src/cmd/internal/obj/dwarf.go - go - Git at Google

 // Copyright 2019 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Writes dwarf information to object files.

 package obj

 import (
 	"cmd/internal/dwarf"
 	"cmd/internal/src"
 	"fmt"
 )

 // Generate a sequence of opcodes that is as short as possible.
 // See section 6.2.5
 const (
 	LINE_BASE   = -4
 	LINE_RANGE  = 10
 	PC_RANGE    = (255 - OPCODE_BASE) / LINE_RANGE
 	OPCODE_BASE = 11
 )

 // generateDebugLinesSymbol fills the debug lines symbol of a given function.
 //
 // It's worth noting that this function doesn't generate the full debug_lines
 // DWARF section, saving that for the linker. This function just generates the
 // state machine part of debug_lines. The full table is generated by the
 // linker.  Also, we use the file numbers from the full package (not just the
 // function in question) when generating the state machine. We do this so we
 // don't have to do a fixup on the indices when writing the full section.
 func (ctxt *Link) generateDebugLinesSymbol(s, lines *LSym) {
 	dctxt := dwCtxt{ctxt}

 	// The Pcfile table is used to generate the debug_lines section, and the file
 	// indices for that data could differ from the files we write out for the
 	// debug_lines section. Here we generate a LUT between those two indices.
 	fileNums := make(map[int32]int64)
 	for i, filename := range s.Func.Pcln.File {
 		if symbolIndex := ctxt.PosTable.FileIndex(filename); symbolIndex >= 0 {
 			fileNums[int32(i)] = int64(symbolIndex) + 1
 		} else {
 			panic(fmt.Sprintf("First time we've seen filename: %q", filename))
 		}
 	}

 	// Set up the debug_lines state machine.
 	// NB: This state machine is reset to this state when we've finished
 	// generating the line table. See below.
 	// TODO: Once delve can support multiple DW_LNS_end_statements, we don't have
 	// to do this.
 	stmt := true
 	line := int64(1)
 	pc := s.Func.Text.Pc
 	name := ""
 	prologue, wrotePrologue := false, false
 	// Walk the progs, generating the DWARF table.
 	for p := s.Func.Text; p != nil; p = p.Link {
 		prologue = prologue || (p.Pos.Xlogue() == src.PosPrologueEnd)
 		// If we're not at a real instruction, keep looping!
 		if p.Pos.Line() == 0 || (p.Link != nil && p.Link.Pc == p.Pc) {
 			continue
 		}
 		newStmt := p.Pos.IsStmt() != src.PosNotStmt
 		newName, newLine := linkgetlineFromPos(ctxt, p.Pos)

 		// Output debug info.
 		wrote := false
 		if name != newName {
 			newFile := ctxt.PosTable.FileIndex(newName) + 1 // 1 indexing for the table.
 			dctxt.AddUint8(lines, dwarf.DW_LNS_set_file)
 			dwarf.Uleb128put(dctxt, lines, int64(newFile))
 			name = newName
 			wrote = true
 		}
 		if prologue && !wrotePrologue {
 			dctxt.AddUint8(lines, uint8(dwarf.DW_LNS_set_prologue_end))
 			wrotePrologue = true
 			wrote = true
 		}
 		if stmt != newStmt {
 			dctxt.AddUint8(lines, uint8(dwarf.DW_LNS_negate_stmt))
 			stmt = newStmt
 			wrote = true
 		}

 		if line != int64(newLine) || wrote {
 			pcdelta := p.Pc - pc
 			putpclcdelta(ctxt, dctxt, lines, uint64(pcdelta), int64(newLine)-line)
 			line, pc = int64(newLine), p.Pc
 		}
 	}

 	// Because these symbols will be concatenated together by the linker, we need
 	// to reset the state machine that controls the debug symbols. The fields in
 	// the state machine that need to be reset are:
 	//   file = 1
 	//   line = 1
 	//   column = 0
 	//   stmt = set in header, we assume true
 	//   basic_block = false
 	// Careful readers of the DWARF specification will note that we don't reset
 	// the address of the state machine -- but this will happen at the beginning
 	// of the NEXT block of opcodes.
 	dctxt.AddUint8(lines, dwarf.DW_LNS_set_file)
 	dwarf.Uleb128put(dctxt, lines, 1)
 	dctxt.AddUint8(lines, dwarf.DW_LNS_advance_line)
 	dwarf.Sleb128put(dctxt, lines, int64(1-line))
 	if !stmt {
 		dctxt.AddUint8(lines, dwarf.DW_LNS_negate_stmt)
 	}
 	dctxt.AddUint8(lines, dwarf.DW_LNS_copy)
 }

