.compile = compile_branchnil(branch_stub) + branch_stub.compile.call(asm) + end + + EndBlock + end + + def compile_branchnil(branch_stub) # Proc escapes arguments in memory + proc do |branch_asm| + branch_asm.comment("branchnil #{branch_stub.shape}") + branch_asm.stub(branch_stub) do + case branch_stub.shape + in Default + branch_asm.je(branch_stub.target0.address) + branch_asm.jmp(branch_stub.target1.address) + in Next0 + branch_asm.jne(branch_stub.target1.address) + in Next1 + branch_asm.je(branch_stub.target0.address) + end + end + end + end + + # once + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_case_dispatch(jit, ctx, asm) + # Normally this instruction would lookup the key in a hash and jump to an + # offset based on that. + # Instead we can take the fallback case and continue with the next + # instruction. + # We'd hope that our jitted code will be sufficiently fast without the + # hash lookup, at least for small hashes, but it's worth revisiting this + # assumption in the future. + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + starting_context = ctx.dup + + case_hash = jit.operand(0, ruby: true) + else_offset = jit.operand(1) + + # Try to reorder case/else branches so that ones that are actually used come first. + # Supporting only Fixnum for now so that the implementation can be an equality check. + key_opnd = ctx.stack_pop(1) + comptime_key = jit.peek_at_stack(0) + + # Check that all cases are fixnums to avoid having to register BOP assumptions on + # all the types that case hashes support. This spends compile time to save memory. + if fixnum?(comptime_key) && comptime_key <= 2**32 && C.rb_hash_keys(case_hash).all? { |key| fixnum?(key) } + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, C::BOP_EQQ) + return CantCompile + end + + # Check if the key is the same value + asm.cmp(key_opnd, to_value(comptime_key)) + side_exit = side_exit(jit, starting_context) + jit_chain_guard(:jne, jit, starting_context, asm, side_exit) + + # Get the offset for the compile-time key + offset = C.rb_hash_stlike_lookup(case_hash, comptime_key) + # NOTE: If we hit the else branch with various values, it could negatively impact the performance. + jump_offset = offset || else_offset + + # Jump to the offset of case or else + target_pc = jit.pc + (jit.insn.len + jump_offset) * C.VALUE.size + jit_direct_jump(jit.iseq, target_pc, ctx, asm) + EndBlock + else + KeepCompiling # continue with === branches + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_plus(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + comptime_recv = jit.peek_at_stack(1) + comptime_obj = jit.peek_at_stack(0) + + if fixnum?(comptime_recv) && fixnum?(comptime_obj) + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, C::BOP_PLUS) + return CantCompile + end + + # Check that both operands are fixnums + guard_two_fixnums(jit, ctx, asm) + + obj_opnd = ctx.stack_pop + recv_opnd = ctx.stack_pop + + asm.mov(:rax, recv_opnd) + asm.sub(:rax, 1) # untag + asm.mov(:rcx, obj_opnd) + asm.add(:rax, :rcx) + asm.jo(side_exit(jit, ctx)) + + dst_opnd = ctx.stack_push(Type::Fixnum) + asm.mov(dst_opnd, :rax) + + KeepCompiling + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_minus(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + comptime_recv = jit.peek_at_stack(1) + comptime_obj = jit.peek_at_stack(0) + + if fixnum?(comptime_recv) && fixnum?(comptime_obj) + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, C::BOP_MINUS) + return CantCompile + end + + # Check that both operands are fixnums + guard_two_fixnums(jit, ctx, asm) + + obj_opnd = ctx.stack_pop + recv_opnd = ctx.stack_pop + + asm.mov(:rax, recv_opnd) + asm.mov(:rcx, obj_opnd) + asm.sub(:rax, :rcx) + asm.jo(side_exit(jit, ctx)) + asm.add(:rax, 1) # re-tag + + dst_opnd = ctx.stack_push(Type::Fixnum) + asm.mov(dst_opnd, :rax) + + KeepCompiling + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_mult(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_div(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_mod(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + if two_fixnums_on_stack?(jit) + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, C::BOP_MOD) + return CantCompile + end + + # Check that both operands are fixnums + guard_two_fixnums(jit, ctx, asm) + + # Get the operands and destination from the stack + arg1 = ctx.stack_pop(1) + arg0 = ctx.stack_pop(1) + + # Check for arg0 % 0 + asm.cmp(arg1, 0) + asm.je(side_exit(jit, ctx)) + + # Call rb_fix_mod_fix(VALUE recv, VALUE obj) + asm.mov(C_ARGS[0], arg0) + asm.mov(C_ARGS[1], arg1) + asm.call(C.rb_fix_mod_fix) + + # Push the return value onto the stack + stack_ret = ctx.stack_push(Type::Fixnum) + asm.mov(stack_ret, C_RET) + + KeepCompiling + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_eq(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + if jit_equality_specialized(jit, ctx, asm, true) + jump_to_next_insn(jit, ctx, asm) + EndBlock + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_neq(jit, ctx, asm) + # opt_neq is passed two rb_call_data as arguments: + # first for ==, second for != + neq_cd = C.rb_call_data.new(jit.operand(1)) + opt_send_without_block(jit, ctx, asm, cd: neq_cd) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_lt(jit, ctx, asm) + jit_fixnum_cmp(jit, ctx, asm, opcode: :cmovl, bop: C::BOP_LT) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_le(jit, ctx, asm) + jit_fixnum_cmp(jit, ctx, asm, opcode: :cmovle, bop: C::BOP_LE) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_gt(jit, ctx, asm) + jit_fixnum_cmp(jit, ctx, asm, opcode: :cmovg, bop: C::BOP_GT) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_ge(jit, ctx, asm) + jit_fixnum_cmp(jit, ctx, asm, opcode: :cmovge, bop: C::BOP_GE) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_ltlt(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_and(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + if two_fixnums_on_stack?(jit) + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, C::BOP_AND) + return CantCompile + end + + # Check that both operands are fixnums + guard_two_fixnums(jit, ctx, asm) + + # Get the operands and destination from the stack + arg1 = ctx.stack_pop(1) + arg0 = ctx.stack_pop(1) + + asm.comment('bitwise and') + asm.mov(:rax, arg0) + asm.and(:rax, arg1) + + # Push the return value onto the stack + dst = ctx.stack_push(Type::Fixnum) + asm.mov(dst, :rax) + + KeepCompiling + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_or(jit, ctx, asm) + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + if two_fixnums_on_stack?(jit) + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, C::BOP_OR) + return CantCompile + end + + # Check that both operands are fixnums + guard_two_fixnums(jit, ctx, asm) + + # Get the operands and destination from the stack + asm.comment('bitwise or') + arg1 = ctx.stack_pop(1) + arg0 = ctx.stack_pop(1) + + # Do the bitwise or arg0 | arg1 + asm.mov(:rax, arg0) + asm.or(:rax, arg1) + + # Push the return value onto the stack + dst = ctx.stack_push(Type::Fixnum) + asm.mov(dst, :rax) + + KeepCompiling + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_aref(jit, ctx, asm) + cd = C.rb_call_data.new(jit.operand(0)) + argc = C.vm_ci_argc(cd.ci) + + if argc != 1 + asm.incr_counter(:optaref_argc_not_one) + return CantCompile + end + + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + comptime_recv = jit.peek_at_stack(1) + comptime_obj = jit.peek_at_stack(0) + + side_exit = side_exit(jit, ctx) + + if C.rb_class_of(comptime_recv) == Array && fixnum?(comptime_obj) + unless Invariants.assume_bop_not_redefined(jit, C::ARRAY_REDEFINED_OP_FLAG, C::BOP_AREF) + return CantCompile + end + + idx_opnd = ctx.stack_opnd(0) + recv_opnd = ctx.stack_opnd(1) + + not_array_exit = counted_exit(side_exit, :optaref_recv_not_array) + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_recv), recv_opnd, StackOpnd[1], comptime_recv, not_array_exit) + + # Bail if idx is not a FIXNUM + asm.mov(:rax, idx_opnd) + asm.test(:rax, C::RUBY_FIXNUM_FLAG) + asm.jz(counted_exit(side_exit, :optaref_arg_not_fixnum)) + + # Call VALUE rb_ary_entry_internal(VALUE ary, long offset). + # It never raises or allocates, so we don't need to write to cfp->pc. + asm.sar(:rax, 1) # Convert fixnum to int + asm.mov(C_ARGS[0], recv_opnd) + asm.mov(C_ARGS[1], :rax) + asm.call(C.rb_ary_entry_internal) + + # Pop the argument and the receiver + ctx.stack_pop(2) + + # Push the return value onto the stack + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + # Let guard chains share the same successor + jump_to_next_insn(jit, ctx, asm) + EndBlock + elsif C.rb_class_of(comptime_recv) == Hash + unless Invariants.assume_bop_not_redefined(jit, C::HASH_REDEFINED_OP_FLAG, C::BOP_AREF) + return CantCompile + end + + recv_opnd = ctx.stack_opnd(1) + + # Guard that the receiver is a Hash + not_hash_exit = counted_exit(side_exit, :optaref_recv_not_hash) + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_recv), recv_opnd, StackOpnd[1], comptime_recv, not_hash_exit) + + # Prepare to call rb_hash_aref(). It might call #hash on the key. + jit_prepare_routine_call(jit, ctx, asm) + + asm.comment('call rb_hash_aref') + key_opnd = ctx.stack_opnd(0) + recv_opnd = ctx.stack_opnd(1) + asm.mov(:rdi, recv_opnd) + asm.mov(:rsi, key_opnd) + asm.call(C.rb_hash_aref) + + # Pop the key and the receiver + ctx.stack_pop(2) + + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + # Let guard chains share the same successor + jump_to_next_insn(jit, ctx, asm) + EndBlock + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_aset(jit, ctx, asm) + # Defer compilation so we can specialize on a runtime `self` + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + comptime_recv = jit.peek_at_stack(2) + comptime_key = jit.peek_at_stack(1) + + # Get the operands from the stack + recv = ctx.stack_opnd(2) + key = ctx.stack_opnd(1) + _val = ctx.stack_opnd(0) + + if C.rb_class_of(comptime_recv) == Array && fixnum?(comptime_key) + side_exit = side_exit(jit, ctx) + + # Guard receiver is an Array + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_recv), recv, StackOpnd[2], comptime_recv, side_exit) + + # Guard key is a fixnum + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_key), key, StackOpnd[1], comptime_key, side_exit) + + # We might allocate or raise + jit_prepare_routine_call(jit, ctx, asm) + + asm.comment('call rb_ary_store') + recv = ctx.stack_opnd(2) + key = ctx.stack_opnd(1) + val = ctx.stack_opnd(0) + asm.mov(:rax, key) + asm.sar(:rax, 1) # FIX2LONG(key) + asm.mov(C_ARGS[0], recv) + asm.mov(C_ARGS[1], :rax) + asm.mov(C_ARGS[2], val) + asm.call(C.rb_ary_store) + + # rb_ary_store returns void + # stored value should still be on stack + val = ctx.stack_opnd(0) + + # Push the return value onto the stack + ctx.stack_pop(3) + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(:rax, val) + asm.mov(stack_ret, :rax) + + jump_to_next_insn(jit, ctx, asm) + EndBlock + elsif C.rb_class_of(comptime_recv) == Hash + side_exit = side_exit(jit, ctx) + + # Guard receiver is a Hash + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_recv), recv, StackOpnd[2], comptime_recv, side_exit) + + # We might allocate or raise + jit_prepare_routine_call(jit, ctx, asm) + + # Call rb_hash_aset + recv = ctx.stack_opnd(2) + key = ctx.stack_opnd(1) + val = ctx.stack_opnd(0) + asm.mov(C_ARGS[0], recv) + asm.mov(C_ARGS[1], key) + asm.mov(C_ARGS[2], val) + asm.call(C.rb_hash_aset) + + # Push the return value onto the stack + ctx.stack_pop(3) + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + jump_to_next_insn(jit, ctx, asm) + EndBlock + else + opt_send_without_block(jit, ctx, asm) + end + end + + # opt_aset_with + # opt_aref_with + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_length(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_size(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_empty_p(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_succ(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_not(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_regexpmatch2(jit, ctx, asm) + opt_send_without_block(jit, ctx, asm) + end + + # invokebuiltin + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_invokebuiltin_delegate(jit, ctx, asm) + bf = C.rb_builtin_function.new(jit.operand(0)) + bf_argc = bf.argc + start_index = jit.operand(1) + + # ec, self, and arguments + if bf_argc + 2 > C_ARGS.size + return CantCompile + end + + # If the calls don't allocate, do they need up to date PC, SP? + jit_prepare_routine_call(jit, ctx, asm) + + # Call the builtin func (ec, recv, arg1, arg2, ...) + asm.comment('call builtin func') + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], [CFP, C.rb_control_frame_t.offsetof(:self)]) + + # Copy arguments from locals + if bf_argc > 0 + # Load environment pointer EP from CFP + asm.mov(:rax, [CFP, C.rb_control_frame_t.offsetof(:ep)]) + + bf_argc.times do |i| + table_size = jit.iseq.body.local_table_size + offs = -table_size - C::VM_ENV_DATA_SIZE + 1 + start_index + i + asm.mov(C_ARGS[2 + i], [:rax, offs * C.VALUE.size]) + end + end + asm.call(bf.func_ptr) + + # Push the return value + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + KeepCompiling + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def opt_invokebuiltin_delegate_leave(jit, ctx, asm) + opt_invokebuiltin_delegate(jit, ctx, asm) + # opt_invokebuiltin_delegate is always followed by leave insn + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putobject_INT2FIX_0_(jit, ctx, asm) + putobject(jit, ctx, asm, val: C.to_value(0)) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def putobject_INT2FIX_1_(jit, ctx, asm) + putobject(jit, ctx, asm, val: C.to_value(1)) + end + + # + # C func + # + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_true(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 0 + asm.comment('nil? == true') + ctx.stack_pop(1) + stack_ret = ctx.stack_push(Type::True) + asm.mov(stack_ret, Qtrue) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_false(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 0 + asm.comment('nil? == false') + ctx.stack_pop(1) + stack_ret = ctx.stack_push(Type::False) + asm.mov(stack_ret, Qfalse) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_kernel_is_a(jit, ctx, asm, argc, known_recv_class) + if argc != 1 + return false + end + + # If this is a super call we might not know the class + if known_recv_class.nil? + return false + end + + # Important note: The output code will simply `return true/false`. + # Correctness follows from: + # - `known_recv_class` implies there is a guard scheduled before here + # for a particular `CLASS_OF(lhs)`. + # - We guard that rhs is identical to the compile-time sample + # - In general, for any two Class instances A, B, `A < B` does not change at runtime. + # Class#superclass is stable. + + sample_rhs = jit.peek_at_stack(0) + sample_lhs = jit.peek_at_stack(1) + + # We are not allowing module here because the module hierarchy can change at runtime. + if C.RB_TYPE_P(sample_rhs, C::RUBY_T_CLASS) + return false + end + sample_is_a = C.obj_is_kind_of(sample_lhs, sample_rhs) + + side_exit = side_exit(jit, ctx) + asm.comment('Kernel#is_a?') + asm.mov(:rax, to_value(sample_rhs)) + asm.cmp(ctx.stack_opnd(0), :rax) + asm.jne(counted_exit(side_exit, :send_is_a_class_mismatch)) + + ctx.stack_pop(2) + + if sample_is_a + stack_ret = ctx.stack_push(Type::True) + asm.mov(stack_ret, Qtrue) + else + stack_ret = ctx.stack_push(Type::False) + asm.mov(stack_ret, Qfalse) + end + return true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_kernel_instance_of(jit, ctx, asm, argc, known_recv_class) + if argc != 1 + return false + end + + # If this is a super call we might not know the class + if known_recv_class.nil? + return false + end + + # Important note: The output code will simply `return true/false`. + # Correctness follows from: + # - `known_recv_class` implies there is a guard scheduled before here + # for a particular `CLASS_OF(lhs)`. + # - We guard that rhs is identical to the compile-time sample + # - For a particular `CLASS_OF(lhs)`, `rb_obj_class(lhs)` does not change. + # (because for any singleton class `s`, `s.superclass.equal?