package frame import ( "bytes" "encoding/binary" "fmt" "github.com/go-delve/delve/pkg/dwarf/util" ) type DWRule struct { Rule Rule Offset int64 Reg uint64 Expression []byte } type FrameContext struct { loc uint64 order binary.ByteOrder address uint64 CFA DWRule Regs map[uint64]DWRule initialRegs map[uint64]DWRule prevRegs map[uint64]DWRule buf *bytes.Buffer cie *CommonInformationEntry RetAddrReg uint64 codeAlignment uint64 dataAlignment int64 } // Instructions used to recreate the table from the .debug_frame data. const ( DW_CFA_nop = 0x0 // No ops DW_CFA_set_loc = 0x01 // op1: address DW_CFA_advance_loc1 = iota // op1: 1-bytes delta DW_CFA_advance_loc2 // op1: 2-byte delta DW_CFA_advance_loc4 // op1: 4-byte delta DW_CFA_offset_extended // op1: ULEB128 register, op2: ULEB128 offset DW_CFA_restore_extended // op1: ULEB128 register DW_CFA_undefined // op1: ULEB128 register DW_CFA_same_value // op1: ULEB128 register DW_CFA_register // op1: ULEB128 register, op2: ULEB128 register DW_CFA_remember_state // No ops DW_CFA_restore_state // No ops DW_CFA_def_cfa // op1: ULEB128 register, op2: ULEB128 offset DW_CFA_def_cfa_register // op1: ULEB128 register DW_CFA_def_cfa_offset // op1: ULEB128 offset DW_CFA_def_cfa_expression // op1: BLOCK DW_CFA_expression // op1: ULEB128 register, op2: BLOCK DW_CFA_offset_extended_sf // op1: ULEB128 register, op2: SLEB128 BLOCK DW_CFA_def_cfa_sf // op1: ULEB128 register, op2: SLEB128 offset DW_CFA_def_cfa_offset_sf // op1: SLEB128 offset DW_CFA_val_offset // op1: ULEB128, op2: ULEB128 DW_CFA_val_offset_sf // op1: ULEB128, op2: SLEB128 DW_CFA_val_expression // op1: ULEB128, op2: BLOCK DW_CFA_lo_user = 0x1c // op1: BLOCK DW_CFA_hi_user = 0x3f // op1: ULEB128 register, op2: BLOCK DW_CFA_advance_loc = (0x1 << 6) // High 2 bits: 0x1, low 6: delta DW_CFA_offset = (0x2 << 6) // High 2 bits: 0x2, low 6: register DW_CFA_restore = (0x3 << 6) // High 2 bits: 0x3, low 6: register ) // Rules defined for register values. type Rule byte const ( RuleUndefined Rule = iota RuleSameVal RuleOffset RuleValOffset RuleRegister RuleExpression RuleValExpression RuleArchitectural RuleCFA // Value is rule.Reg + rule.Offset RuleFramePointer // Value is stored at address rule.Reg + rule.Offset, but only if it's less than the current CFA, otherwise same value ) const low_6_offset = 0x3f type instruction func(frame *FrameContext) // // Mapping from DWARF opcode to function. var fnlookup = map[byte]instruction{ DW_CFA_advance_loc: advanceloc, DW_CFA_offset: offset, DW_CFA_restore: restore, DW_CFA_set_loc: setloc, DW_CFA_advance_loc1: advanceloc1, DW_CFA_advance_loc2: advanceloc2, DW_CFA_advance_loc4: advanceloc4, DW_CFA_offset_extended: offsetextended, DW_CFA_restore_extended: restoreextended, DW_CFA_undefined: undefined, DW_CFA_same_value: samevalue, DW_CFA_register: register, DW_CFA_remember_state: rememberstate, DW_CFA_restore_state: restorestate, DW_CFA_def_cfa: defcfa, DW_CFA_def_cfa_register: defcfaregister, DW_CFA_def_cfa_offset: defcfaoffset, DW_CFA_def_cfa_expression: defcfaexpression, DW_CFA_expression: expression, DW_CFA_offset_extended_sf: offsetextendedsf, DW_CFA_def_cfa_sf: defcfasf, DW_CFA_def_cfa_offset_sf: defcfaoffsetsf, DW_CFA_val_offset: valoffset, DW_CFA_val_offset_sf: valoffsetsf, DW_CFA_val_expression: valexpression, DW_CFA_lo_user: louser, DW_CFA_hi_user: hiuser, } func executeCIEInstructions(cie *CommonInformationEntry) *FrameContext { initialInstructions := make([]byte, len(cie.InitialInstructions)) copy(initialInstructions, cie.InitialInstructions) frame := &FrameContext{ cie: cie, Regs: make(map[uint64]DWRule), RetAddrReg: cie.ReturnAddressRegister, initialRegs: make(map[uint64]DWRule), prevRegs: make(map[uint64]DWRule), codeAlignment: cie.CodeAlignmentFactor, dataAlignment: cie.DataAlignmentFactor, buf: bytes.NewBuffer(initialInstructions), } frame.ExecuteDwarfProgram() return frame } // Unwind the stack to find the return address register. func executeDwarfProgramUntilPC(fde *FrameDescriptionEntry, pc uint64) *FrameContext { frame := executeCIEInstructions(fde.CIE) frame.order = fde.order frame.loc = fde.Begin() frame.address = pc frame.ExecuteUntilPC(fde.Instructions) return frame } func (frame *FrameContext) ExecuteDwarfProgram() { for frame.buf.Len() > 0 { executeDwarfInstruction(frame) } } // Execute dwarf instructions. func (frame *FrameContext) ExecuteUntilPC(instructions []byte) { frame.buf.Truncate(0) frame.buf.Write(instructions) // We only need to execute the instructions until // ctx.loc > ctx.address (which is the address we // are currently at in the traced process). for frame.address >= frame.loc && frame.buf.Len() > 0 { executeDwarfInstruction(frame) } } func executeDwarfInstruction(frame *FrameContext) { instruction, err := frame.buf.ReadByte() if err != nil { panic("Could not read from instruction buffer") } if instruction == DW_CFA_nop { return } fn := lookupFunc(instruction, frame.buf) fn(frame) } func lookupFunc(instruction byte, buf *bytes.Buffer) instruction { const high_2_bits = 0xc0 var restore bool // Special case the 3 opcodes that have their argument encoded in the opcode itself. switch instruction & high_2_bits { case DW_CFA_advance_loc: instruction = DW_CFA_advance_loc restore = true case DW_CFA_offset: instruction = DW_CFA_offset restore = true case DW_CFA_restore: instruction = DW_CFA_restore restore = true } if restore { // Restore the last byte as it actually contains the argument for the opcode. err := buf.UnreadByte() if err != nil { panic("Could not unread byte") } } fn, ok := fnlookup[instruction] if !ok { panic(fmt.Sprintf("Encountered an unexpected DWARF CFA opcode: %#v", instruction)) } return fn } func advanceloc(frame *FrameContext) { b, err := frame.buf.ReadByte() if err != nil { panic("Could not read byte") } delta := b & low_6_offset frame.loc += uint64(delta) * frame.codeAlignment } func advanceloc1(frame *FrameContext) { delta, err := frame.buf.ReadByte() if err != nil { panic("Could not read byte") } frame.loc += uint64(delta) * frame.codeAlignment } func advanceloc2(frame *FrameContext) { var delta uint16 binary.Read(frame.buf, frame.order, &delta) frame.loc += uint64(delta) * frame.codeAlignment } func advanceloc4(frame *FrameContext) { var delta uint32 binary.Read(frame.buf, frame.order, &delta) frame.loc += uint64(delta) * frame.codeAlignment } func offset(frame *FrameContext) { b, err := frame.buf.ReadByte() if err != nil { panic(err) } var ( reg = b & low_6_offset offset, _ = util.DecodeULEB128(frame.buf) ) frame.Regs[uint64(reg)] = DWRule{Offset: int64(offset) * frame.dataAlignment, Rule: RuleOffset} } func restore(frame *FrameContext) { b, err := frame.buf.ReadByte() if err != nil { panic(err) } reg := uint64(b & low_6_offset) oldrule, ok := frame.initialRegs[reg] if ok { frame.Regs[reg] = DWRule{Offset: oldrule.Offset, Rule: RuleOffset} } else { frame.Regs[reg] = DWRule{Rule: RuleUndefined} } } func setloc(frame *FrameContext) { var loc uint64 binary.Read(frame.buf, frame.order, &loc) frame.loc = loc + frame.cie.staticBase } func offsetextended(frame *FrameContext) { var ( reg, _ = util.DecodeULEB128(frame.buf) offset, _ = util.DecodeULEB128(frame.buf) ) frame.Regs[reg] = DWRule{Offset: int64(offset) * frame.dataAlignment, Rule: RuleOffset} } func undefined(frame *FrameContext) { reg, _ := util.DecodeULEB128(frame.buf) frame.Regs[reg] = DWRule{Rule: RuleUndefined} } func samevalue(frame *FrameContext) { reg, _ := util.DecodeULEB128(frame.buf) frame.Regs[reg] = DWRule{Rule: RuleSameVal} } func register(frame *FrameContext) { reg1, _ := util.DecodeULEB128(frame.buf) reg2, _ := util.DecodeULEB128(frame.buf) frame.Regs[reg1] = DWRule{Reg: reg2, Rule: RuleRegister} } func rememberstate(frame *FrameContext) { frame.prevRegs = frame.Regs } func restorestate(frame *FrameContext) { frame.Regs = frame.prevRegs } func restoreextended(frame *FrameContext) { reg, _ := util.DecodeULEB128(frame.buf) oldrule, ok := frame.initialRegs[reg] if ok { frame.Regs[reg] = DWRule{Offset: oldrule.Offset, Rule: RuleOffset} } else { frame.Regs[reg] = DWRule{Rule: RuleUndefined} } } func defcfa(frame *FrameContext) { reg, _ := util.DecodeULEB128(frame.buf) offset, _ := util.DecodeULEB128(frame.buf) frame.CFA.Rule = RuleCFA frame.CFA.Reg = reg frame.CFA.Offset = int64(offset) } func defcfaregister(frame *FrameContext) { reg, _ := util.DecodeULEB128(frame.buf) frame.CFA.Reg = reg } func defcfaoffset(frame *FrameContext) { offset, _ := util.DecodeULEB128(frame.buf) frame.CFA.Offset = int64(offset) } func defcfasf(frame *FrameContext) { reg, _ := util.DecodeULEB128(frame.buf) offset, _ := util.DecodeSLEB128(frame.buf) frame.CFA.Rule = RuleCFA frame.CFA.Reg = reg frame.CFA.Offset = offset * frame.dataAlignment } func defcfaoffsetsf(frame *FrameContext) { offset, _ := util.DecodeSLEB128(frame.buf) offset *= frame.dataAlignment frame.CFA.Offset = offset } func defcfaexpression(frame *FrameContext) { var ( l, _ = util.DecodeULEB128(frame.buf) expr = frame.buf.Next(int(l)) ) frame.CFA.Expression = expr frame.CFA.Rule = RuleExpression } func expression(frame *FrameContext) { var ( reg, _ = util.DecodeULEB128(frame.buf) l, _ = util.DecodeULEB128(frame.buf) expr = frame.buf.Next(int(l)) ) frame.Regs[reg] = DWRule{Rule: RuleExpression, Expression: expr} } func offsetextendedsf(frame *FrameContext) { var ( reg, _ = util.DecodeULEB128(frame.buf) offset, _ = util.DecodeSLEB128(frame.buf) ) frame.Regs[reg] = DWRule{Offset: offset * frame.dataAlignment, Rule: RuleOffset} } func valoffset(frame *FrameContext) { var ( reg, _ = util.DecodeULEB128(frame.buf) offset, _ = util.DecodeULEB128(frame.buf) ) frame.Regs[reg] = DWRule{Offset: int64(offset), Rule: RuleValOffset} } func valoffsetsf(frame *FrameContext) { var ( reg, _ = util.DecodeULEB128(frame.buf) offset, _ = util.DecodeSLEB128(frame.buf) ) frame.Regs[reg] = DWRule{Offset: offset * frame.dataAlignment, Rule: RuleValOffset} } func valexpression(frame *FrameContext) { var ( reg, _ = util.DecodeULEB128(frame.buf) l, _ = util.DecodeULEB128(frame.buf) expr = frame.buf.Next(int(l)) ) frame.Regs[reg] = DWRule{Rule: RuleValExpression, Expression: expr} } func louser(frame *FrameContext) { frame.buf.Next(1) } func hiuser(frame *FrameContext) { frame.buf.Next(1) }