 func putpclcdelta(linkctxt *Link, dctxt dwCtxt, s *LSym, deltaPC uint64, deltaLC int64) {
 	// Choose a special opcode that minimizes the number of bytes needed to
 	// encode the remaining PC delta and LC delta.
 	var opcode int64
 	if deltaLC < LINE_BASE {
 		if deltaPC >= PC_RANGE {
 			opcode = OPCODE_BASE + (LINE_RANGE * PC_RANGE)
 		} else {
 			opcode = OPCODE_BASE + (LINE_RANGE * int64(deltaPC))
 		}
 	} else if deltaLC < LINE_BASE+LINE_RANGE {
 		if deltaPC >= PC_RANGE {
 			opcode = OPCODE_BASE + (deltaLC - LINE_BASE) + (LINE_RANGE * PC_RANGE)
 			if opcode > 255 {
 				opcode -= LINE_RANGE
 			}
 		} else {
 			opcode = OPCODE_BASE + (deltaLC - LINE_BASE) + (LINE_RANGE * int64(deltaPC))
 		}
 	} else {
 		if deltaPC <= PC_RANGE {
 			opcode = OPCODE_BASE + (LINE_RANGE - 1) + (LINE_RANGE * int64(deltaPC))
 			if opcode > 255 {
 				opcode = 255
 			}
 		} else {
 			// Use opcode 249 (pc+=23, lc+=5) or 255 (pc+=24, lc+=1).
 			//
 			// Let x=deltaPC-PC_RANGE.  If we use opcode 255, x will be the remaining
 			// deltaPC that we need to encode separately before emitting 255.  If we
 			// use opcode 249, we will need to encode x+1.  If x+1 takes one more
 			// byte to encode than x, then we use opcode 255.
 			//
 			// In all other cases x and x+1 take the same number of bytes to encode,
 			// so we use opcode 249, which may save us a byte in encoding deltaLC,
 			// for similar reasons.
 			switch deltaPC - PC_RANGE {
 			// PC_RANGE is the largest deltaPC we can encode in one byte, using
 			// DW_LNS_const_add_pc.
 			//
 			// (1<<16)-1 is the largest deltaPC we can encode in three bytes, using
 			// DW_LNS_fixed_advance_pc.
 			//
 			// (1<<(7n))-1 is the largest deltaPC we can encode in n+1 bytes for
 			// n=1,3,4,5,..., using DW_LNS_advance_pc.
 			case PC_RANGE, (1 << 7) - 1, (1 << 16) - 1, (1 << 21) - 1, (1 << 28) - 1,
 				(1 << 35) - 1, (1 << 42) - 1, (1 << 49) - 1, (1 << 56) - 1, (1 << 63) - 1:
 				opcode = 255
 			default:
 				opcode = OPCODE_BASE + LINE_RANGE*PC_RANGE - 1 // 249
 			}
 		}
 	}
 	if opcode < OPCODE_BASE || opcode > 255 {
 		panic(fmt.Sprintf("produced invalid special opcode %d", opcode))
 	}

 	// Subtract from deltaPC and deltaLC the amounts that the opcode will add.
 	deltaPC -= uint64((opcode - OPCODE_BASE) / LINE_RANGE)
 	deltaLC -= (opcode-OPCODE_BASE)%LINE_RANGE + LINE_BASE

 	// Encode deltaPC.
 	if deltaPC != 0 {
 		if deltaPC <= PC_RANGE {
 			// Adjust the opcode so that we can use the 1-byte DW_LNS_const_add_pc
 			// instruction.
 			opcode -= LINE_RANGE * int64(PC_RANGE-deltaPC)
 			if opcode < OPCODE_BASE {
 				panic(fmt.Sprintf("produced invalid special opcode %d", opcode))
 			}
 			dctxt.AddUint8(s, dwarf.DW_LNS_const_add_pc)
 		} else if (1<<14) <= deltaPC && deltaPC < (1<<16) {
 			dctxt.AddUint8(s, dwarf.DW_LNS_fixed_advance_pc)
 			dctxt.AddUint16(s, uint16(deltaPC))
 		} else {
 			dctxt.AddUint8(s, dwarf.DW_LNS_advance_pc)
 			dwarf.Uleb128put(dctxt, s, int64(deltaPC))
 		}
 	}

 	// Encode deltaLC.
 	if deltaLC != 0 {
 		dctxt.AddUint8(s, dwarf.DW_LNS_advance_line)
 		dwarf.Sleb128put(dctxt, s, deltaLC)
 	}

 	// Output the special opcode.
 	dctxt.AddUint8(s, uint8(opcode))
 }
	// Copyright 2019 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Writes dwarf information to object files.

	package obj

	import (
	"cmd/internal/dwarf"
	"cmd/internal/src"
	"fmt"
	)

	// Generate a sequence of opcodes that is as short as possible.
	// See section 6.2.5
	const (
	LINE_BASE = -4
	LINE_RANGE = 10
	PC_RANGE = (255 - OPCODE_BASE) / LINE_RANGE
	OPCODE_BASE = 11
	)

	// generateDebugLinesSymbol fills the debug lines symbol of a given function.
	//
	// It's worth noting that this function doesn't generate the full debug_lines
	// DWARF section, saving that for the linker. This function just generates the
	// state machine part of debug_lines. The full table is generated by the
	// linker. Also, we use the file numbers from the full package (not just the
	// function in question) when generating the state machine. We do this so we
	// don't have to do a fixup on the indices when writing the full section.
	func (ctxt Link) generateDebugLinesSymbol(s, lines LSym) {
	dctxt := dwCtxt{ctxt}