(s.attached_object.class)`) + + sample_rhs = jit.peek_at_stack(0) + sample_lhs = jit.peek_at_stack(1) + + # Filters out cases where the C implementation raises + unless C.RB_TYPE_P(sample_rhs, C::RUBY_T_CLASS) || C.RB_TYPE_P(sample_rhs, C::RUBY_T_MODULE) + return false + end + + # We need to grab the class here to deal with singleton classes. + # Instance of grabs the "real class" of the object rather than the + # singleton class. + sample_lhs_real_class = C.rb_obj_class(sample_lhs) + + sample_instance_of = (sample_lhs_real_class == sample_rhs) + + side_exit = side_exit(jit, ctx) + asm.comment('Kernel#instance_of?') + asm.mov(:rax, to_value(sample_rhs)) + asm.cmp(ctx.stack_opnd(0), :rax) + asm.jne(counted_exit(side_exit, :send_instance_of_class_mismatch)) + + ctx.stack_pop(2) + + if sample_instance_of + stack_ret = ctx.stack_push(Type::True) + asm.mov(stack_ret, Qtrue) + else + stack_ret = ctx.stack_push(Type::False) + asm.mov(stack_ret, Qfalse) + end + return true; + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_obj_not(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 0 + recv_type = ctx.get_opnd_type(StackOpnd[0]) + + case recv_type.known_truthy + in false + asm.comment('rb_obj_not(nil_or_false)') + ctx.stack_pop(1) + out_opnd = ctx.stack_push(Type::True) + asm.mov(out_opnd, Qtrue) + in true + # Note: recv_type != Type::Nil && recv_type != Type::False. + asm.comment('rb_obj_not(truthy)') + ctx.stack_pop(1) + out_opnd = ctx.stack_push(Type::False) + asm.mov(out_opnd, Qfalse) + in nil + asm.comment('rb_obj_not') + + recv = ctx.stack_pop + # This `test` sets ZF only for Qnil and Qfalse, which let cmovz set. + asm.test(recv, ~Qnil) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.cmovz(:rax, :rcx) + + stack_ret = ctx.stack_push(Type::UnknownImm) + asm.mov(stack_ret, :rax) + end + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_obj_equal(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + asm.comment('equal?') + obj1 = ctx.stack_pop(1) + obj2 = ctx.stack_pop(1) + + asm.mov(:rax, obj1) + asm.mov(:rcx, obj2) + asm.cmp(:rax, :rcx) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.cmove(:rax, :rcx) + + stack_ret = ctx.stack_push(Type::UnknownImm) + asm.mov(stack_ret, :rax) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_obj_not_equal(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + jit_equality_specialized(jit, ctx, asm, false) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_mod_eqq(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + + asm.comment('Module#===') + # By being here, we know that the receiver is a T_MODULE or a T_CLASS, because Module#=== can + # only live on these objects. With that, we can call rb_obj_is_kind_of() without + # jit_prepare_routine_call() or a control frame push because it can't raise, allocate, or call + # Ruby methods with these inputs. + # Note the difference in approach from Kernel#is_a? because we don't get a free guard for the + # right hand side. + lhs = ctx.stack_opnd(1) # the module + rhs = ctx.stack_opnd(0) + asm.mov(C_ARGS[0], rhs); + asm.mov(C_ARGS[1], lhs); + asm.call(C.rb_obj_is_kind_of) + + # Return the result + ctx.stack_pop(2) + stack_ret = ctx.stack_push(Type::UnknownImm) + asm.mov(stack_ret, C_RET) + + return true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_int_equal(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + return false unless two_fixnums_on_stack?(jit) + + guard_two_fixnums(jit, ctx, asm) + + # Compare the arguments + asm.comment('rb_int_equal') + arg1 = ctx.stack_pop(1) + arg0 = ctx.stack_pop(1) + asm.mov(:rax, arg1) + asm.cmp(arg0, :rax) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.cmove(:rax, :rcx) + + stack_ret = ctx.stack_push(Type::UnknownImm) + asm.mov(stack_ret, :rax) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_int_mul(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + return false unless two_fixnums_on_stack?(jit) + + guard_two_fixnums(jit, ctx, asm) + + asm.comment('rb_int_mul') + y_opnd = ctx.stack_pop + x_opnd = ctx.stack_pop + asm.mov(C_ARGS[0], x_opnd) + asm.mov(C_ARGS[1], y_opnd) + asm.call(C.rb_fix_mul_fix) + + ret_opnd = ctx.stack_push(Type::Unknown) + asm.mov(ret_opnd, C_RET) + true + end + + def jit_rb_int_div(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + return false unless two_fixnums_on_stack?(jit) + + guard_two_fixnums(jit, ctx, asm) + + asm.comment('rb_int_div') + y_opnd = ctx.stack_pop + x_opnd = ctx.stack_pop + asm.mov(:rax, y_opnd) + asm.cmp(:rax, C.to_value(0)) + asm.je(side_exit(jit, ctx)) + + asm.mov(C_ARGS[0], x_opnd) + asm.mov(C_ARGS[1], :rax) + asm.call(C.rb_fix_div_fix) + + ret_opnd = ctx.stack_push(Type::Unknown) + asm.mov(ret_opnd, C_RET) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_int_aref(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + return false unless two_fixnums_on_stack?(jit) + + guard_two_fixnums(jit, ctx, asm) + + asm.comment('rb_int_aref') + y_opnd = ctx.stack_pop + x_opnd = ctx.stack_pop + + asm.mov(C_ARGS[0], x_opnd) + asm.mov(C_ARGS[1], y_opnd) + asm.call(C.rb_fix_aref) + + ret_opnd = ctx.stack_push(Type::UnknownImm) + asm.mov(ret_opnd, C_RET) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_str_empty_p(jit, ctx, asm, argc, known_recv_class) + recv_opnd = ctx.stack_pop(1) + out_opnd = ctx.stack_push(Type::UnknownImm) + + asm.comment('get string length') + asm.mov(:rax, recv_opnd) + str_len_opnd = [:rax, C.RString.offsetof(:len)] + + asm.cmp(str_len_opnd, 0) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.cmove(:rax, :rcx) + asm.mov(out_opnd, :rax) + + return true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_str_to_s(jit, ctx, asm, argc, known_recv_class) + return false if argc != 0 + if known_recv_class == String + asm.comment('to_s on plain string') + # The method returns the receiver, which is already on the stack. + # No stack movement. + return true + end + false + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_str_bytesize(jit, ctx, asm, argc, known_recv_class) + asm.comment('String#bytesize') + + recv = ctx.stack_pop(1) + asm.mov(C_ARGS[0], recv) + asm.call(C.rb_str_bytesize) + + out_opnd = ctx.stack_push(Type::Fixnum) + asm.mov(out_opnd, C_RET) + + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_str_concat(jit, ctx, asm, argc, known_recv_class) + # The << operator can accept integer codepoints for characters + # as the argument. We only specially optimise string arguments. + # If the peeked-at compile time argument is something other than + # a string, assume it won't be a string later either. + comptime_arg = jit.peek_at_stack(0) + unless C.RB_TYPE_P(comptime_arg, C::RUBY_T_STRING) + return false + end + + # Guard that the concat argument is a string + asm.mov(:rax, ctx.stack_opnd(0)) + guard_object_is_string(jit, ctx, asm, :rax, :rcx, StackOpnd[0]) + + # Guard buffers from GC since rb_str_buf_append may allocate. During the VM lock on GC, + # other Ractors may trigger global invalidation, so we need ctx.clear_local_types. + # PC is used on errors like Encoding::CompatibilityError raised by rb_str_buf_append. + jit_prepare_routine_call(jit, ctx, asm) + + concat_arg = ctx.stack_pop(1) + recv = ctx.stack_pop(1) + + # Test if string encodings differ. If different, use rb_str_append. If the same, + # use rb_yjit_str_simple_append, which calls rb_str_cat. + asm.comment('<< on strings') + + # Take receiver's object flags XOR arg's flags. If any + # string-encoding flags are different between the two, + # the encodings don't match. + recv_reg = :rax + asm.mov(recv_reg, recv) + concat_arg_reg = :rcx + asm.mov(concat_arg_reg, concat_arg) + asm.mov(recv_reg, [recv_reg, C.RBasic.offsetof(:flags)]) + asm.mov(concat_arg_reg, [concat_arg_reg, C.RBasic.offsetof(:flags)]) + asm.xor(recv_reg, concat_arg_reg) + asm.test(recv_reg, C::RUBY_ENCODING_MASK) + + # Push once, use the resulting operand in both branches below. + stack_ret = ctx.stack_push(Type::TString) + + enc_mismatch = asm.new_label('enc_mismatch') + asm.jnz(enc_mismatch) + + # If encodings match, call the simple append function and jump to return + asm.mov(C_ARGS[0], recv) + asm.mov(C_ARGS[1], concat_arg) + asm.call(C.rjit_str_simple_append) + ret_label = asm.new_label('func_return') + asm.mov(stack_ret, C_RET) + asm.jmp(ret_label) + + # If encodings are different, use a slower encoding-aware concatenate + asm.write_label(enc_mismatch) + asm.mov(C_ARGS[0], recv) + asm.mov(C_ARGS[1], concat_arg) + asm.call(C.rb_str_buf_append) + asm.mov(stack_ret, C_RET) + # Drop through to return + + asm.write_label(ret_label) + + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_str_uplus(jit, ctx, asm, argc, _known_recv_class) + if argc != 0 + return false + end + + # We allocate when we dup the string + jit_prepare_routine_call(jit, ctx, asm) + + asm.comment('Unary plus on string') + asm.mov(:rax, ctx.stack_pop(1)) # recv_opnd + asm.mov(:rcx, [:rax, C.RBasic.offsetof(:flags)]) # flags_opnd + asm.test(:rcx, C::RUBY_FL_FREEZE) + + ret_label = asm.new_label('stack_ret') + + # String#+@ can only exist on T_STRING + stack_ret = ctx.stack_push(Type::TString) + + # If the string isn't frozen, we just return it. + asm.mov(stack_ret, :rax) # recv_opnd + asm.jz(ret_label) + + # Str is frozen - duplicate it + asm.mov(C_ARGS[0], :rax) # recv_opnd + asm.call(C.rb_str_dup) + asm.mov(stack_ret, C_RET) + + asm.write_label(ret_label) + + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_str_getbyte(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + asm.comment('rb_str_getbyte') + + index_opnd = ctx.stack_pop + str_opnd = ctx.stack_pop + asm.mov(C_ARGS[0], str_opnd) + asm.mov(C_ARGS[1], index_opnd) + asm.call(C.rb_str_getbyte) + + ret_opnd = ctx.stack_push(Type::Fixnum) + asm.mov(ret_opnd, C_RET) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_ary_empty_p(jit, ctx, asm, argc, _known_recv_class) + array_reg = :rax + asm.mov(array_reg, ctx.stack_pop(1)) + jit_array_len(asm, array_reg, :rcx) + + asm.test(:rcx, :rcx) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.cmovz(:rax, :rcx) + + out_opnd = ctx.stack_push(Type::UnknownImm) + asm.mov(out_opnd, :rax) + + return true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_ary_push(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 1 + asm.comment('rb_ary_push') + + jit_prepare_routine_call(jit, ctx, asm) + + item_opnd = ctx.stack_pop + ary_opnd = ctx.stack_pop + asm.mov(C_ARGS[0], ary_opnd) + asm.mov(C_ARGS[1], item_opnd) + asm.call(C.rb_ary_push) + + ret_opnd = ctx.stack_push(Type::TArray) + asm.mov(ret_opnd, C_RET) + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_obj_respond_to(jit, ctx, asm, argc, known_recv_class) + # respond_to(:sym) or respond_to(:sym, true) + if argc != 1 && argc != 2 + return false + end + + if known_recv_class.nil? + return false + end + + recv_class = known_recv_class + + # Get the method_id from compile time. We will later add a guard against it. + mid_sym = jit.peek_at_stack(argc - 1) + unless static_symbol?(mid_sym) + return false + end + mid = C.rb_sym2id(mid_sym) + + # This represents the value of the "include_all" argument and whether it's known + allow_priv = if argc == 1 + # Default is false + false + else + # Get value from type information (may or may not be known) + ctx.get_opnd_type(StackOpnd[0]).known_truthy + end + + target_cme = C.rb_callable_method_entry_or_negative(recv_class, mid) + + # Should never be null, as in that case we will be returned a "negative CME" + assert_equal(false, target_cme.nil?) + + cme_def_type = C.UNDEFINED_METHOD_ENTRY_P(target_cme) ? C::VM_METHOD_TYPE_UNDEF : target_cme.def.type + + if cme_def_type == C::VM_METHOD_TYPE_REFINED + return false + end + + visibility = if cme_def_type == C::VM_METHOD_TYPE_UNDEF + C::METHOD_VISI_UNDEF + else + C.METHOD_ENTRY_VISI(target_cme) + end + + result = + case [visibility, allow_priv] + in C::METHOD_VISI_UNDEF, _ then Qfalse # No method => false + in C::METHOD_VISI_PUBLIC, _ then Qtrue # Public method => true regardless of include_all + in _, true then Qtrue # include_all => always true + else return false # not public and include_all not known, can't compile + end + + if result != Qtrue + # Only if respond_to_missing? hasn't been overridden + # In the future, we might want to jit the call to respond_to_missing? + unless Invariants.assume_method_basic_definition(jit, recv_class, C.idRespond_to_missing) + return false + end + end + + # Invalidate this block if method lookup changes for the method being queried. This works + # both for the case where a method does or does not exist, as for the latter we asked for a + # "negative CME" earlier. + Invariants.assume_method_lookup_stable(jit, target_cme) + + # Generate a side exit + side_exit = side_exit(jit, ctx) + + if argc == 2 + # pop include_all argument (we only use its type info) + ctx.stack_pop(1) + end + + sym_opnd = ctx.stack_pop(1) + _recv_opnd = ctx.stack_pop(1) + + # This is necessary because we have no guarantee that sym_opnd is a constant + asm.comment('guard known mid') + asm.mov(:rax, to_value(mid_sym)) + asm.cmp(sym_opnd, :rax) + asm.jne(side_exit) + + putobject(jit, ctx, asm, val: result) + + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_rb_f_block_given_p(jit, ctx, asm, argc, _known_recv_class) + asm.comment('block_given?') + + # Same as rb_vm_frame_block_handler + jit_get_lep(jit, asm, reg: :rax) + asm.mov(:rax, [:rax, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) # block_handler + + ctx.stack_pop(1) + out_opnd = ctx.stack_push(Type::UnknownImm) + + # Return `block_handler != VM_BLOCK_HANDLER_NONE` + asm.cmp(:rax, C::VM_BLOCK_HANDLER_NONE) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.cmovne(:rax, :rcx) # block_given + asm.mov(out_opnd, :rax) + + true + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_thread_s_current(jit, ctx, asm, argc, _known_recv_class) + return false if argc != 0 + asm.comment('Thread.current') + ctx.stack_pop(1) + + # ec->thread_ptr + asm.mov(:rax, [EC, C.rb_execution_context_t.offsetof(:thread_ptr)]) + + # thread->self + asm.mov(:rax, [:rax, C.rb_thread_struct.offsetof(:self)]) + + stack_ret = ctx.stack_push(Type::UnknownHeap) + asm.mov(stack_ret, :rax) + true + end + + # + # Helpers + # + + def register_cfunc_codegen_funcs + # Specialization for C methods. See register_cfunc_method for details. + register_cfunc_method(BasicObject, :!, :jit_rb_obj_not) + + register_cfunc_method(NilClass, :nil?, :jit_rb_true) + register_cfunc_method(Kernel, :nil?, :jit_rb_false) + register_cfunc_method(Kernel, :is_a?, :jit_rb_kernel_is_a) + register_cfunc_method(Kernel, :kind_of?, :jit_rb_kernel_is_a) + register_cfunc_method(Kernel, :instance_of?, :jit_rb_kernel_instance_of) + + register_cfunc_method(BasicObject, :==, :jit_rb_obj_equal) + register_cfunc_method(BasicObject, :equal?, :jit_rb_obj_equal) + register_cfunc_method(BasicObject, :!=, :jit_rb_obj_not_equal) + register_cfunc_method(Kernel, :eql?, :jit_rb_obj_equal) + register_cfunc_method(Module, :==, :jit_rb_obj_equal) + register_cfunc_method(Module, :===, :jit_rb_mod_eqq) + register_cfunc_method(Symbol, :==, :jit_rb_obj_equal) + register_cfunc_method(Symbol, :===, :jit_rb_obj_equal) + register_cfunc_method(Integer, :==, :jit_rb_int_equal) + register_cfunc_method(Integer, :===, :jit_rb_int_equal) + + # rb_str_to_s() methods in string.c + register_cfunc_method(String, :empty?, :jit_rb_str_empty_p) + register_cfunc_method(String, :to_s, :jit_rb_str_to_s) + register_cfunc_method(String, :to_str, :jit_rb_str_to_s) + register_cfunc_method(String, :bytesize, :jit_rb_str_bytesize) + register_cfunc_method(String, :<<, :jit_rb_str_concat) + register_cfunc_method(String, :+@, :jit_rb_str_uplus) + + # rb_ary_empty_p() method in array.c + register_cfunc_method(Array, :empty?, :jit_rb_ary_empty_p) + + register_cfunc_method(Kernel, :respond_to?, :jit_obj_respond_to) + register_cfunc_method(Kernel, :block_given?, :jit_rb_f_block_given_p) + + # Thread.current + register_cfunc_method(C.rb_singleton_class(Thread), :current, :jit_thread_s_current) + + #--- + register_cfunc_method(Array, :<<, :jit_rb_ary_push) + register_cfunc_method(Integer, :*, :jit_rb_int_mul) + register_cfunc_method(Integer, :/, :jit_rb_int_div) + register_cfunc_method(Integer, :[], :jit_rb_int_aref) + register_cfunc_method(String, :getbyte, :jit_rb_str_getbyte) + end + + def register_cfunc_method(klass, mid_sym, func) + mid = C.rb_intern(mid_sym.to_s) + me = C.rb_method_entry_at(klass, mid) + + assert_equal(false, me.nil?) + + # Only cfuncs are supported + method_serial = me.def.method_serial + + @cfunc_codegen_table[method_serial] = method(func) + end + + def lookup_cfunc_codegen(cme_def) + @cfunc_codegen_table[cme_def.method_serial] + end + + def stack_swap(_jit, ctx, asm, offset0, offset1) + stack0_mem = ctx.stack_opnd(offset0) + stack1_mem = ctx.stack_opnd(offset1) + + mapping0 = ctx.get_opnd_mapping(StackOpnd[offset0]) + mapping1 = ctx.get_opnd_mapping(StackOpnd[offset1]) + + asm.mov(:rax, stack0_mem) + asm.mov(:rcx, stack1_mem) + asm.mov(stack0_mem, :rcx) + asm.mov(stack1_mem, :rax) + + ctx.set_opnd_mapping(StackOpnd[offset0], mapping1) + ctx.set_opnd_mapping(StackOpnd[offset1], mapping0) + end + + def jit_getlocal_generic(jit, ctx, asm, idx:, level:) + # Load environment pointer EP (level 0) from CFP + ep_reg = :rax + jit_get_ep(asm, level, reg: ep_reg) + + # Load the local from the block + # val = *(vm_get_ep(GET_EP(), level) - idx); + asm.mov(:rax, [ep_reg, -idx * C.VALUE.size]) + + # Write the local at SP + stack_top = if level == 0 + local_idx = ep_offset_to_local_idx(jit.iseq, idx) + ctx.stack_push_local(local_idx) + else + ctx.stack_push(Type::Unknown) + end + + asm.mov(stack_top, :rax) + KeepCompiling + end + + def jit_setlocal_generic(jit, ctx, asm, idx:, level:) + value_type = ctx.get_opnd_type(StackOpnd[0]) + + # Load environment pointer EP at level + ep_reg = :rax + jit_get_ep(asm, level, reg: ep_reg) + + # Write barriers may be required when VM_ENV_FLAG_WB_REQUIRED is set, however write barriers + # only affect heap objects being written. If we know an immediate value is being written we + # can skip this check. + unless value_type.imm? + # flags & VM_ENV_FLAG_WB_REQUIRED + flags_opnd = [ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_FLAGS] + asm.test(flags_opnd, C::VM_ENV_FLAG_WB_REQUIRED) + + # if (flags & VM_ENV_FLAG_WB_REQUIRED) != 0 + asm.jnz(side_exit(jit, ctx)) + end + + if level == 0 + local_idx = ep_offset_to_local_idx(jit.iseq, idx) + ctx.set_local_type(local_idx, value_type) + end + + # Pop the value to write from the stack + stack_top = ctx.stack_pop(1) + + # Write the value at the environment pointer + asm.mov(:rcx, stack_top) + asm.mov([ep_reg, -(C.VALUE.size * idx)], :rcx) + + KeepCompiling + end + + # Compute the index of a local variable from its slot index + def ep_offset_to_local_idx(iseq, ep_offset) + # Layout illustration + # This is an array of VALUE + # | VM_ENV_DATA_SIZE | + # v v + # low addr <+-------+-------+-------+-------+------------------+ + # |local 0|local 1| ... |local n| .... | + # +-------+-------+-------+-------+------------------+ + # ^ ^ ^ ^ + # +-------+---local_table_size----+ cfp->ep--+ + # | | + # +------------------ep_offset---------------+ + # + # See usages of local_var_name() from iseq.c for similar calculation. + + # Equivalent of iseq->body->local_table_size + local_table_size = iseq.body.local_table_size + op = ep_offset - C::VM_ENV_DATA_SIZE + local_idx = local_table_size - op - 1 + assert_equal(true, local_idx >= 0 && local_idx < local_table_size) + local_idx + end + + # Compute the index of a local variable from its slot index + def slot_to_local_idx(iseq, slot_idx) + # Layout illustration + # This is an array of VALUE + # | VM_ENV_DATA_SIZE | + # v v + # low addr <+-------+-------+-------+-------+------------------+ + # |local 0|local 1| ... |local n| .... | + # +-------+-------+-------+-------+------------------+ + # ^ ^ ^ ^ + # +-------+---local_table_size----+ cfp->ep--+ + # | | + # +------------------slot_idx----------------+ + # + # See usages of local_var_name() from iseq.c for similar calculation. + + local_table_size = iseq.body.local_table_size + op = slot_idx - C::VM_ENV_DATA_SIZE + local_table_size - op - 1 + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def guard_object_is_heap(jit, ctx, asm, object, object_opnd, counter = nil) + object_type = ctx.get_opnd_type(object_opnd) + if object_type.heap? + return + end + + side_exit = side_exit(jit, ctx) + side_exit = counted_exit(side_exit, counter) if counter + + asm.comment('guard object is heap') + # Test that the object is not an immediate + asm.test(object, C::RUBY_IMMEDIATE_MASK) + asm.jnz(side_exit) + + # Test that the object is not false + asm.cmp(object, Qfalse) + asm.je(side_exit) + + if object_type.diff(Type::UnknownHeap) != TypeDiff::Incompatible + ctx.upgrade_opnd_type(object_opnd, Type::UnknownHeap) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def guard_object_is_array(jit, ctx, asm, object_reg, flags_reg, object_opnd, counter = nil) + object_type = ctx.get_opnd_type(object_opnd) + if object_type.array? + return + end + + guard_object_is_heap(jit, ctx, asm, object_reg, object_opnd, counter) + + side_exit = side_exit(jit, ctx) + side_exit = counted_exit(side_exit, counter) if counter + + asm.comment('guard object is array') + # Pull out the type mask + asm.mov(flags_reg, [object_reg, C.RBasic.offsetof(:flags)]) + asm.and(flags_reg, C::RUBY_T_MASK) + + # Compare the result with T_ARRAY + asm.cmp(flags_reg, C::RUBY_T_ARRAY) + asm.jne(side_exit) + + if object_type.diff(Type::TArray) != TypeDiff::Incompatible + ctx.upgrade_opnd_type(object_opnd, Type::TArray) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def guard_object_is_string(jit, ctx, asm, object_reg, flags_reg, object_opnd, counter = nil) + object_type = ctx.get_opnd_type(object_opnd) + if object_type.string? + return + end + + guard_object_is_heap(jit, ctx, asm, object_reg, object_opnd, counter) + + side_exit = side_exit(jit, ctx) + side_exit = counted_exit(side_exit, counter) if counter + + asm.comment('guard object is string') + # Pull out the type mask + asm.mov(flags_reg, [object_reg, C.RBasic.offsetof(:flags)]) + asm.and(flags_reg, C::RUBY_T_MASK) + + # Compare the result with T_STRING + asm.cmp(flags_reg, C::RUBY_T_STRING) + asm.jne(side_exit) + + if object_type.diff(Type::TString) != TypeDiff::Incompatible + ctx.upgrade_opnd_type(object_opnd, Type::TString) + end + end + + # clobbers object_reg + def guard_object_is_not_ruby2_keyword_hash(asm, object_reg, flags_reg, side_exit) + asm.comment('guard object is not ruby2 keyword hash') + + not_ruby2_keyword = asm.new_label('not_ruby2_keyword') + asm.test(object_reg, C::RUBY_IMMEDIATE_MASK) + asm.jnz(not_ruby2_keyword) + + asm.cmp(object_reg, Qfalse) + asm.je(not_ruby2_keyword) + + asm.mov(flags_reg, [object_reg, C.RBasic.offsetof(:flags)]) + type_reg = object_reg + asm.mov(type_reg, flags_reg) + asm.and(type_reg, C::RUBY_T_MASK) + + asm.cmp(type_reg, C::RUBY_T_HASH) + asm.jne(not_ruby2_keyword) + + asm.test(flags_reg, C::RHASH_PASS_AS_KEYWORDS) + asm.jnz(side_exit) + + asm.write_label(not_ruby2_keyword) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_chain_guard(opcode, jit, ctx, asm, side_exit, limit: 20) + opcode => :je | :jne | :jnz | :jz + + if ctx.chain_depth < limit + deeper = ctx.dup + deeper.chain_depth += 1 + + branch_stub = BranchStub.new( + iseq: jit.iseq, + shape: Default, + target0: BranchTarget.new(ctx: deeper, pc: jit.pc), + ) + branch_stub.target0.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(deeper, ocb_asm, branch_stub, true) + @ocb.write(ocb_asm) + end + branch_stub.compile = compile_jit_chain_guard(branch_stub, opcode:) + branch_stub.compile.call(asm) + else + asm.public_send(opcode, side_exit) + end + end + + def compile_jit_chain_guard(branch_stub, opcode:) # Proc escapes arguments in memory + proc do |branch_asm| + # Not using `asm.comment` here since it's usually put before cmp/test before this. + branch_asm.stub(branch_stub) do + case branch_stub.shape + in Default + branch_asm.public_send(opcode, branch_stub.target0.address) + end + end + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_guard_known_klass(jit, ctx, asm, known_klass, obj_opnd, insn_opnd, comptime_obj, side_exit, limit: 10) + # Only memory operand is supported for now + assert_equal(true, obj_opnd.is_a?(Array)) + + known_klass = C.to_value(known_klass) + val_type = ctx.get_opnd_type(insn_opnd) + if val_type.known_class == known_klass + # We already know from type information that this is a match + return + end + + # Touching this as Ruby could crash for FrozenCore + if known_klass == C.rb_cNilClass + assert(!val_type.heap?) + assert(val_type.unknown?) + + asm.comment('guard object is nil') + asm.cmp(obj_opnd, Qnil) + jit_chain_guard(:jne, jit, ctx, asm, side_exit, limit:) + + ctx.upgrade_opnd_type(insn_opnd, Type::Nil) + elsif known_klass == C.rb_cTrueClass + assert(!val_type.heap?) + assert(val_type.unknown?) + + asm.comment('guard object is true') + asm.cmp(obj_opnd, Qtrue) + jit_chain_guard(:jne, jit, ctx, asm, side_exit, limit:) + + ctx.upgrade_opnd_type(insn_opnd, Type::True) + elsif known_klass == C.rb_cFalseClass + assert(!val_type.heap?) + assert(val_type.unknown?) + + asm.comment('guard object is false') + asm.cmp(obj_opnd, Qfalse) + jit_chain_guard(:jne, jit, ctx, asm, side_exit, limit:) + + ctx.upgrade_opnd_type(insn_opnd, Type::False) + elsif known_klass == C.rb_cInteger && fixnum?(comptime_obj) + # We will guard fixnum and bignum as though they were separate classes + # BIGNUM can be handled by the general else case below + assert(val_type.unknown?) + + asm.comment('guard object is fixnum') + asm.test(obj_opnd, C::RUBY_FIXNUM_FLAG) + jit_chain_guard(:jz, jit, ctx, asm, side_exit, limit:) + + ctx.upgrade_opnd_type(insn_opnd, Type::Fixnum) + elsif known_klass == C.rb_cSymbol && static_symbol?(comptime_obj) + assert(!val_type.heap?) + # We will guard STATIC vs DYNAMIC as though they were separate classes + # DYNAMIC symbols can be handled by the general else case below + if val_type != Type::ImmSymbol || !val_type.imm? + assert(val_type.unknown?) + + asm.comment('guard object is static symbol') + assert_equal(8, C::RUBY_SPECIAL_SHIFT) + asm.cmp(BytePtr[*obj_opnd], C::RUBY_SYMBOL_FLAG) + jit_chain_guard(:jne, jit, ctx, asm, side_exit, limit:) + + ctx.upgrade_opnd_type(insn_opnd, Type::ImmSymbol) + end + elsif known_klass == C.rb_cFloat && flonum?(comptime_obj) + assert(!val_type.heap?) + if val_type != Type::Flonum || !val_type.imm? + assert(val_type.unknown?) + + # We will guard flonum vs heap float as though they were separate classes + asm.comment('guard object is flonum') + asm.mov(:rax, obj_opnd) + asm.and(:rax, C::RUBY_FLONUM_MASK) + asm.cmp(:rax, C::RUBY_FLONUM_FLAG) + jit_chain_guard(:jne, jit, ctx, asm, side_exit, limit:) + + ctx.upgrade_opnd_type(insn_opnd, Type::Flonum) + end + elsif C.RCLASS_SINGLETON_P(known_klass) && comptime_obj == C.rb_class_attached_object(known_klass) + # Singleton classes are attached to one specific object, so we can + # avoid one memory access (and potentially the is_heap check) by + # looking for the expected object directly. + # Note that in case the sample instance has a singleton class that + # doesn't attach to the sample instance, it means the sample instance + # has an empty singleton class that hasn't been materialized yet. In + # this case, comparing against the sample instance doesn't guarantee + # that its singleton class is empty, so we can't avoid the memory + # access. As an example, `Object.new.singleton_class` is an object in + # this situation. + asm.comment('guard known object with singleton class') + asm.mov(:rax, to_value(comptime_obj)) + asm.cmp(obj_opnd, :rax) + jit_chain_guard(:jne, jit, ctx, asm, side_exit, limit:) + elsif val_type == Type::CString && known_klass == C.rb_cString + # guard elided because the context says we've already checked + assert_equal(C.to_value(C.rb_class_of(comptime_obj)), C.rb_cString) + else + assert(!val_type.imm?) + + # Load memory to a register + asm.mov(:rax, obj_opnd) + obj_opnd = :rax + + # Check that the receiver is a heap object + # Note: if we get here, the class doesn't have immediate instances. + unless val_type.heap? + asm.comment('guard not immediate') + asm.test(obj_opnd, C::RUBY_IMMEDIATE_MASK) + jit_chain_guard(:jnz, jit, ctx, asm, side_exit, limit:) + asm.cmp(obj_opnd, Qfalse) + jit_chain_guard(:je, jit, ctx, asm, side_exit, limit:) + end + + # Bail if receiver class is different from known_klass + klass_opnd = [obj_opnd, C.RBasic.offsetof(:klass)] + asm.comment("guard known class #{known_klass}") + asm.mov(:rcx, known_klass) + asm.cmp(klass_opnd, :rcx) + jit_chain_guard(:jne, jit, ctx, asm, side_exit, limit:) + + if known_klass == C.rb_cString + # Upgrading to Type::CString here is incorrect. + # The guard we put only checks RBASIC_CLASS(obj), + # which adding a singleton class can change. We + # additionally need to know the string is frozen + # to claim Type::CString. + ctx.upgrade_opnd_type(insn_opnd, Type::TString) + elsif known_klass == C.rb_cArray + ctx.upgrade_opnd_type(insn_opnd, Type::TArray) + end + end + end + + # @param jit [RubyVM::RJIT::JITState] + def two_fixnums_on_stack?(jit) + comptime_recv = jit.peek_at_stack(1) + comptime_arg = jit.peek_at_stack(0) + return fixnum?(comptime_recv) && fixnum?(comptime_arg) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def guard_two_fixnums(jit, ctx, asm) + # Get stack operands without popping them + arg1 = ctx.stack_opnd(0) + arg0 = ctx.stack_opnd(1) + + # Get the stack operand types + arg1_type = ctx.get_opnd_type(StackOpnd[0]) + arg0_type = ctx.get_opnd_type(StackOpnd[1]) + + if arg0_type.heap? || arg1_type.heap? + asm.comment('arg is heap object') + asm.jmp(side_exit(jit, ctx)) + return + end + + if arg0_type != Type::Fixnum && arg0_type.specific? + asm.comment('arg0 not fixnum') + asm.jmp(side_exit(jit, ctx)) + return + end + + if arg1_type != Type::Fixnum && arg1_type.specific? + asm.comment('arg1 not fixnum') + asm.jmp(side_exit(jit, ctx)) + return + end + + assert(!arg0_type.heap?) + assert(!arg1_type.heap?) + assert(arg0_type == Type::Fixnum || arg0_type.unknown?) + assert(arg1_type == Type::Fixnum || arg1_type.unknown?) + + # If not fixnums at run-time, fall back + if arg0_type != Type::Fixnum + asm.comment('guard arg0 fixnum') + asm.test(arg0, C::RUBY_FIXNUM_FLAG) + jit_chain_guard(:jz, jit, ctx, asm, side_exit(jit, ctx)) + end + if arg1_type != Type::Fixnum + asm.comment('guard arg1 fixnum') + asm.test(arg1, C::RUBY_FIXNUM_FLAG) + jit_chain_guard(:jz, jit, ctx, asm, side_exit(jit, ctx)) + end + + # Set stack types in context + ctx.upgrade_opnd_type(StackOpnd[0], Type::Fixnum) + ctx.upgrade_opnd_type(StackOpnd[1], Type::Fixnum) + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_fixnum_cmp(jit, ctx, asm, opcode:, bop:) + opcode => :cmovl | :cmovle | :cmovg | :cmovge + + unless jit.at_current_insn? + defer_compilation(jit, ctx, asm) + return EndBlock + end + + comptime_recv = jit.peek_at_stack(1) + comptime_obj = jit.peek_at_stack(0) + + if fixnum?(comptime_recv) && fixnum?(comptime_obj) + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, bop) + return CantCompile + end + + # Check that both operands are fixnums + guard_two_fixnums(jit, ctx, asm) + + obj_opnd = ctx.stack_pop + recv_opnd = ctx.stack_pop + + asm.mov(:rax, obj_opnd) + asm.cmp(recv_opnd, :rax) + asm.mov(:rax, Qfalse) + asm.mov(:rcx, Qtrue) + asm.public_send(opcode, :rax, :rcx) + + dst_opnd = ctx.stack_push(Type::UnknownImm) + asm.mov(dst_opnd, :rax) + + KeepCompiling + else + opt_send_without_block(jit, ctx, asm) + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_equality_specialized(jit, ctx, asm, gen_eq) + # Create a side-exit to fall back to the interpreter + side_exit = side_exit(jit, ctx) + + a_opnd = ctx.stack_opnd(1) + b_opnd = ctx.stack_opnd(0) + + comptime_a = jit.peek_at_stack(1) + comptime_b = jit.peek_at_stack(0) + + if two_fixnums_on_stack?(jit) + unless Invariants.assume_bop_not_redefined(jit, C::INTEGER_REDEFINED_OP_FLAG, C::BOP_EQ) + return false + end + + guard_two_fixnums(jit, ctx, asm) + + asm.comment('check fixnum equality') + asm.mov(:rax, a_opnd) + asm.mov(:rcx, b_opnd) + asm.cmp(:rax, :rcx) + asm.mov(:rax, gen_eq ? Qfalse : Qtrue) + asm.mov(:rcx, gen_eq ? Qtrue : Qfalse) + asm.cmove(:rax, :rcx) + + # Push the output on the stack + ctx.stack_pop(2) + dst = ctx.stack_push(Type::UnknownImm) + asm.mov(dst, :rax) + + true + elsif C.rb_class_of(comptime_a) == String && C.rb_class_of(comptime_b) == String + unless Invariants.assume_bop_not_redefined(jit, C::STRING_REDEFINED_OP_FLAG, C::BOP_EQ) + # if overridden, emit the generic version + return false + end + + # Guard that a is a String + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_a), a_opnd, StackOpnd[1], comptime_a, side_exit) + + equal_label = asm.new_label(:equal) + ret_label = asm.new_label(:ret) + + # If they are equal by identity, return true + asm.mov(:rax, a_opnd) + asm.mov(:rcx, b_opnd) + asm.cmp(:rax, :rcx) + asm.je(equal_label) + + # Otherwise guard that b is a T_STRING (from type info) or String (from runtime guard) + btype = ctx.get_opnd_type(StackOpnd[0]) + unless btype.string? + # Note: any T_STRING is valid here, but we check for a ::String for simplicity + # To pass a mutable static variable (rb_cString) requires an unsafe block + jit_guard_known_klass(jit, ctx, asm, C.rb_class_of(comptime_b), b_opnd, StackOpnd[0], comptime_b, side_exit) + end + + asm.comment('call rb_str_eql_internal') + asm.mov(C_ARGS[0], a_opnd) + asm.mov(C_ARGS[1], b_opnd) + asm.call(gen_eq ? C.rb_str_eql_internal : C.rjit_str_neq_internal) + + # Push the output on the stack + ctx.stack_pop(2) + dst = ctx.stack_push(Type::UnknownImm) + asm.mov(dst, C_RET) + asm.jmp(ret_label) + + asm.write_label(equal_label) + asm.mov(dst, gen_eq ? Qtrue : Qfalse) + + asm.write_label(ret_label) + + true + else + false + end + end + + # NOTE: This clobbers :rax + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_prepare_routine_call(jit, ctx, asm) + jit.record_boundary_patch_point = true + jit_save_pc(jit, asm) + jit_save_sp(ctx, asm) + + # In case the routine calls Ruby methods, it can set local variables + # through Kernel#binding and other means. + ctx.clear_local_types + end + + # NOTE: This clobbers :rax + # @param jit [RubyVM::RJIT::JITState] + # @param asm [RubyVM::RJIT::Assembler] + def jit_save_pc(jit, asm, comment: 'save PC to CFP') + next_pc = jit.pc + jit.insn.len * C.VALUE.size # Use the next one for backtrace and side exits + asm.comment(comment) + asm.mov(:rax, next_pc) + asm.mov([CFP, C.rb_control_frame_t.offsetof(:pc)], :rax) + end + + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_save_sp(ctx, asm) + if ctx.sp_offset != 0 + asm.comment('save SP to CFP') + asm.lea(SP, ctx.sp_opnd) + asm.mov([CFP, C.rb_control_frame_t.offsetof(:sp)], SP) + ctx.sp_offset = 0 + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jump_to_next_insn(jit, ctx, asm) + reset_depth = ctx.dup + reset_depth.chain_depth = 0 + + next_pc = jit.pc + jit.insn.len * C.VALUE.size + + # We are at the end of the current instruction. Record the boundary. + if jit.record_boundary_patch_point + exit_pos = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_side_exit(next_pc, ctx, ocb_asm) + @ocb.write(ocb_asm) + end + Invariants.record_global_inval_patch(asm, exit_pos) + jit.record_boundary_patch_point = false + end + + jit_direct_jump(jit.iseq, next_pc, reset_depth, asm, comment: 'jump_to_next_insn') + end + + # rb_vm_check_ints + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_check_ints(jit, ctx, asm) + asm.comment('RUBY_VM_CHECK_INTS(ec)') + asm.mov(:eax, DwordPtr[EC, C.rb_execution_context_t.offsetof(:interrupt_flag)]) + asm.test(:eax, :eax) + asm.jnz(side_exit(jit, ctx)) + end + + # See get_lvar_level in compile.c + def get_lvar_level(iseq) + level = 0 + while iseq.to_i != iseq.body.local_iseq.to_i + level += 1 + iseq = iseq.body.parent_iseq + end + return level + end + + # GET_LEP + # @param jit [RubyVM::RJIT::JITState] + # @param asm [RubyVM::RJIT::Assembler] + def jit_get_lep(jit, asm, reg:) + level = get_lvar_level(jit.iseq) + jit_get_ep(asm, level, reg:) + end + + # vm_get_ep + # @param asm [RubyVM::RJIT::Assembler] + def jit_get_ep(asm, level, reg:) + asm.mov(reg, [CFP, C.rb_control_frame_t.offsetof(:ep)]) + level.times do + # GET_PREV_EP: ep[VM_ENV_DATA_INDEX_SPECVAL] & ~0x03 + asm.mov(reg, [reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) + asm.and(reg, ~0x03) + end + end + + # vm_getivar + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_getivar(jit, ctx, asm, comptime_obj, ivar_id, obj_opnd, obj_yarv_opnd) + side_exit = side_exit(jit, ctx) + starting_ctx = ctx.dup # copy for jit_chain_guard + + # Guard not special const + if C::SPECIAL_CONST_P(comptime_obj) + asm.incr_counter(:getivar_special_const) + return CantCompile + end + + case C::BUILTIN_TYPE(comptime_obj) + when C::T_OBJECT + # This is the only supported case for now (ROBJECT_IVPTR) + else + # General case. Call rb_ivar_get(). + # VALUE rb_ivar_get(VALUE obj, ID id) + asm.comment('call rb_ivar_get()') + asm.mov(C_ARGS[0], obj_opnd ? obj_opnd : [CFP, C.rb_control_frame_t.offsetof(:self)]) + asm.mov(C_ARGS[1], ivar_id) + + # The function could raise exceptions. + jit_prepare_routine_call(jit, ctx, asm) # clobbers obj_opnd and :rax + + asm.call(C.rb_ivar_get) + + if obj_opnd # attr_reader + ctx.stack_pop + end + + # Push the ivar on the stack + out_opnd = ctx.stack_push(Type::Unknown) + asm.mov(out_opnd, C_RET) + + # Jump to next instruction. This allows guard chains to share the same successor. + jump_to_next_insn(jit, ctx, asm) + return EndBlock + end + + asm.mov(:rax, obj_opnd ? obj_opnd : [CFP, C.rb_control_frame_t.offsetof(:self)]) + guard_object_is_heap(jit, ctx, asm, :rax, obj_yarv_opnd, :getivar_not_heap) + + shape_id = C.rb_shape_get_shape_id(comptime_obj) + if shape_id == C::OBJ_TOO_COMPLEX_SHAPE_ID + asm.incr_counter(:getivar_too_complex) + return CantCompile + end + + asm.comment('guard shape') + asm.cmp(DwordPtr[:rax, C.rb_shape_id_offset], shape_id) + jit_chain_guard(:jne, jit, starting_ctx, asm, counted_exit(side_exit, :getivar_megamorphic)) + + if obj_opnd + ctx.stack_pop # pop receiver for attr_reader + end + + index = C.rb_shape_get_iv_index(shape_id, ivar_id) + # If there is no IVAR index, then the ivar was undefined + # when we entered the compiler. That means we can just return + # nil for this shape + iv name + if index.nil? + stack_opnd = ctx.stack_push(Type::Nil) + val_opnd = Qnil + else + asm.comment('ROBJECT_IVPTR') + if C::FL_TEST_RAW(comptime_obj, C::ROBJECT_EMBED) + # Access embedded array + asm.mov(:rax, [:rax, C.RObject.offsetof(:as, :ary) + (index * C.VALUE.size)]) + else + # Pull out an ivar table on heap + asm.mov(:rax, [:rax, C.RObject.offsetof(:as, :heap, :ivptr)]) + # Read the table + asm.mov(:rax, [:rax, index * C.VALUE.size]) + end + stack_opnd = ctx.stack_push(Type::Unknown) + val_opnd = :rax + end + asm.mov(stack_opnd, val_opnd) + + # Let guard chains share the same successor + jump_to_next_insn(jit, ctx, asm) + EndBlock + end + + def jit_write_iv(asm, comptime_receiver, recv_reg, temp_reg, ivar_index, set_value, needs_extension) + # Compile time self is embedded and the ivar index lands within the object + embed_test_result = C::FL_TEST_RAW(comptime_receiver, C::ROBJECT_EMBED) && !needs_extension + + if embed_test_result + # Find the IV offset + offs = C.RObject.offsetof(:as, :ary) + ivar_index * C.VALUE.size + + # Write the IV + asm.comment('write IV') + asm.mov(temp_reg, set_value) + asm.mov([recv_reg, offs], temp_reg) + else + # Compile time value is *not* embedded. + + # Get a pointer to the extended table + asm.mov(recv_reg, [recv_reg, C.RObject.offsetof(:as, :heap, :ivptr)]) + + # Write the ivar in to the extended table + asm.comment("write IV"); + asm.mov(temp_reg, set_value) + asm.mov([recv_reg, C.VALUE.size * ivar_index], temp_reg) + end + end + + # vm_caller_setup_arg_block: Handle VM_CALL_ARGS_BLOCKARG cases. + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def guard_block_arg(jit, ctx, asm, calling) + if calling.flags & C::VM_CALL_ARGS_BLOCKARG != 0 + block_arg_type = ctx.get_opnd_type(StackOpnd[0]) + case block_arg_type + in Type::Nil + calling.block_handler = C::VM_BLOCK_HANDLER_NONE + in Type::BlockParamProxy + calling.block_handler = C.rb_block_param_proxy + else + asm.incr_counter(:send_block_arg) + return CantCompile + end + end + end + + # vm_search_method + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_search_method(jit, ctx, asm, mid, calling) + assert_equal(true, jit.at_current_insn?) + + # Generate a side exit + side_exit = side_exit(jit, ctx) + + # kw_splat is not supported yet + if calling.flags & C::VM_CALL_KW_SPLAT != 0 + asm.incr_counter(:send_kw_splat) + return CantCompile + end + + # Get a compile-time receiver and its class + recv_idx = calling.argc + (calling.flags & C::VM_CALL_ARGS_BLOCKARG != 0 ? 1 : 0) # blockarg is not popped yet + recv_idx += calling.send_shift + comptime_recv = jit.peek_at_stack(recv_idx) + comptime_recv_klass = C.rb_class_of(comptime_recv) + + # Guard the receiver class (part of vm_search_method_fastpath) + recv_opnd = ctx.stack_opnd(recv_idx) + megamorphic_exit = counted_exit(side_exit, :send_klass_megamorphic) + jit_guard_known_klass(jit, ctx, asm, comptime_recv_klass, recv_opnd, StackOpnd[recv_idx], comptime_recv, megamorphic_exit) + + # Do method lookup (vm_cc_cme(cc) != NULL) + cme = C.rb_callable_method_entry(comptime_recv_klass, mid) + if cme.nil? + asm.incr_counter(:send_missing_cme) + return CantCompile # We don't support vm_call_method_name + end + + # Invalidate on redefinition (part of vm_search_method_fastpath) + Invariants.assume_method_lookup_stable(jit, cme) + + return cme, comptime_recv_klass + end + + # vm_call_general + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_general(jit, ctx, asm, mid, calling, cme, known_recv_class) + jit_call_method(jit, ctx, asm, mid, calling, cme, known_recv_class) + end + + # vm_call_method + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + # @param send_shift [Integer] The number of shifts needed for VM_CALL_OPT_SEND + def jit_call_method(jit, ctx, asm, mid, calling, cme, known_recv_class) + # The main check of vm_call_method before vm_call_method_each_type + case C::METHOD_ENTRY_VISI(cme) + in C::METHOD_VISI_PUBLIC + # You can always call public methods + in C::METHOD_VISI_PRIVATE + # Allow only callsites without a receiver + if calling.flags & C::VM_CALL_FCALL == 0 + asm.incr_counter(:send_private) + return CantCompile + end + in C::METHOD_VISI_PROTECTED + # If the method call is an FCALL, it is always valid + if calling.flags & C::VM_CALL_FCALL == 0 + # otherwise we need an ancestry check to ensure the receiver is valid to be called as protected + jit_protected_callee_ancestry_guard(asm, cme, side_exit(jit, ctx)) + end + end + + # Get a compile-time receiver + recv_idx = calling.argc + (calling.flags & C::VM_CALL_ARGS_BLOCKARG != 0 ? 1 : 0) # blockarg is not popped yet + recv_idx += calling.send_shift + comptime_recv = jit.peek_at_stack(recv_idx) + recv_opnd = ctx.stack_opnd(recv_idx) + + jit_call_method_each_type(jit, ctx, asm, calling, cme, comptime_recv, recv_opnd, known_recv_class) + end + + # Generate ancestry guard for protected callee. + # Calls to protected callees only go through when self.is_a?(klass_that_defines_the_callee). + def jit_protected_callee_ancestry_guard(asm, cme, side_exit) + # See vm_call_method(). + def_class = cme.defined_class + # Note: PC isn't written to current control frame as rb_is_kind_of() shouldn't raise. + # VALUE rb_obj_is_kind_of(VALUE obj, VALUE klass); + + asm.mov(C_ARGS[0], [CFP, C.rb_control_frame_t.offsetof(:self)]) + asm.mov(C_ARGS[1], to_value(def_class)) + asm.call(C.rb_obj_is_kind_of) + asm.test(C_RET, C_RET) + asm.jz(counted_exit(side_exit, :send_protected_check_failed)) + end + + # vm_call_method_each_type + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_method_each_type(jit, ctx, asm, calling, cme, comptime_recv, recv_opnd, known_recv_class) + case cme.def.type + in C::VM_METHOD_TYPE_ISEQ + iseq = def_iseq_ptr(cme.def) + jit_call_iseq(jit, ctx, asm, cme, calling, iseq) + in C::VM_METHOD_TYPE_NOTIMPLEMENTED + asm.incr_counter(:send_notimplemented) + return CantCompile + in C::VM_METHOD_TYPE_CFUNC + jit_call_cfunc(jit, ctx, asm, cme, calling, known_recv_class:) + in C::VM_METHOD_TYPE_ATTRSET + jit_call_attrset(jit, ctx, asm, cme, calling, comptime_recv, recv_opnd) + in C::VM_METHOD_TYPE_IVAR + jit_call_ivar(jit, ctx, asm, cme, calling, comptime_recv, recv_opnd) + in C::VM_METHOD_TYPE_MISSING + asm.incr_counter(:send_missing) + return CantCompile + in C::VM_METHOD_TYPE_BMETHOD + jit_call_bmethod(jit, ctx, asm, calling, cme, comptime_recv, recv_opnd, known_recv_class) + in C::VM_METHOD_TYPE_ALIAS + jit_call_alias(jit, ctx, asm, calling, cme, comptime_recv, recv_opnd, known_recv_class) + in C::VM_METHOD_TYPE_OPTIMIZED + jit_call_optimized(jit, ctx, asm, cme, calling, known_recv_class) + in C::VM_METHOD_TYPE_UNDEF + asm.incr_counter(:send_undef) + return CantCompile + in C::VM_METHOD_TYPE_ZSUPER + asm.incr_counter(:send_zsuper) + return CantCompile + in C::VM_METHOD_TYPE_REFINED + asm.incr_counter(:send_refined) + return CantCompile + end + end + + # vm_call_iseq_setup + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_iseq(jit, ctx, asm, cme, calling, iseq, frame_type: nil, prev_ep: nil) + argc = calling.argc + flags = calling.flags + send_shift = calling.send_shift + + # When you have keyword arguments, there is an extra object that gets + # placed on the stack the represents a bitmap of the keywords that were not + # specified at the call site. We need to keep track of the fact that this + # value is present on the stack in order to properly set up the callee's + # stack pointer. + doing_kw_call = iseq.body.param.flags.has_kw + supplying_kws = flags & C::VM_CALL_KWARG != 0 + + if flags & C::VM_CALL_TAILCALL != 0 + # We can't handle tailcalls + asm.incr_counter(:send_tailcall) + return CantCompile + end + + # No support for callees with these parameters yet as they require allocation + # or complex handling. + if iseq.body.param.flags.has_post + asm.incr_counter(:send_iseq_has_opt) + return CantCompile + end + if iseq.body.param.flags.has_kwrest + asm.incr_counter(:send_iseq_has_kwrest) + return CantCompile + end + + # In order to handle backwards compatibility between ruby 3 and 2 + # ruby2_keywords was introduced. It is called only on methods + # with splat and changes they way they handle them. + # We are just going to not compile these. + # https://www.rubydoc.info/stdlib/core/Proc:ruby2_keywords + if iseq.body.param.flags.ruby2_keywords && flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:send_iseq_ruby2_keywords) + return CantCompile + end + + iseq_has_rest = iseq.body.param.flags.has_rest + if iseq_has_rest && calling.block_handler == :captured + asm.incr_counter(:send_iseq_has_rest_and_captured) + return CantCompile + end + + if iseq_has_rest && iseq.body.param.flags.has_kw && supplying_kws + asm.incr_counter(:send_iseq_has_rest_and_kw_supplied) + return CantCompile + end + + # If we have keyword arguments being passed to a callee that only takes + # positionals, then we need to allocate a hash. For now we're going to + # call that too complex and bail. + if supplying_kws && !iseq.body.param.flags.has_kw + asm.incr_counter(:send_iseq_has_no_kw) + return CantCompile + end + + # If we have a method accepting no kwargs (**nil), exit if we have passed + # it any kwargs. + if supplying_kws && iseq.body.param.flags.accepts_no_kwarg + asm.incr_counter(:send_iseq_accepts_no_kwarg) + return CantCompile + end + + # For computing number of locals to set up for the callee + num_params = iseq.body.param.size + + # Block parameter handling. This mirrors setup_parameters_complex(). + if iseq.body.param.flags.has_block + if iseq.body.local_iseq.to_i == iseq.to_i + num_params -= 1 + else + # In this case (param.flags.has_block && local_iseq != iseq), + # the block argument is setup as a local variable and requires + # materialization (allocation). Bail. + asm.incr_counter(:send_iseq_materialized_block) + return CantCompile + end + end + + if flags & C::VM_CALL_ARGS_SPLAT != 0 && flags & C::VM_CALL_ZSUPER != 0 + # zsuper methods are super calls without any arguments. + # They are also marked as splat, but don't actually have an array + # they pull arguments from, instead we need to change to call + # a different method with the current stack. + asm.incr_counter(:send_iseq_zsuper) + return CantCompile + end + + start_pc_offset = 0 + required_num = iseq.body.param.lead_num + + # This struct represents the metadata about the caller-specified + # keyword arguments. + kw_arg = calling.kwarg + kw_arg_num = if kw_arg.nil? + 0 + else + kw_arg.keyword_len + end + + # Arity handling and optional parameter setup + opts_filled = argc - required_num - kw_arg_num + opt_num = iseq.body.param.opt_num + opts_missing = opt_num - opts_filled + + if doing_kw_call && flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:send_iseq_splat_with_kw) + return CantCompile + end + + if flags & C::VM_CALL_KW_SPLAT != 0 + asm.incr_counter(:send_iseq_kw_splat) + return CantCompile + end + + if iseq_has_rest && opt_num != 0 + asm.incr_counter(:send_iseq_has_rest_and_optional) + return CantCompile + end + + if opts_filled < 0 && flags & C::VM_CALL_ARGS_SPLAT == 0 + # Too few arguments and no splat to make up for it + asm.incr_counter(:send_iseq_arity_error) + return CantCompile + end + + if opts_filled > opt_num && !iseq_has_rest + # Too many arguments and no place to put them (i.e. rest arg) + asm.incr_counter(:send_iseq_arity_error) + return CantCompile + end + + block_arg = flags & C::VM_CALL_ARGS_BLOCKARG != 0 + + # Guard block_arg_type + if guard_block_arg(jit, ctx, asm, calling) == CantCompile + return CantCompile + end + + # If we have unfilled optional arguments and keyword arguments then we + # would need to adjust the arguments location to account for that. + # For now we aren't handling this case. + if doing_kw_call && opts_missing > 0 + asm.incr_counter(:send_iseq_missing_optional_kw) + return CantCompile + end + + # We will handle splat case later + if opt_num > 0 && flags & C::VM_CALL_ARGS_SPLAT == 0 + num_params -= opts_missing + start_pc_offset = iseq.body.param.opt_table[opts_filled] + end + + if doing_kw_call + # Here we're calling a method with keyword arguments and specifying + # keyword arguments at this call site. + + # This struct represents the metadata about the callee-specified + # keyword parameters. + keyword = iseq.body.param.keyword + keyword_num = keyword.num + keyword_required_num = keyword.required_num + + required_kwargs_filled = 0 + + if keyword_num > 30 + # We have so many keywords that (1 << num) encoded as a FIXNUM + # (which shifts it left one more) no longer fits inside a 32-bit + # immediate. + asm.incr_counter(:send_iseq_too_many_kwargs) + return CantCompile + end + + # Check that the kwargs being passed are valid + if supplying_kws + # This is the list of keyword arguments that the callee specified + # in its initial declaration. + # SAFETY: see compile.c for sizing of this slice. + callee_kwargs = keyword_num.times.map { |i| keyword.table[i] } + + # Here we're going to build up a list of the IDs that correspond to + # the caller-specified keyword arguments. If they're not in the + # same order as the order specified in the callee declaration, then + # we're going to need to generate some code to swap values around + # on the stack. + caller_kwargs = [] + kw_arg.keyword_len.times do |kwarg_idx| + sym = C.to_ruby(kw_arg[:keywords][kwarg_idx]) + caller_kwargs << C.rb_sym2id(sym) + end + + # First, we're going to be sure that the names of every + # caller-specified keyword argument correspond to a name in the + # list of callee-specified keyword parameters. + caller_kwargs.each do |caller_kwarg| + search_result = callee_kwargs.map.with_index.find { |kwarg, _| kwarg == caller_kwarg } + + case search_result + in nil + # If the keyword was never found, then we know we have a + # mismatch in the names of the keyword arguments, so we need to + # bail. + asm.incr_counter(:send_iseq_kwargs_mismatch) + return CantCompile + in _, callee_idx if callee_idx < keyword_required_num + # Keep a count to ensure all required kwargs are specified + required_kwargs_filled += 1 + else + end + end + end + assert_equal(true, required_kwargs_filled <= keyword_required_num) + if required_kwargs_filled != keyword_required_num + asm.incr_counter(:send_iseq_kwargs_mismatch) + return CantCompile + end + end + + # Check if we need the arg0 splat handling of vm_callee_setup_block_arg + arg_setup_block = (calling.block_handler == :captured) # arg_setup_type: arg_setup_block (invokeblock) + block_arg0_splat = arg_setup_block && argc == 1 && + (iseq.body.param.flags.has_lead || opt_num > 1) && + !iseq.body.param.flags.ambiguous_param0 + if block_arg0_splat + # If block_arg0_splat, we still need side exits after splat, but + # doing push_splat_args here disallows it. So bail out. + if flags & C::VM_CALL_ARGS_SPLAT != 0 && !iseq_has_rest + asm.incr_counter(:invokeblock_iseq_arg0_args_splat) + return CantCompile + end + # The block_arg0_splat implementation is for the rb_simple_iseq_p case, + # but doing_kw_call means it's not a simple ISEQ. + if doing_kw_call + asm.incr_counter(:invokeblock_iseq_arg0_has_kw) + return CantCompile + end + # The block_arg0_splat implementation cannot deal with optional parameters. + # This is a setup_parameters_complex() situation and interacts with the + # starting position of the callee. + if opt_num > 1 + asm.incr_counter(:invokeblock_iseq_arg0_optional) + return CantCompile + end + end + if flags & C::VM_CALL_ARGS_SPLAT != 0 && !iseq_has_rest + array = jit.peek_at_stack(block_arg ? 1 : 0) + splat_array_length = if array.nil? + 0 + else + array.length + end + + if opt_num == 0 && required_num != splat_array_length + argc - 1 + asm.incr_counter(:send_iseq_splat_arity_error) + return CantCompile + end + end + + # We will not have CantCompile from here. + + if block_arg + ctx.stack_pop(1) + end + + if calling.block_handler == C::VM_BLOCK_HANDLER_NONE && iseq.body.builtin_attrs & C::BUILTIN_ATTR_LEAF != 0 + if jit_leaf_builtin_func(jit, ctx, asm, flags, iseq) + return KeepCompiling + end + end + + # Number of locals that are not parameters + num_locals = iseq.body.local_table_size - num_params + + # Stack overflow check + # Note that vm_push_frame checks it against a decremented cfp, hence the multiply by 2. + # #define CHECK_VM_STACK_OVERFLOW0(cfp, sp, margin) + asm.comment('stack overflow check') + locals_offs = C.VALUE.size * (num_locals + iseq.body.stack_max) + 2 * C.rb_control_frame_t.size + asm.lea(:rax, ctx.sp_opnd(locals_offs)) + asm.cmp(CFP, :rax) + asm.jbe(counted_exit(side_exit(jit, ctx), :send_stackoverflow)) + + # push_splat_args does stack manipulation so we can no longer side exit + if splat_array_length + remaining_opt = (opt_num + required_num) - (splat_array_length + (argc - 1)) + + if opt_num > 0 + # We are going to jump to the correct offset based on how many optional + # params are remaining. + offset = opt_num - remaining_opt + start_pc_offset = iseq.body.param.opt_table[offset] + end + # We are going to assume that the splat fills + # all the remaining arguments. In the generated code + # we test if this is true and if not side exit. + argc = argc - 1 + splat_array_length + remaining_opt + push_splat_args(splat_array_length, jit, ctx, asm) + + remaining_opt.times do + # We need to push nil for the optional arguments + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, Qnil) + end + end + + # This is a .send call and we need to adjust the stack + if flags & C::VM_CALL_OPT_SEND != 0 + handle_opt_send_shift_stack(asm, argc, ctx, send_shift:) + end + + if iseq_has_rest + # We are going to allocate so setting pc and sp. + jit_save_pc(jit, asm) # clobbers rax + jit_save_sp(ctx, asm) + + if flags & C::VM_CALL_ARGS_SPLAT != 0 + non_rest_arg_count = argc - 1 + # We start by dupping the array because someone else might have + # a reference to it. + array = ctx.stack_pop(1) + asm.mov(C_ARGS[0], array) + asm.call(C.rb_ary_dup) + array = C_RET + if non_rest_arg_count > required_num + # If we have more arguments than required, we need to prepend + # the items from the stack onto the array. + diff = (non_rest_arg_count - required_num) + + # diff is >0 so no need to worry about null pointer + asm.comment('load pointer to array elements') + offset_magnitude = C.VALUE.size * diff + values_opnd = ctx.sp_opnd(-offset_magnitude) + values_ptr = :rcx + asm.lea(values_ptr, values_opnd) + + asm.comment('prepend stack values to rest array') + asm.mov(C_ARGS[0], diff) + asm.mov(C_ARGS[1], values_ptr) + asm.mov(C_ARGS[2], array) + asm.call(C.rb_ary_unshift_m) + ctx.stack_pop(diff) + + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, C_RET) + # We now should have the required arguments + # and an array of all the rest arguments + argc = required_num + 1 + elsif non_rest_arg_count < required_num + # If we have fewer arguments than required, we need to take some + # from the array and move them to the stack. + diff = (required_num - non_rest_arg_count) + # This moves the arguments onto the stack. But it doesn't modify the array. + move_rest_args_to_stack(array, diff, jit, ctx, asm) + + # We will now slice the array to give us a new array of the correct size + asm.mov(C_ARGS[0], array) + asm.mov(C_ARGS[1], diff) + asm.call(C.rjit_rb_ary_subseq_length) + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, C_RET) + + # We now should have the required arguments + # and an array of all the rest arguments + argc = required_num + 1 + else + # The arguments are equal so we can just push to the stack + assert_equal(non_rest_arg_count, required_num) + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, array) + end + else + assert_equal(true, argc >= required_num) + n = (argc - required_num) + argc = required_num + 1 + # If n is 0, then elts is never going to be read, so we can just pass null + if n == 0 + values_ptr = 0 + else + asm.comment('load pointer to array elements') + offset_magnitude = C.VALUE.size * n + values_opnd = ctx.sp_opnd(-offset_magnitude) + values_ptr = :rcx + asm.lea(values_ptr, values_opnd) + end + + asm.mov(C_ARGS[0], EC) + asm.mov(C_ARGS[1], n) + asm.mov(C_ARGS[2], values_ptr) + asm.call(C.rb_ec_ary_new_from_values) + + ctx.stack_pop(n) + stack_ret = ctx.stack_push(Type::TArray) + asm.mov(stack_ret, C_RET) + end + end + + if doing_kw_call + # Here we're calling a method with keyword arguments and specifying + # keyword arguments at this call site. + + # Number of positional arguments the callee expects before the first + # keyword argument + args_before_kw = required_num + opt_num + + # This struct represents the metadata about the caller-specified + # keyword arguments. + ci_kwarg = calling.kwarg + caller_keyword_len = if ci_kwarg.nil? + 0 + else + ci_kwarg.keyword_len + end + + # This struct represents the metadata about the callee-specified + # keyword parameters. + keyword = iseq.body.param.keyword + + asm.comment('keyword args') + + # This is the list of keyword arguments that the callee specified + # in its initial declaration. + callee_kwargs = keyword.table + total_kwargs = keyword.num + + # Here we're going to build up a list of the IDs that correspond to + # the caller-specified keyword arguments. If they're not in the + # same order as the order specified in the callee declaration, then + # we're going to need to generate some code to swap values around + # on the stack. + caller_kwargs = [] + + caller_keyword_len.times do |kwarg_idx| + sym = C.to_ruby(ci_kwarg[:keywords][kwarg_idx]) + caller_kwargs << C.rb_sym2id(sym) + end + kwarg_idx = caller_keyword_len + + unspecified_bits = 0 + + keyword_required_num = keyword.required_num + (keyword_required_num...total_kwargs).each do |callee_idx| + already_passed = false + callee_kwarg = callee_kwargs[callee_idx] + + caller_keyword_len.times do |caller_idx| + if caller_kwargs[caller_idx] == callee_kwarg + already_passed = true + break + end + end + + unless already_passed + # Reserve space on the stack for each default value we'll be + # filling in (which is done in the next loop). Also increments + # argc so that the callee's SP is recorded correctly. + argc += 1 + default_arg = ctx.stack_push(Type::Unknown) + + # callee_idx - keyword->required_num is used in a couple of places below. + req_num = keyword.required_num + extra_args = callee_idx - req_num + + # VALUE default_value = keyword->default_values[callee_idx - keyword->required_num]; + default_value = keyword.default_values[extra_args] + + if default_value == Qundef + # Qundef means that this value is not constant and must be + # recalculated at runtime, so we record it in unspecified_bits + # (Qnil is then used as a placeholder instead of Qundef). + unspecified_bits |= 0x01 << extra_args + default_value = Qnil + end + + asm.mov(:rax, default_value) + asm.mov(default_arg, :rax) + + caller_kwargs[kwarg_idx] = callee_kwarg + kwarg_idx += 1 + end + end + + assert_equal(kwarg_idx, total_kwargs) + + # Next, we're going to loop through every keyword that was + # specified by the caller and make sure that it's in the correct + # place. If it's not we're going to swap it around with another one. + total_kwargs.times do |kwarg_idx| + callee_kwarg = callee_kwargs[kwarg_idx] + + # If the argument is already in the right order, then we don't + # need to generate any code since the expected value is already + # in the right place on the stack. + if callee_kwarg == caller_kwargs[kwarg_idx] + next + end + + # In this case the argument is not in the right place, so we + # need to find its position where it _should_ be and swap with + # that location. + ((kwarg_idx + 1)...total_kwargs).each do |swap_idx| + if callee_kwarg == caller_kwargs[swap_idx] + # First we're going to generate the code that is going + # to perform the actual swapping at runtime. + offset0 = argc - 1 - swap_idx - args_before_kw + offset1 = argc - 1 - kwarg_idx - args_before_kw + stack_swap(jit, ctx, asm, offset0, offset1) + + # Next we're going to do some bookkeeping on our end so + # that we know the order that the arguments are + # actually in now. + caller_kwargs[kwarg_idx], caller_kwargs[swap_idx] = + caller_kwargs[swap_idx], caller_kwargs[kwarg_idx] + + break + end + end + end + + # Keyword arguments cause a special extra local variable to be + # pushed onto the stack that represents the parameters that weren't + # explicitly given a value and have a non-constant default. + asm.mov(ctx.stack_opnd(-1), C.to_value(unspecified_bits)) + end + + # Same as vm_callee_setup_block_arg_arg0_check and vm_callee_setup_block_arg_arg0_splat + # on vm_callee_setup_block_arg for arg_setup_block. This is done after CALLER_SETUP_ARG + # and CALLER_REMOVE_EMPTY_KW_SPLAT, so this implementation is put here. This may need + # side exits, so you still need to allow side exits here if block_arg0_splat is true. + # Note that you can't have side exits after this arg0 splat. + if block_arg0_splat + asm.incr_counter(:send_iseq_block_arg0_splat) + return CantCompile + end + + # Create a context for the callee + callee_ctx = Context.new + + # Set the argument types in the callee's context + argc.times do |arg_idx| + stack_offs = argc - arg_idx - 1 + arg_type = ctx.get_opnd_type(StackOpnd[stack_offs]) + callee_ctx.set_local_type(arg_idx, arg_type) + end + + recv_type = if calling.block_handler == :captured + Type::Unknown # we don't track the type information of captured->self for now + else + ctx.get_opnd_type(StackOpnd[argc]) + end + callee_ctx.upgrade_opnd_type(SelfOpnd, recv_type) + + # Setup the new frame + frame_type ||= C::VM_FRAME_MAGIC_METHOD | C::VM_ENV_FLAG_LOCAL + jit_push_frame( + jit, ctx, asm, cme, flags, argc, frame_type, calling.block_handler, + iseq: iseq, + local_size: num_locals, + stack_max: iseq.body.stack_max, + prev_ep:, + doing_kw_call:, + ) + + # Directly jump to the entry point of the callee + pc = (iseq.body.iseq_encoded + start_pc_offset).to_i + jit_direct_jump(iseq, pc, callee_ctx, asm) + + EndBlock + end + + def jit_leaf_builtin_func(jit, ctx, asm, flags, iseq) + builtin_func = builtin_function(iseq) + if builtin_func.nil? + return false + end + + # this is a .send call not currently supported for builtins + if flags & C::VM_CALL_OPT_SEND != 0 + return false + end + + builtin_argc = builtin_func.argc + if builtin_argc + 1 >= C_ARGS.size + return false + end + + asm.comment('inlined leaf builtin') + + # The callee may allocate, e.g. Integer#abs on a Bignum. + # Save SP for GC, save PC for allocation tracing, and prepare + # for global invalidation after GC's VM lock contention. + jit_prepare_routine_call(jit, ctx, asm) + + # Call the builtin func (ec, recv, arg1, arg2, ...) + asm.mov(C_ARGS[0], EC) + + # Copy self and arguments + (0..builtin_argc).each do |i| + stack_opnd = ctx.stack_opnd(builtin_argc - i) + asm.mov(C_ARGS[i + 1], stack_opnd) + end + ctx.stack_pop(builtin_argc + 1) + asm.call(builtin_func.func_ptr) + + # Push the return value + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + return true + end + + # vm_call_cfunc + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_cfunc(jit, ctx, asm, cme, calling, known_recv_class: nil) + argc = calling.argc + flags = calling.flags + + cfunc = cme.def.body.cfunc + cfunc_argc = cfunc.argc + + # If the function expects a Ruby array of arguments + if cfunc_argc < 0 && cfunc_argc != -1 + asm.incr_counter(:send_cfunc_ruby_array_varg) + return CantCompile + end + + # We aren't handling a vararg cfuncs with splat currently. + if flags & C::VM_CALL_ARGS_SPLAT != 0 && cfunc_argc == -1 + asm.incr_counter(:send_args_splat_cfunc_var_args) + return CantCompile + end + + if flags & C::VM_CALL_ARGS_SPLAT != 0 && flags & C::VM_CALL_ZSUPER != 0 + # zsuper methods are super calls without any arguments. + # They are also marked as splat, but don't actually have an array + # they pull arguments from, instead we need to change to call + # a different method with the current stack. + asm.incr_counter(:send_args_splat_cfunc_zuper) + return CantCompile; + end + + # In order to handle backwards compatibility between ruby 3 and 2 + # ruby2_keywords was introduced. It is called only on methods + # with splat and changes they way they handle them. + # We are just going to not compile these. + # https://docs.ruby-lang.org/en/3.2/Module.html#method-i-ruby2_keywords + if jit.iseq.body.param.flags.ruby2_keywords && flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:send_args_splat_cfunc_ruby2_keywords) + return CantCompile; + end + + kw_arg = calling.kwarg + kw_arg_num = if kw_arg.nil? + 0 + else + kw_arg.keyword_len + end + + if kw_arg_num != 0 && flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:send_cfunc_splat_with_kw) + return CantCompile + end + + if c_method_tracing_currently_enabled? + # Don't JIT if tracing c_call or c_return + asm.incr_counter(:send_cfunc_tracing) + return CantCompile + end + + # Delegate to codegen for C methods if we have it. + if kw_arg.nil? && flags & C::VM_CALL_OPT_SEND == 0 && flags & C::VM_CALL_ARGS_SPLAT == 0 && (cfunc_argc == -1 || argc == cfunc_argc) + known_cfunc_codegen = lookup_cfunc_codegen(cme.def) + if known_cfunc_codegen&.call(jit, ctx, asm, argc, known_recv_class) + # cfunc codegen generated code. Terminate the block so + # there isn't multiple calls in the same block. + jump_to_next_insn(jit, ctx, asm) + return EndBlock + end + end + + # Check for interrupts + jit_check_ints(jit, ctx, asm) + + # Stack overflow check + # #define CHECK_VM_STACK_OVERFLOW0(cfp, sp, margin) + # REG_CFP <= REG_SP + 4 * SIZEOF_VALUE + sizeof(rb_control_frame_t) + asm.comment('stack overflow check') + asm.lea(:rax, ctx.sp_opnd(C.VALUE.size * 4 + 2 * C.rb_control_frame_t.size)) + asm.cmp(CFP, :rax) + asm.jbe(counted_exit(side_exit(jit, ctx), :send_stackoverflow)) + + # Number of args which will be passed through to the callee + # This is adjusted by the kwargs being combined into a hash. + passed_argc = if kw_arg.nil? + argc + else + argc - kw_arg_num + 1 + end + + # If the argument count doesn't match + if cfunc_argc >= 0 && cfunc_argc != passed_argc && flags & C::VM_CALL_ARGS_SPLAT == 0 + asm.incr_counter(:send_cfunc_argc_mismatch) + return CantCompile + end + + # Don't JIT functions that need C stack arguments for now + if cfunc_argc >= 0 && passed_argc + 1 > C_ARGS.size + asm.incr_counter(:send_cfunc_toomany_args) + return CantCompile + end + + block_arg = flags & C::VM_CALL_ARGS_BLOCKARG != 0 + + # Guard block_arg_type + if guard_block_arg(jit, ctx, asm, calling) == CantCompile + return CantCompile + end + + if block_arg + ctx.stack_pop(1) + end + + # push_splat_args does stack manipulation so we can no longer side exit + if flags & C::VM_CALL_ARGS_SPLAT != 0 + assert_equal(true, cfunc_argc >= 0) + required_args = cfunc_argc - (argc - 1) + # + 1 because we pass self + if required_args + 1 >= C_ARGS.size + asm.incr_counter(:send_cfunc_toomany_args) + return CantCompile + end + + # We are going to assume that the splat fills + # all the remaining arguments. So the number of args + # should just equal the number of args the cfunc takes. + # In the generated code we test if this is true + # and if not side exit. + argc = cfunc_argc + passed_argc = argc + push_splat_args(required_args, jit, ctx, asm) + end + + # This is a .send call and we need to adjust the stack + if flags & C::VM_CALL_OPT_SEND != 0 + handle_opt_send_shift_stack(asm, argc, ctx, send_shift: calling.send_shift) + end + + # Points to the receiver operand on the stack + + # Store incremented PC into current control frame in case callee raises. + jit_save_pc(jit, asm) + + # Increment the stack pointer by 3 (in the callee) + # sp += 3 + + frame_type = C::VM_FRAME_MAGIC_CFUNC | C::VM_FRAME_FLAG_CFRAME | C::VM_ENV_FLAG_LOCAL + if kw_arg + frame_type |= C::VM_FRAME_FLAG_CFRAME_KW + end + + jit_push_frame(jit, ctx, asm, cme, flags, argc, frame_type, calling.block_handler) + + if kw_arg + # Build a hash from all kwargs passed + asm.comment('build_kwhash') + imemo_ci = calling.ci_addr + # we assume all callinfos with kwargs are on the GC heap + assert_equal(true, C.imemo_type_p(imemo_ci, C.imemo_callinfo)) + asm.mov(C_ARGS[0], imemo_ci) + asm.lea(C_ARGS[1], ctx.sp_opnd(0)) + asm.call(C.rjit_build_kwhash) + + # Replace the stack location at the start of kwargs with the new hash + stack_opnd = ctx.stack_opnd(argc - passed_argc) + asm.mov(stack_opnd, C_RET) + end + + # Copy SP because REG_SP will get overwritten + sp = :rax + asm.lea(sp, ctx.sp_opnd(0)) + + # Pop the C function arguments from the stack (in the caller) + ctx.stack_pop(argc + 1) + + # Write interpreter SP into CFP. + # Needed in case the callee yields to the block. + jit_save_sp(ctx, asm) + + # Non-variadic method + case cfunc_argc + in (0..) # Non-variadic method + # Copy the arguments from the stack to the C argument registers + # self is the 0th argument and is at index argc from the stack top + (0..passed_argc).each do |i| + asm.mov(C_ARGS[i], [sp, -(argc + 1 - i) * C.VALUE.size]) + end + in -1 # Variadic method: rb_f_puts(int argc, VALUE *argv, VALUE recv) + # The method gets a pointer to the first argument + # rb_f_puts(int argc, VALUE *argv, VALUE recv) + asm.mov(C_ARGS[0], passed_argc) + asm.lea(C_ARGS[1], [sp, -argc * C.VALUE.size]) # argv + asm.mov(C_ARGS[2], [sp, -(argc + 1) * C.VALUE.size]) # recv + end + + # Call the C function + # VALUE ret = (cfunc->func)(recv, argv[0], argv[1]); + # cfunc comes from compile-time cme->def, which we assume to be stable. + # Invalidation logic is in yjit_method_lookup_change() + asm.comment('call C function') + asm.mov(:rax, cfunc.func) + asm.call(:rax) # TODO: use rel32 if close enough + + # Record code position for TracePoint patching. See full_cfunc_return(). + Invariants.record_global_inval_patch(asm, full_cfunc_return) + + # Push the return value on the Ruby stack + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + + # Pop the stack frame (ec->cfp++) + # Instead of recalculating, we can reuse the previous CFP, which is stored in a callee-saved + # register + asm.mov([EC, C.rb_execution_context_t.offsetof(:cfp)], CFP) + + # cfunc calls may corrupt types + ctx.clear_local_types + + # Note: the return block of jit_call_iseq has ctx->sp_offset == 1 + # which allows for sharing the same successor. + + # Jump (fall through) to the call continuation block + # We do this to end the current block after the call + assert_equal(1, ctx.sp_offset) + jump_to_next_insn(jit, ctx, asm) + EndBlock + end + + # vm_call_attrset + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_attrset(jit, ctx, asm, cme, calling, comptime_recv, recv_opnd) + argc = calling.argc + flags = calling.flags + send_shift = calling.send_shift + + if flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:send_attrset_splat) + return CantCompile + end + if flags & C::VM_CALL_KWARG != 0 + asm.incr_counter(:send_attrset_kwarg) + return CantCompile + elsif argc != 1 || !C.RB_TYPE_P(comptime_recv, C::RUBY_T_OBJECT) + asm.incr_counter(:send_attrset_method) + return CantCompile + elsif c_method_tracing_currently_enabled? + # Can't generate code for firing c_call and c_return events + # See :attr-tracing: + asm.incr_counter(:send_c_tracingg) + return CantCompile + elsif flags & C::VM_CALL_ARGS_BLOCKARG != 0 + asm.incr_counter(:send_block_arg) + return CantCompile + end + + ivar_name = cme.def.body.attr.id + + # This is a .send call and we need to adjust the stack + if flags & C::VM_CALL_OPT_SEND != 0 + handle_opt_send_shift_stack(asm, argc, ctx, send_shift:) + end + + # Save the PC and SP because the callee may allocate + # Note that this modifies REG_SP, which is why we do it first + jit_prepare_routine_call(jit, ctx, asm) + + # Get the operands from the stack + val_opnd = ctx.stack_pop(1) + recv_opnd = ctx.stack_pop(1) + + # Call rb_vm_set_ivar_id with the receiver, the ivar name, and the value + asm.mov(C_ARGS[0], recv_opnd) + asm.mov(C_ARGS[1], ivar_name) + asm.mov(C_ARGS[2], val_opnd) + asm.call(C.rb_vm_set_ivar_id) + + out_opnd = ctx.stack_push(Type::Unknown) + asm.mov(out_opnd, C_RET) + + KeepCompiling + end + + # vm_call_ivar (+ part of vm_call_method_each_type) + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_ivar(jit, ctx, asm, cme, calling, comptime_recv, recv_opnd) + argc = calling.argc + flags = calling.flags + + if flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:send_ivar_splat) + return CantCompile + end + + if argc != 0 + asm.incr_counter(:send_arity) + return CantCompile + end + + # We don't support handle_opt_send_shift_stack for this yet. + if flags & C::VM_CALL_OPT_SEND != 0 + asm.incr_counter(:send_ivar_opt_send) + return CantCompile + end + + ivar_id = cme.def.body.attr.id + + # Not handling block_handler + if flags & C::VM_CALL_ARGS_BLOCKARG != 0 + asm.incr_counter(:send_block_arg) + return CantCompile + end + + jit_getivar(jit, ctx, asm, comptime_recv, ivar_id, recv_opnd, StackOpnd[0]) + end + + # vm_call_bmethod + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_bmethod(jit, ctx, asm, calling, cme, comptime_recv, recv_opnd, known_recv_class) + proc_addr = cme.def.body.bmethod.proc + + proc_t = C.rb_yjit_get_proc_ptr(proc_addr) + proc_block = proc_t.block + + if proc_block.type != C.block_type_iseq + asm.incr_counter(:send_bmethod_not_iseq) + return CantCompile + end + + capture = proc_block.as.captured + iseq = capture.code.iseq + + # TODO: implement this + # Optimize for single ractor mode and avoid runtime check for + # "defined with an un-shareable Proc in a different Ractor" + # if !assume_single_ractor_mode(jit, ocb) + # return CantCompile; + # end + + # Passing a block to a block needs logic different from passing + # a block to a method and sometimes requires allocation. Bail for now. + if calling.block_handler != C::VM_BLOCK_HANDLER_NONE + asm.incr_counter(:send_bmethod_blockarg) + return CantCompile + end + + jit_call_iseq( + jit, ctx, asm, cme, calling, iseq, + frame_type: C::VM_FRAME_MAGIC_BLOCK | C::VM_FRAME_FLAG_BMETHOD | C::VM_FRAME_FLAG_LAMBDA, + prev_ep: capture.ep, + ) + end + + # vm_call_alias + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_alias(jit, ctx, asm, calling, cme, comptime_recv, recv_opnd, known_recv_class) + cme = C.rb_aliased_callable_method_entry(cme) + jit_call_method_each_type(jit, ctx, asm, calling, cme, comptime_recv, recv_opnd, known_recv_class) + end + + # vm_call_optimized + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_optimized(jit, ctx, asm, cme, calling, known_recv_class) + if calling.flags & C::VM_CALL_ARGS_BLOCKARG != 0 + # Not working yet + asm.incr_counter(:send_block_arg) + return CantCompile + end + + case cme.def.body.optimized.type + in C::OPTIMIZED_METHOD_TYPE_SEND + jit_call_opt_send(jit, ctx, asm, cme, calling, known_recv_class) + in C::OPTIMIZED_METHOD_TYPE_CALL + jit_call_opt_call(jit, ctx, asm, cme, calling.flags, calling.argc, calling.block_handler, known_recv_class, send_shift: calling.send_shift) + in C::OPTIMIZED_METHOD_TYPE_BLOCK_CALL + asm.incr_counter(:send_optimized_block_call) + return CantCompile + in C::OPTIMIZED_METHOD_TYPE_STRUCT_AREF + jit_call_opt_struct_aref(jit, ctx, asm, cme, calling.flags, calling.argc, calling.block_handler, known_recv_class, send_shift: calling.send_shift) + in C::OPTIMIZED_METHOD_TYPE_STRUCT_ASET + asm.incr_counter(:send_optimized_struct_aset) + return CantCompile + end + end + + # vm_call_opt_send + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_opt_send(jit, ctx, asm, cme, calling, known_recv_class) + if jit_caller_setup_arg(jit, ctx, asm, calling.flags) == CantCompile + return CantCompile + end + + if calling.argc == 0 + asm.incr_counter(:send_optimized_send_no_args) + return CantCompile + end + + calling.argc -= 1 + # We aren't handling `send(:send, ...)` yet. This might work, but not tested yet. + if calling.send_shift > 0 + asm.incr_counter(:send_optimized_send_send) + return CantCompile + end + # Lazily handle stack shift in handle_opt_send_shift_stack + calling.send_shift += 1 + + jit_call_symbol(jit, ctx, asm, cme, calling, known_recv_class, C::VM_CALL_FCALL) + end + + # vm_call_opt_call + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_opt_call(jit, ctx, asm, cme, flags, argc, block_handler, known_recv_class, send_shift:) + if block_handler != C::VM_BLOCK_HANDLER_NONE + asm.incr_counter(:send_optimized_call_block) + return CantCompile + end + + if flags & C::VM_CALL_KWARG != 0 + asm.incr_counter(:send_optimized_call_kwarg) + return CantCompile + end + + if flags & C::VM_CALL_ARGS_SPLAT != 0 + asm.incr_counter(:send_optimized_call_splat) + return CantCompile + end + + # TODO: implement this + # Optimize for single ractor mode and avoid runtime check for + # "defined with an un-shareable Proc in a different Ractor" + # if !assume_single_ractor_mode(jit, ocb) + # return CantCompile + # end + + # If this is a .send call we need to adjust the stack + if flags & C::VM_CALL_OPT_SEND != 0 + handle_opt_send_shift_stack(asm, argc, ctx, send_shift:) + end + + # About to reset the SP, need to load this here + recv_idx = argc # blockarg is not supported. send_shift is already handled. + asm.mov(:rcx, ctx.stack_opnd(recv_idx)) # recv + + # Save the PC and SP because the callee can make Ruby calls + jit_prepare_routine_call(jit, ctx, asm) # NOTE: clobbers rax + + asm.lea(:rax, ctx.sp_opnd(0)) # sp + + kw_splat = flags & C::VM_CALL_KW_SPLAT + + asm.mov(C_ARGS[0], :rcx) + asm.mov(C_ARGS[1], EC) + asm.mov(C_ARGS[2], argc) + asm.lea(C_ARGS[3], [:rax, -argc * C.VALUE.size]) # stack_argument_pointer. NOTE: C_ARGS[3] is rcx + asm.mov(C_ARGS[4], kw_splat) + asm.mov(C_ARGS[5], C::VM_BLOCK_HANDLER_NONE) + asm.call(C.rjit_optimized_call) + + ctx.stack_pop(argc + 1) + + stack_ret = ctx.stack_push(Type::Unknown) + asm.mov(stack_ret, C_RET) + return KeepCompiling + end + + # vm_call_opt_struct_aref + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_opt_struct_aref(jit, ctx, asm, cme, flags, argc, block_handler, known_recv_class, send_shift:) + if argc != 0 + asm.incr_counter(:send_optimized_struct_aref_error) + return CantCompile + end + + if c_method_tracing_currently_enabled? + # Don't JIT if tracing c_call or c_return + asm.incr_counter(:send_cfunc_tracing) + return CantCompile + end + + off = cme.def.body.optimized.index + + recv_idx = argc # blockarg is not supported + recv_idx += send_shift + comptime_recv = jit.peek_at_stack(recv_idx) + + # This is a .send call and we need to adjust the stack + if flags & C::VM_CALL_OPT_SEND != 0 + handle_opt_send_shift_stack(asm, argc, ctx, send_shift:) + end + + # All structs from the same Struct class should have the same + # length. So if our comptime_recv is embedded all runtime + # structs of the same class should be as well, and the same is + # true of the converse. + embedded = C::FL_TEST_RAW(comptime_recv, C::RSTRUCT_EMBED_LEN_MASK) + + asm.comment('struct aref') + asm.mov(:rax, ctx.stack_pop(1)) # recv + + if embedded + asm.mov(:rax, [:rax, C.RStruct.offsetof(:as, :ary) + (C.VALUE.size * off)]) + else + asm.mov(:rax, [:rax, C.RStruct.offsetof(:as, :heap, :ptr)]) + asm.mov(:rax, [:rax, C.VALUE.size * off]) + end + + ret = ctx.stack_push(Type::Unknown) + asm.mov(ret, :rax) + + jump_to_next_insn(jit, ctx, asm) + EndBlock + end + + # vm_call_opt_send (lazy part) + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def handle_opt_send_shift_stack(asm, argc, ctx, send_shift:) + # We don't support `send(:send, ...)` for now. + assert_equal(1, send_shift) + + asm.comment('shift stack') + (0...argc).reverse_each do |i| + opnd = ctx.stack_opnd(i) + opnd2 = ctx.stack_opnd(i + 1) + asm.mov(:rax, opnd) + asm.mov(opnd2, :rax) + end + + ctx.shift_stack(argc) + end + + # vm_call_symbol + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_call_symbol(jit, ctx, asm, cme, calling, known_recv_class, flags) + flags |= C::VM_CALL_OPT_SEND | (calling.kw_splat ? C::VM_CALL_KW_SPLAT : 0) + + comptime_symbol = jit.peek_at_stack(calling.argc) + if comptime_symbol.class != String && !static_symbol?(comptime_symbol) + asm.incr_counter(:send_optimized_send_not_sym_or_str) + return CantCompile + end + + mid = C.get_symbol_id(comptime_symbol) + if mid == 0 + asm.incr_counter(:send_optimized_send_null_mid) + return CantCompile + end + + asm.comment("Guard #{comptime_symbol.inspect} is on stack") + class_changed_exit = counted_exit(side_exit(jit, ctx), :send_optimized_send_mid_class_changed) + jit_guard_known_klass( + jit, ctx, asm, C.rb_class_of(comptime_symbol), ctx.stack_opnd(calling.argc), + StackOpnd[calling.argc], comptime_symbol, class_changed_exit, + ) + asm.mov(C_ARGS[0], ctx.stack_opnd(calling.argc)) + asm.call(C.rb_get_symbol_id) + asm.cmp(C_RET, mid) + id_changed_exit = counted_exit(side_exit(jit, ctx), :send_optimized_send_mid_id_changed) + jit_chain_guard(:jne, jit, ctx, asm, id_changed_exit) + + # rb_callable_method_entry_with_refinements + calling.flags = flags + cme, _ = jit_search_method(jit, ctx, asm, mid, calling) + if cme == CantCompile + return CantCompile + end + + if flags & C::VM_CALL_FCALL != 0 + return jit_call_method(jit, ctx, asm, mid, calling, cme, known_recv_class) + end + + raise NotImplementedError # unreachable for now + end + + # vm_push_frame + # + # Frame structure: + # | args | locals | cme/cref | block_handler/prev EP | frame type (EP here) | stack bottom (SP here) + # + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_push_frame(jit, ctx, asm, cme, flags, argc, frame_type, block_handler, iseq: nil, local_size: 0, stack_max: 0, prev_ep: nil, doing_kw_call: nil) + # Save caller SP and PC before pushing a callee frame for backtrace and side exits + asm.comment('save SP to caller CFP') + recv_idx = argc # blockarg is already popped + recv_idx += (block_handler == :captured) ? 0 : 1 # receiver is not on stack when captured->self is used + if iseq + # Skip setting this to SP register. This cfp->sp will be copied to SP on leave insn. + asm.lea(:rax, ctx.sp_opnd(C.VALUE.size * -recv_idx)) # Pop receiver and arguments to prepare for side exits + asm.mov([CFP, C.rb_control_frame_t.offsetof(:sp)], :rax) + else + asm.lea(SP, ctx.sp_opnd(C.VALUE.size * -recv_idx)) + asm.mov([CFP, C.rb_control_frame_t.offsetof(:sp)], SP) + ctx.sp_offset = recv_idx + end + jit_save_pc(jit, asm, comment: 'save PC to caller CFP') + + sp_offset = ctx.sp_offset + 3 + local_size + (doing_kw_call ? 1 : 0) # callee_sp + local_size.times do |i| + asm.comment('set local variables') if i == 0 + local_index = sp_offset + i - local_size - 3 + asm.mov([SP, C.VALUE.size * local_index], Qnil) + end + + asm.comment('set up EP with managing data') + ep_offset = sp_offset - 1 + # ep[-2]: cref_or_me + asm.mov(:rax, cme.to_i) + asm.mov([SP, C.VALUE.size * (ep_offset - 2)], :rax) + # ep[-1]: block handler or prev env ptr (specval) + if prev_ep + asm.mov(:rax, prev_ep.to_i | 1) # tagged prev ep + asm.mov([SP, C.VALUE.size * (ep_offset - 1)], :rax) + elsif block_handler == :captured + # Set captured->ep, saving captured in :rcx for captured->self + ep_reg = :rcx + jit_get_lep(jit, asm, reg: ep_reg) + asm.mov(:rcx, [ep_reg, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) # block_handler + asm.and(:rcx, ~0x3) # captured + asm.mov(:rax, [:rcx, C.VALUE.size]) # captured->ep + asm.or(:rax, 0x1) # GC_GUARDED_PTR + asm.mov([SP, C.VALUE.size * (ep_offset - 1)], :rax) + elsif block_handler == C::VM_BLOCK_HANDLER_NONE + asm.mov([SP, C.VALUE.size * (ep_offset - 1)], C::VM_BLOCK_HANDLER_NONE) + elsif block_handler == C.rb_block_param_proxy + # vm_caller_setup_arg_block: block_code == rb_block_param_proxy + jit_get_lep(jit, asm, reg: :rax) # VM_CF_BLOCK_HANDLER: VM_CF_LEP + asm.mov(:rax, [:rax, C.VALUE.size * C::VM_ENV_DATA_INDEX_SPECVAL]) # VM_CF_BLOCK_HANDLER: VM_ENV_BLOCK_HANDLER + asm.mov([CFP, C.rb_control_frame_t.offsetof(:block_code)], :rax) # reg_cfp->block_code = handler + asm.mov([SP, C.VALUE.size * (ep_offset - 1)], :rax) # return handler; + else # assume blockiseq + asm.mov(:rax, block_handler) + asm.mov([CFP, C.rb_control_frame_t.offsetof(:block_code)], :rax) + asm.lea(:rax, [CFP, C.rb_control_frame_t.offsetof(:self)]) # VM_CFP_TO_CAPTURED_BLOCK + asm.or(:rax, 1) # VM_BH_FROM_ISEQ_BLOCK + asm.mov([SP, C.VALUE.size * (ep_offset - 1)], :rax) + end + # ep[-0]: ENV_FLAGS + asm.mov([SP, C.VALUE.size * (ep_offset - 0)], frame_type) + + asm.comment('set up new frame') + cfp_offset = -C.rb_control_frame_t.size # callee CFP + # For ISEQ, JIT code will set it as needed. However, C func needs 0 there for svar frame detection. + if iseq.nil? + asm.mov([CFP, cfp_offset + C.rb_control_frame_t.offsetof(:pc)], 0) + end + asm.mov(:rax, iseq.to_i) + asm.mov([CFP, cfp_offset + C.rb_control_frame_t.offsetof(:iseq)], :rax) + if block_handler == :captured + asm.mov(:rax, [:rcx]) # captured->self + else + self_index = ctx.sp_offset - (1 + argc) # blockarg has been popped + asm.mov(:rax, [SP, C.VALUE.size * self_index]) + end + asm.mov([CFP, cfp_offset + C.rb_control_frame_t.offsetof(:self)], :rax) + asm.lea(:rax, [SP, C.VALUE.size * ep_offset]) + asm.mov([CFP, cfp_offset + C.rb_control_frame_t.offsetof(:ep)], :rax) + asm.mov([CFP, cfp_offset + C.rb_control_frame_t.offsetof(:block_code)], 0) + # Update SP register only for ISEQ calls. SP-relative operations should be done above this. + sp_reg = iseq ? SP : :rax + asm.lea(sp_reg, [SP, C.VALUE.size * sp_offset]) + asm.mov([CFP, cfp_offset + C.rb_control_frame_t.offsetof(:sp)], sp_reg) + + # cfp->jit_return is used only for ISEQs + if iseq + # The callee might change locals through Kernel#binding and other means. + ctx.clear_local_types + + # Stub cfp->jit_return + return_ctx = ctx.dup + return_ctx.stack_pop(argc + ((block_handler == :captured) ? 0 : 1)) # Pop args and receiver. blockarg has been popped + return_ctx.stack_push(Type::Unknown) # push callee's return value + return_ctx.sp_offset = 1 # SP is in the position after popping a receiver and arguments + return_ctx.chain_depth = 0 + branch_stub = BranchStub.new( + iseq: jit.iseq, + shape: Default, + target0: BranchTarget.new(ctx: return_ctx, pc: jit.pc + jit.insn.len * C.VALUE.size), + ) + branch_stub.target0.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(return_ctx, ocb_asm, branch_stub, true) + @ocb.write(ocb_asm) + end + branch_stub.compile = compile_jit_return(branch_stub, cfp_offset:) + branch_stub.compile.call(asm) + end + + asm.comment('switch to callee CFP') + # Update CFP register only for ISEQ calls + cfp_reg = iseq ? CFP : :rax + asm.lea(cfp_reg, [CFP, cfp_offset]) + asm.mov([EC, C.rb_execution_context_t.offsetof(:cfp)], cfp_reg) + end + + def compile_jit_return(branch_stub, cfp_offset:) # Proc escapes arguments in memory + proc do |branch_asm| + branch_asm.comment('set jit_return to callee CFP') + branch_asm.stub(branch_stub) do + case branch_stub.shape + in Default + branch_asm.mov(:rax, branch_stub.target0.address) + branch_asm.mov([CFP, cfp_offset + C.rb_control_frame_t.offsetof(:jit_return)], :rax) + end + end + end + end + + # CALLER_SETUP_ARG: Return CantCompile if not supported + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def jit_caller_setup_arg(jit, ctx, asm, flags) + if flags & C::VM_CALL_ARGS_SPLAT != 0 && flags & C::VM_CALL_KW_SPLAT != 0 + asm.incr_counter(:send_args_splat_kw_splat) + return CantCompile + elsif flags & C::VM_CALL_ARGS_SPLAT != 0 + # splat is not supported in this path + asm.incr_counter(:send_args_splat) + return CantCompile + elsif flags & C::VM_CALL_KW_SPLAT != 0 + asm.incr_counter(:send_args_kw_splat) + return CantCompile + elsif flags & C::VM_CALL_KWARG != 0 + asm.incr_counter(:send_kwarg) + return CantCompile + end + end + + # Pushes arguments from an array to the stack. Differs from push splat because + # the array can have items left over. + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def move_rest_args_to_stack(array, num_args, jit, ctx, asm) + side_exit = side_exit(jit, ctx) + + asm.comment('move_rest_args_to_stack') + + # array is :rax + array_len_opnd = :rcx + jit_array_len(asm, array, array_len_opnd) + + asm.comment('Side exit if length is less than required') + asm.cmp(array_len_opnd, num_args) + asm.jl(counted_exit(side_exit, :send_iseq_has_rest_and_splat_not_equal)) + + asm.comment('Push arguments from array') + + # Load the address of the embedded array + # (struct RArray *)(obj)->as.ary + array_reg = array + + # Conditionally load the address of the heap array + # (struct RArray *)(obj)->as.heap.ptr + flags_opnd = [array_reg, C.RBasic.offsetof(:flags)] + asm.test(flags_opnd, C::RARRAY_EMBED_FLAG) + heap_ptr_opnd = [array_reg, C.RArray.offsetof(:as, :heap, :ptr)] + # Load the address of the embedded array + # (struct RArray *)(obj)->as.ary + ary_opnd = :rdx # NOTE: array :rax is used after move_rest_args_to_stack too + asm.lea(:rcx, [array_reg, C.RArray.offsetof(:as, :ary)]) + asm.mov(ary_opnd, heap_ptr_opnd) + asm.cmovnz(ary_opnd, :rcx) + + num_args.times do |i| + top = ctx.stack_push(Type::Unknown) + asm.mov(:rcx, [ary_opnd, i * C.VALUE.size]) + asm.mov(top, :rcx) + end + end + + # vm_caller_setup_arg_splat (+ CALLER_SETUP_ARG): + # Pushes arguments from an array to the stack that are passed with a splat (i.e. *args). + # It optimistically compiles to a static size that is the exact number of arguments needed for the function. + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def push_splat_args(required_args, jit, ctx, asm) + side_exit = side_exit(jit, ctx) + + asm.comment('push_splat_args') + + array_opnd = ctx.stack_opnd(0) + array_stack_opnd = StackOpnd[0] + array_reg = :rax + asm.mov(array_reg, array_opnd) + + guard_object_is_array(jit, ctx, asm, array_reg, :rcx, array_stack_opnd, :send_args_splat_not_array) + + array_len_opnd = :rcx + jit_array_len(asm, array_reg, array_len_opnd) + + asm.comment('Side exit if length is not equal to remaining args') + asm.cmp(array_len_opnd, required_args) + asm.jne(counted_exit(side_exit, :send_args_splat_length_not_equal)) + + asm.comment('Check last argument is not ruby2keyword hash') + + ary_opnd = :rcx + jit_array_ptr(asm, array_reg, ary_opnd) # clobbers array_reg + + last_array_value = :rax + asm.mov(last_array_value, [ary_opnd, (required_args - 1) * C.VALUE.size]) + + ruby2_exit = counted_exit(side_exit, :send_args_splat_ruby2_hash); + guard_object_is_not_ruby2_keyword_hash(asm, last_array_value, :rcx, ruby2_exit) # clobbers :rax + + asm.comment('Push arguments from array') + array_opnd = ctx.stack_pop(1) + + if required_args > 0 + # Load the address of the embedded array + # (struct RArray *)(obj)->as.ary + array_reg = :rax + asm.mov(array_reg, array_opnd) + + # Conditionally load the address of the heap array + # (struct RArray *)(obj)->as.heap.ptr + flags_opnd = [array_reg, C.RBasic.offsetof(:flags)] + asm.test(flags_opnd, C::RARRAY_EMBED_FLAG) + heap_ptr_opnd = [array_reg, C.RArray.offsetof(:as, :heap, :ptr)] + # Load the address of the embedded array + # (struct RArray *)(obj)->as.ary + asm.lea(:rcx, [array_reg, C.RArray.offsetof(:as, :ary)]) + asm.mov(:rax, heap_ptr_opnd) + asm.cmovnz(:rax, :rcx) + ary_opnd = :rax + + (0...required_args).each do |i| + top = ctx.stack_push(Type::Unknown) + asm.mov(:rcx, [ary_opnd, i * C.VALUE.size]) + asm.mov(top, :rcx) + end + + asm.comment('end push_each') + end + end + + # Generate RARRAY_LEN. For array_opnd, use Opnd::Reg to reduce memory access, + # and use Opnd::Mem to save registers. + def jit_array_len(asm, array_reg, len_reg) + asm.comment('get array length for embedded or heap') + + # Pull out the embed flag to check if it's an embedded array. + asm.mov(len_reg, [array_reg, C.RBasic.offsetof(:flags)]) + + # Get the length of the array + asm.and(len_reg, C::RARRAY_EMBED_LEN_MASK) + asm.sar(len_reg, C::RARRAY_EMBED_LEN_SHIFT) + + # Conditionally move the length of the heap array + asm.test([array_reg, C.RBasic.offsetof(:flags)], C::RARRAY_EMBED_FLAG) + + # Select the array length value + asm.cmovz(len_reg, [array_reg, C.RArray.offsetof(:as, :heap, :len)]) + end + + # Generate RARRAY_CONST_PTR (part of RARRAY_AREF) + def jit_array_ptr(asm, array_reg, ary_opnd) # clobbers array_reg + asm.comment('get array pointer for embedded or heap') + + flags_opnd = [array_reg, C.RBasic.offsetof(:flags)] + asm.test(flags_opnd, C::RARRAY_EMBED_FLAG) + # Load the address of the embedded array + # (struct RArray *)(obj)->as.ary + asm.mov(ary_opnd, [array_reg, C.RArray.offsetof(:as, :heap, :ptr)]) + asm.lea(array_reg, [array_reg, C.RArray.offsetof(:as, :ary)]) # clobbers array_reg + asm.cmovnz(ary_opnd, array_reg) + end + + def assert(cond) + assert_equal(cond, true) + end + + def assert_equal(left, right) + if left != right + raise "'#{left.inspect}' was not '#{right.inspect}'" + end + end + + def fixnum?(obj) + (C.to_value(obj) & C::RUBY_FIXNUM_FLAG) == C::RUBY_FIXNUM_FLAG + end + + def flonum?(obj) + (C.to_value(obj) & C::RUBY_FLONUM_MASK) == C::RUBY_FLONUM_FLAG + end + + def symbol?(obj) + static_symbol?(obj) || dynamic_symbol?(obj) + end + + def static_symbol?(obj) + (C.to_value(obj) & 0xff) == C::RUBY_SYMBOL_FLAG + end + + def dynamic_symbol?(obj) + return false if C::SPECIAL_CONST_P(obj) + C.RB_TYPE_P(obj, C::RUBY_T_SYMBOL) + end + + def shape_too_complex?(obj) + C.rb_shape_get_shape_id(obj) == C::OBJ_TOO_COMPLEX_SHAPE_ID + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + # @param asm [RubyVM::RJIT::Assembler] + def defer_compilation(jit, ctx, asm) + # Make a stub to compile the current insn + if ctx.chain_depth != 0 + raise "double defer!" + end + ctx.chain_depth += 1 + jit_direct_jump(jit.iseq, jit.pc, ctx, asm, comment: 'defer_compilation') + end + + def jit_direct_jump(iseq, pc, ctx, asm, comment: 'jit_direct_jump') + branch_stub = BranchStub.new( + iseq:, + shape: Default, + target0: BranchTarget.new(ctx:, pc:), + ) + branch_stub.target0.address = Assembler.new.then do |ocb_asm| + @exit_compiler.compile_branch_stub(ctx, ocb_asm, branch_stub, true) + @ocb.write(ocb_asm) + end + branch_stub.compile = compile_jit_direct_jump(branch_stub, comment:) + branch_stub.compile.call(asm) + end + + def compile_jit_direct_jump(branch_stub, comment:) # Proc escapes arguments in memory + proc do |branch_asm| + branch_asm.comment(comment) + branch_asm.stub(branch_stub) do + case branch_stub.shape + in Default + branch_asm.jmp(branch_stub.target0.address) + in Next0 + # Just write the block without a jump + end + end + end + end + + # @param jit [RubyVM::RJIT::JITState] + # @param ctx [RubyVM::RJIT::Context] + def side_exit(jit, ctx) + # We use the latest ctx.sp_offset to generate a side exit to tolerate sp_offset changes by jit_save_sp. + # However, we want to simulate an old stack_size when we take a side exit. We do that by adjusting the + # sp_offset because gen_outlined_exit uses ctx.sp_offset to move SP. + ctx = ctx.with_stack_size(jit.stack_size_for_pc) + + jit.side_exit_for_pc[ctx.sp_offset] ||= Assembler.new.then do |asm| + @exit_compiler.compile_side_exit(jit.pc, ctx, asm) + @ocb.write(asm) + end + end + + def counted_exit(side_exit, name) + asm = Assembler.new + asm.incr_counter(name) + asm.jmp(side_exit) + @ocb.write(asm) + end + + def def_iseq_ptr(cme_def) + C.rb_iseq_check(cme_def.body.iseq.iseqptr) + end + + def to_value(obj) + GC_REFS << obj + C.to_value(obj) + end + + def full_cfunc_return + @full_cfunc_return ||= Assembler.new.then do |asm| + @exit_compiler.compile_full_cfunc_return(asm) + @ocb.write(asm) + end + end + + def c_method_tracing_currently_enabled? + C.rb_rjit_global_events & (C::RUBY_EVENT_C_CALL | C::RUBY_EVENT_C_RETURN) != 0 + end + + # Return a builtin function if a given iseq consists of only that builtin function + def builtin_function(iseq) + opt_invokebuiltin_delegate_leave = INSNS.values.find { |i| i.name == :opt_invokebuiltin_delegate_leave } + leave = INSNS.values.find { |i| i.name == :leave } + if iseq.body.iseq_size == opt_invokebuiltin_delegate_leave.len + leave.len && + C.rb_vm_insn_decode(iseq.body.iseq_encoded[0]) == opt_invokebuiltin_delegate_leave.bin && + C.rb_vm_insn_decode(iseq.body.iseq_encoded[opt_invokebuiltin_delegate_leave.len]) == leave.bin + C.rb_builtin_function.new(iseq.body.iseq_encoded[1]) + end + end + + def build_calling(ci:, block_handler:) + CallingInfo.new( + argc: C.vm_ci_argc(ci), + flags: C.vm_ci_flag(ci), + kwarg: C.vm_ci_kwarg(ci), + ci_addr: ci.to_i, + send_shift: 0, + block_handler:, + ) + end + end +end diff --git a/lib/ruby_vm/rjit/invariants.rb b/lib/ruby_vm/rjit/invariants.rb new file mode 100644 index 0000000000..5b061d1994 --- /dev/null +++ b/lib/ruby_vm/rjit/invariants.rb @@ -0,0 +1,155 @@ +require 'set' + +module RubyVM::RJIT + class Invariants + class << self + # Called by RubyVM::RJIT::Compiler to lazily initialize this + # @param cb [CodeBlock] + # @param ocb [CodeBlock] + # @param compiler [RubyVM::RJIT::Compiler] + # @param exit_compiler [RubyVM::RJIT::ExitCompiler] + def initialize(cb, ocb, compiler, exit_compiler) + @cb = cb + @ocb = ocb + @compiler = compiler + @exit_compiler = exit_compiler + @bop_blocks = Set.new # TODO: actually invalidate this + @cme_blocks = Hash.new { |h, k| h[k] = Set.new } + @const_blocks = Hash.new { |h, k| h[k] = Set.new } + @patches = {} + + # freeze # workaround a binding.irb issue. TODO: resurrect this + end + + # @param jit [RubyVM::RJIT::JITState] + # @param klass [Integer] + # @param op [Integer] + def assume_bop_not_redefined(jit, klass, op) + return false unless C.BASIC_OP_UNREDEFINED_P(klass, op) + + ensure_block_entry_exit(jit, cause: 'assume_bop_not_redefined') + @bop_blocks << jit.block + true + end + + # @param jit [RubyVM::RJIT::JITState] + def assume_method_lookup_stable(jit, cme) + ensure_block_entry_exit(jit, cause: 'assume_method_lookup_stable') + @cme_blocks[cme.to_i] << jit.block + end + + # @param jit [RubyVM::RJIT::JITState] + def assume_method_basic_definition(jit, klass, mid) + if C.rb_method_basic_definition_p(klass, mid) + cme = C.rb_callable_method_entry(klass, mid) + assume_method_lookup_stable(jit, cme) + true + else + false + end + end + + def assume_stable_constant_names(jit, idlist) + (0..).each do |i| + break if (id = idlist[i]) == 0 + @const_blocks[id] << jit.block + end + end + + # @param asm [RubyVM::RJIT::Assembler] + def record_global_inval_patch(asm, target) + asm.pos_marker do |address| + if @patches.key?(address) + raise 'multiple patches in the same address' + end + @patches[address] = target + end + end + + def on_cme_invalidate(cme) + @cme_blocks.fetch(cme.to_i, []).each do |block| + @cb.with_write_addr(block.start_addr) do + asm = Assembler.new + asm.comment('on_cme_invalidate') + asm.jmp(block.entry_exit) + @cb.write(asm) + end + # TODO: re-generate branches that refer to this block + end + @cme_blocks.delete(cme.to_i) + end + + def on_constant_ic_update(iseq, ic, insn_idx) + # TODO: check multi ractor as well + if ic.entry.ic_cref + # No need to recompile the slowpath + return + end + + pc = iseq.body.iseq_encoded + insn_idx + insn_name = Compiler.decode_insn(pc.*).name + if insn_name != :opt_getconstant_path && insn_name != :trace_opt_getconstant_path + raise 'insn_idx was not at opt_getconstant_path' + end + if ic.to_i != pc[1] + raise 'insn_idx + 1 was not at the updated IC' + end + @compiler.invalidate_blocks(iseq, pc.to_i) + end + + def on_constant_state_changed(id) + @const_blocks.fetch(id, []).each do |block| + @compiler.invalidate_block(block) + end + end + + def on_tracing_invalidate_all + invalidate_all + end + + def on_update_references + # Give up. In order to support GC.compact, you'd have to update ISEQ + # addresses in BranchStub, etc. Ideally, we'd need to update moved + # pointers in JITed code here, but we just invalidate all for now. + invalidate_all + end + + # @param jit [RubyVM::RJIT::JITState] + # @param block [RubyVM::RJIT::Block] + def ensure_block_entry_exit(jit, cause:) + block = jit.block + if block.entry_exit.nil? + block.entry_exit = Assembler.new.then do |asm| + @exit_compiler.compile_entry_exit(block.pc, block.ctx, asm, cause:) + @ocb.write(asm) + end + end + end + + private + + def invalidate_all + # On-Stack Replacement + @patches.each do |address, target| + # TODO: assert patches don't overlap each other + @cb.with_write_addr(address) do + asm = Assembler.new + asm.comment('on_tracing_invalidate_all') + asm.jmp(target) + @cb.write(asm) + end + end + @patches.clear + + C.rjit_for_each_iseq do |iseq| + # Avoid entering past code + iseq.body.jit_entry = 0 + # Avoid reusing past code + iseq.body.rjit_blocks.clear if iseq.body.rjit_blocks + # Compile this again if not converted to trace_* insns + iseq.body.jit_entry_calls = 0 + end + end + end + end +end diff --git a/lib/ruby_vm/rjit/jit_state.rb b/lib/ruby_vm/rjit/jit_state.rb new file mode 100644 index 0000000000..02a713474e --- /dev/null +++ b/lib/ruby_vm/rjit/jit_state.rb @@ -0,0 +1,65 @@ +module RubyVM::RJIT + class JITState < Struct.new( + :iseq, # @param `RubyVM::RJIT::CPointer::Struct_rb_iseq_t` + :pc, # @param [Integer] The JIT target PC + :cfp, # @param `RubyVM::RJIT::CPointer::Struct_rb_control_frame_t` The JIT source CFP (before RJIT is called) + :block, # @param [RubyVM::RJIT::Block] + :stack_size_for_pc, # @param [Integer] + :side_exit_for_pc, # @param [Hash{ Integer => Integer }] { sp_offset => address } + :record_boundary_patch_point, # @param [TrueClass,FalseClass] + ) + def initialize(side_exit_for_pc: {}, record_boundary_patch_point: false, **) = super + + def insn + Compiler.decode_insn(C.VALUE.new(pc).*) + end + + def operand(index, signed: false, ruby: false) + addr = pc + (index + 1) * Fiddle::SIZEOF_VOIDP + value = Fiddle::Pointer.new(addr)[0, Fiddle::SIZEOF_VOIDP].unpack(signed ? 'q' : 'Q')[0] + if ruby + value = C.to_ruby(value) + end + value + end + + def at_current_insn? + pc == cfp.pc.to_i + end + + def peek_at_local(n) + local_table_size = iseq.body.local_table_size + offset = -C::VM_ENV_DATA_SIZE - local_table_size + n + 1 + value = (cfp.ep + offset).* + C.to_ruby(value) + end + + def peek_at_stack(depth_from_top) + raise 'not at current insn' unless at_current_insn? + offset = -(1 + depth_from_top) + # rb_rjit_branch_stub_hit updates SP, so you don't need to worry about sp_offset + value = (cfp.sp + offset).* + C.to_ruby(value) + end + + def peek_at_self + C.to_ruby(cfp.self) + end + + def peek_at_block_handler(level) + ep = ep_at_level(cfp, level:) + ep[C::VM_ENV_DATA_INDEX_SPECVAL] + end + + private + + def ep_at_level(cfp, level:) + ep = cfp.ep + level.times do + # VM_ENV_PREV_EP + ep = C.VALUE.new(ep[C::VM_ENV_DATA_INDEX_SPECVAL] & ~0x03) + end + ep + end + end +end diff --git a/lib/ruby_vm/rjit/stats.rb b/lib/ruby_vm/rjit/stats.rb new file mode 100644 index 0000000000..7e353c698e --- /dev/null +++ b/lib/ruby_vm/rjit/stats.rb @@ -0,0 +1,191 @@ +# frozen_string_literal: true +module RubyVM::RJIT + # Return a Hash for \RJIT statistics. \--rjit-stats makes more information available. + def self.runtime_stats + stats = {} + + # Insn exits + INSNS.each_value do |insn| + exits = C.rjit_insn_exits[insn.bin] + if exits > 0 + stats[:"exit_#{insn.name}"] = exits + end + end + + # Runtime stats + C.rb_rjit_runtime_counters.members.each do |member| + stats[member] = C.rb_rjit_counters.public_send(member) + end + stats[:vm_insns_count] = C.rb_vm_insns_count + + # Other stats are calculated here + stats[:side_exit_count] = stats.select { |name, _count| name.start_with?('exit_') }.sum(&:last) + if stats[:vm_insns_count] > 0 + retired_in_rjit = stats[:rjit_insns_count] - stats[:side_exit_count] + stats[:total_insns_count] = retired_in_rjit + stats[:vm_insns_count] + stats[:ratio_in_rjit] = 100.0 * retired_in_rjit / stats[:total_insns_count] + else + stats.delete(:vm_insns_count) + end + + stats + end + + # :nodoc: all + class << self + private + + # --yjit-stats at_exit + def print_stats + stats = runtime_stats + $stderr.puts("***RJIT: Printing RJIT statistics on exit***") + + print_counters(stats, prefix: 'send_', prompt: 'method call exit reasons') + print_counters(stats, prefix: 'invokeblock_', prompt: 'invokeblock exit reasons') + print_counters(stats, prefix: 'invokesuper_', prompt: 'invokesuper exit reasons') + print_counters(stats, prefix: 'getblockpp_', prompt: 'getblockparamproxy exit reasons') + print_counters(stats, prefix: 'getivar_', prompt: 'getinstancevariable exit reasons') + print_counters(stats, prefix: 'setivar_', prompt: 'setinstancevariable exit reasons') + print_counters(stats, prefix: 'optaref_', prompt: 'opt_aref exit reasons') + print_counters(stats, prefix: 'optgetconst_', prompt: 'opt_getconstant_path exit reasons') + print_counters(stats, prefix: 'expandarray_', prompt: 'expandarray exit reasons') + + $stderr.puts "compiled_block_count: #{format_number(13, stats[:compiled_block_count])}" + $stderr.puts "side_exit_count: #{format_number(13, stats[:side_exit_count])}" + $stderr.puts "total_insns_count: #{format_number(13, stats[:total_insns_count])}" if stats.key?(:total_insns_count) + $stderr.puts "vm_insns_count: #{format_number(13, stats[:vm_insns_count])}" if stats.key?(:vm_insns_count) + $stderr.puts "rjit_insns_count: #{format_number(13, stats[:rjit_insns_count])}" + $stderr.puts "ratio_in_rjit: #{format('%12.1f', stats[:ratio_in_rjit])}%" if stats.key?(:ratio_in_rjit) + + print_exit_counts(stats) + end + + def print_counters(stats, prefix:, prompt:) + $stderr.puts("#{prompt}: ") + counters = stats.filter { |key, _| key.start_with?(prefix) } + counters.filter! { |_, value| value != 0 } + counters.transform_keys! { |key| key.to_s.delete_prefix(prefix) } + + if counters.empty? + $stderr.puts(" (all relevant counters are zero)") + return + end + + counters = counters.to_a + counters.sort_by! { |(_, counter_value)| counter_value } + longest_name_length = counters.max_by { |(name, _)| name.length }.first.length + total = counters.sum { |(_, counter_value)| counter_value } + + counters.reverse_each do |(name, value)| + percentage = value.fdiv(total) * 100 + $stderr.printf(" %*s %s (%4.1f%%)\n", longest_name_length, name, format_number(10, value), percentage) + end + end + + def print_exit_counts(stats, how_many: 20, padding: 2) + exits = stats.filter_map { |name, count| [name.to_s.delete_prefix('exit_'), count] if name.start_with?('exit_') }.to_h + return if exits.empty? + + top_exits = exits.sort_by { |_name, count| -count }.first(how_many).to_h + total_exits = exits.values.sum + $stderr.puts "Top-#{top_exits.size} most frequent exit ops (#{format("%.1f", 100.0 * top_exits.values.sum / total_exits)}% of exits):" + + name_width = top_exits.map { |name, _count| name.length }.max + padding + count_width = top_exits.map { |_name, count| format_number(10, count).length }.max + padding + top_exits.each do |name, count| + ratio = 100.0 * count / total_exits + $stderr.puts "#{format("%#{name_width}s", name)}: #{format_number(count_width, count)} (#{format('%4.1f', ratio)}%)" + end + end + + # Format large numbers with comma separators for readability + def format_number(pad, number) + integer, decimal = number.to_s.split('.') + d_groups = integer.chars.reverse.each_slice(3) + with_commas = d_groups.map(&:join).join(',').reverse + [with_commas, decimal].compact.join('.').rjust(pad, ' ') + end + + # --yjit-trace-exits at_exit + def dump_trace_exits + filename = "#{Dir.pwd}/rjit_exit_locations.dump" + File.binwrite(filename, Marshal.dump(exit_traces)) + $stderr.puts("RJIT exit locations dumped to:\n#{filename}") + end + + # Convert rb_rjit_raw_samples and rb_rjit_line_samples into a StackProf format. + def exit_traces + results = C.rjit_exit_traces + raw_samples = results[:raw].dup + line_samples = results[:lines].dup + frames = results[:frames].dup + samples_count = 0 + + # Loop through the instructions and set the frame hash with the data. + # We use nonexistent.def for the file name, otherwise insns.def will be displayed + # and that information isn't useful in this context. + RubyVM::INSTRUCTION_NAMES.each_with_index do |name, frame_id| + frame_hash = { samples: 0, total_samples: 0, edges: {}, name: name, file: "nonexistent.def", line: nil, lines: {} } + results[:frames][frame_id] = frame_hash + frames[frame_id] = frame_hash + end + + # Loop through the raw_samples and build the hashes for StackProf. + # The loop is based off an example in the StackProf documentation and therefore + # this functionality can only work with that library. + # + # Raw Samples: + # [ length, frame1, frame2, frameN, ..., instruction, count + # + # Line Samples + # [ length, line_1, line_2, line_n, ..., dummy value, count + i = 0 + while i < raw_samples.length + stack_length = raw_samples[i] + 1 + i += 1 # consume the stack length + + prev_frame_id = nil + stack_length.times do |idx| + idx += i + frame_id = raw_samples[idx] + + if prev_frame_id + prev_frame = frames[prev_frame_id] + prev_frame[:edges][frame_id] ||= 0 + prev_frame[:edges][frame_id] += 1 + end + + frame_info = frames[frame_id] + frame_info[:total_samples] += 1 + + frame_info[:lines][line_samples[idx]] ||= [0, 0] + frame_info[:lines][line_samples[idx]][0] += 1 + + prev_frame_id = frame_id + end + + i += stack_length # consume the stack + + top_frame_id = prev_frame_id + top_frame_line = 1 + + sample_count = raw_samples[i] + + frames[top_frame_id][:samples] += sample_count + frames[top_frame_id][:lines] ||= {} + frames[top_frame_id][:lines][top_frame_line] ||= [0, 0] + frames[top_frame_id][:lines][top_frame_line][1] += sample_count + + samples_count += sample_count + i += 1 + end + + results[:samples] = samples_count + # Set missed_samples and gc_samples to 0 as their values + # don't matter to us in this context. + results[:missed_samples] = 0 + results[:gc_samples] = 0 + results + end + end +end diff --git a/lib/ruby_vm/rjit/type.rb b/lib/ruby_vm/rjit/type.rb new file mode 100644 index 0000000000..119692014b --- /dev/null +++ b/lib/ruby_vm/rjit/type.rb @@ -0,0 +1,221 @@ +module RubyVM::RJIT + # Represent the type of a value (local/stack/self) in RJIT + Type = Data.define(:type) do + # Check if the type is an immediate + def imm? + case self + in Type::UnknownImm then true + in Type::Nil then true + in Type::True then true + in Type::False then true + in Type::Fixnum then true + in Type::Flonum then true + in Type::ImmSymbol then true + else false + end + end + + # Returns true when the type is not specific. + def unknown? + case self + in Type::Unknown | Type::UnknownImm | Type::UnknownHeap then true + else false + end + end + + # Returns true when we know the VALUE is a specific handle type, + # such as a static symbol ([Type::ImmSymbol], i.e. true from RB_STATIC_SYM_P()). + # Opposite of [Self::is_unknown]. + def specific? + !self.unknown? + end + + # Check if the type is a heap object + def heap? + case self + in Type::UnknownHeap then true + in Type::TArray then true + in Type::Hash then true + in Type::HeapSymbol then true + in Type::TString then true + in Type::CString then true + in Type::BlockParamProxy then true + else false + end + end + + # Check if it's a T_ARRAY object + def array? + case self + in Type::TArray then true + else false + end + end + + # Check if it's a T_STRING object (both TString and CString are T_STRING) + def string? + case self + in Type::TString then true + in Type::CString then true + else false + end + end + + # Returns the class if it is known, otherwise nil + def known_class + case self + in Type::Nil then C.rb_cNilClass + in Type::True then C.rb_cTrueClass + in Type::False then C.rb_cFalseClass + in Type::Fixnum then C.rb_cInteger + in Type::Flonum then C.rb_cFloat + in Type::ImmSymbol | Type::HeapSymbol then C.rb_cSymbol + in Type::CString then C.rb_cString + else nil + end + end + + # Returns a boolean representing whether the value is truthy if known, otherwise nil + def known_truthy + case self + in Type::Nil then false + in Type::False then false + in Type::UnknownHeap then false + in Type::Unknown | Type::UnknownImm then nil + else true + end + end + + # Returns a boolean representing whether the value is equal to nil if known, otherwise nil + def known_nil + case [self, self.known_truthy] + in Type::Nil, _ then true + in Type::False, _ then false # Qfalse is not nil + in _, true then false # if truthy, can't be nil + in _, _ then nil # otherwise unknown + end + end + + def diff(dst) + # Perfect match, difference is zero + if self == dst + return TypeDiff::Compatible[0] + end + + # Any type can flow into an unknown type + if dst == Type::Unknown + return TypeDiff::Compatible[1] + end + + # A CString is also a TString. + if self == Type::CString && dst == Type::TString + return TypeDiff::Compatible[1] + end + + # Specific heap type into unknown heap type is imperfect but valid + if self.heap? && dst == Type::UnknownHeap + return TypeDiff::Compatible[1] + end + + # Specific immediate type into unknown immediate type is imperfect but valid + if self.imm? && dst == Type::UnknownImm + return TypeDiff::Compatible[1] + end + + # Incompatible types + return TypeDiff::Incompatible + end + + def upgrade(new_type) + assert(new_type.diff(self) != TypeDiff::Incompatible) + new_type + end + + private + + def assert(cond) + unless cond + raise "'#{cond.inspect}' was not true" + end + end + end + + # This returns an appropriate Type based on a known value + class << Type + def from(val) + if C::SPECIAL_CONST_P(val) + if fixnum?(val) + Type::Fixnum + elsif val.nil? + Type::Nil + elsif val == true + Type::True + elsif val == false + Type::False + elsif static_symbol?(val) + Type::ImmSymbol + elsif flonum?(val) + Type::Flonum + else + raise "Illegal value: #{val.inspect}" + end + else + val_class = C.to_value(C.rb_class_of(val)) + if val_class == C.rb_cString && C.rb_obj_frozen_p(val) + return Type::CString + end + if C.to_value(val) == C.rb_block_param_proxy + return Type::BlockParamProxy + end + case C::BUILTIN_TYPE(val) + in C::RUBY_T_ARRAY + Type::TArray + in C::RUBY_T_HASH + Type::Hash + in C::RUBY_T_STRING + Type::TString + else + Type::UnknownHeap + end + end + end + + private + + def fixnum?(obj) + (C.to_value(obj) & C::RUBY_FIXNUM_FLAG) == C::RUBY_FIXNUM_FLAG + end + + def flonum?(obj) + (C.to_value(obj) & C::RUBY_FLONUM_MASK) == C::RUBY_FLONUM_FLAG + end + + def static_symbol?(obj) + (C.to_value(obj) & 0xff) == C::RUBY_SYMBOL_FLAG + end + end + + # List of types + Type::Unknown = Type[:Unknown] + Type::UnknownImm = Type[:UnknownImm] + Type::UnknownHeap = Type[:UnknownHeap] + Type::Nil = Type[:Nil] + Type::True = Type[:True] + Type::False = Type[:False] + Type::Fixnum = Type[:Fixnum] + Type::Flonum = Type[:Flonum] + Type::Hash = Type[:Hash] + Type::ImmSymbol = Type[:ImmSymbol] + Type::HeapSymbol = Type[:HeapSymbol] + + Type::TString = Type[:TString] # An object with the T_STRING flag set, possibly an rb_cString + Type::CString = Type[:CString] # An un-subclassed string of type rb_cString (can have instance vars in some cases) + Type::TArray = Type[:TArray] # An object with the T_ARRAY flag set, possibly an rb_cArray + + Type::BlockParamProxy = Type[:BlockParamProxy] # A special sentinel value indicating the block parameter should be read from + + module TypeDiff + Compatible = Data.define(:diversion) # The smaller, the more compatible. + Incompatible = :Incompatible + end +end |