	// The Pcfile table is used to generate the debug_lines section, and the file
	// indices for that data could differ from the files we write out for the
	// debug_lines section. Here we generate a LUT between those two indices.
	fileNums := make(map[int32]int64)
	for i, filename := range s.Func.Pcln.File {
	if symbolIndex := ctxt.PosTable.FileIndex(filename); symbolIndex >= 0 {
	fileNums[int32(i)] = int64(symbolIndex) + 1
	} else {
	panic(fmt.Sprintf("First time we've seen filename: %q", filename))
	}
	}

	// Set up the debug_lines state machine.
	// NB: This state machine is reset to this state when we've finished
	// generating the line table. See below.
	// TODO: Once delve can support multiple DW_LNS_end_statements, we don't have
	// to do this.
	stmt := true
	line := int64(1)
	pc := s.Func.Text.Pc
	name := ""
	prologue, wrotePrologue := false, false
	// Walk the progs, generating the DWARF table.
	for p := s.Func.Text; p != nil; p = p.Link {
	prologue = prologue \|\| (p.Pos.Xlogue() == src.PosPrologueEnd)
	// If we're not at a real instruction, keep looping!
	if p.Pos.Line() == 0 \|\| (p.Link != nil && p.Link.Pc == p.Pc) {
	continue
	}
	newStmt := p.Pos.IsStmt() != src.PosNotStmt
	newName, newLine := linkgetlineFromPos(ctxt, p.Pos)

	// Output debug info.
	wrote := false
	if name != newName {
	newFile := ctxt.PosTable.FileIndex(newName) + 1 // 1 indexing for the table.
	dctxt.AddUint8(lines, dwarf.DW_LNS_set_file)
	dwarf.Uleb128put(dctxt, lines, int64(newFile))
	name = newName
	wrote = true
	}
	if prologue && !wrotePrologue {
	dctxt.AddUint8(lines, uint8(dwarf.DW_LNS_set_prologue_end))
	wrotePrologue = true
	wrote = true
	}
	if stmt != newStmt {
	dctxt.AddUint8(lines, uint8(dwarf.DW_LNS_negate_stmt))
	stmt = newStmt
	wrote = true
	}

	if line != int64(newLine) \|\| wrote {
	pcdelta := p.Pc - pc
	putpclcdelta(ctxt, dctxt, lines, uint64(pcdelta), int64(newLine)-line)
	line, pc = int64(newLine), p.Pc
	}
	}

	// Because these symbols will be concatenated together by the linker, we need
	// to reset the state machine that controls the debug symbols. The fields in
	// the state machine that need to be reset are:
	// file = 1
	// line = 1
	// column = 0
	// stmt = set in header, we assume true
	// basic_block = false
	// Careful readers of the DWARF specification will note that we don't reset
	// the address of the state machine -- but this will happen at the beginning
	// of the NEXT block of opcodes.
	dctxt.AddUint8(lines, dwarf.DW_LNS_set_file)
	dwarf.Uleb128put(dctxt, lines, 1)
	dctxt.AddUint8(lines, dwarf.DW_LNS_advance_line)
	dwarf.Sleb128put(dctxt, lines, int64(1-line))
	if !stmt {
	dctxt.AddUint8(lines, dwarf.DW_LNS_negate_stmt)
	}
	dctxt.AddUint8(lines, dwarf.DW_LNS_copy)
	}

	func putpclcdelta(linkctxt Link, dctxt dwCtxt, s LSym, deltaPC uint64, deltaLC int64) {
	// Choose a special opcode that minimizes the number of bytes needed to
	// encode the remaining PC delta and LC delta.
	var opcode int64
	if deltaLC < LINE_BASE {
	if deltaPC >= PC_RANGE {
	opcode = OPCODE_BASE + (LINE_RANGE * PC_RANGE)
	} else {
	opcode = OPCODE_BASE + (LINE_RANGE * int64(deltaPC))
	}
	} else if deltaLC < LINE_BASE+LINE_RANGE {
	if deltaPC >= PC_RANGE {
	opcode = OPCODE_BASE + (deltaLC - LINE_BASE) + (LINE_RANGE * PC_RANGE)
	if opcode > 255 {
	opcode -= LINE_RANGE
	}
	} else {
	opcode = OPCODE_BASE + (deltaLC - LINE_BASE) + (LINE_RANGE * int64(deltaPC))
	}
	} else {
	if deltaPC <= PC_RANGE {
	opcode = OPCODE_BASE + (LINE_RANGE - 1) + (LINE_RANGE * int64(deltaPC))
	if opcode > 255 {
	opcode = 255
	}
	} else {
	// Use opcode 249 (pc+=23, lc+=5) or 255 (pc+=24, lc+=1).
	//
	// Let x=deltaPC-PC_RANGE. If we use opcode 255, x will be the remaining
	// deltaPC that we need to encode separately before emitting 255. If we
	// use opcode 249, we will need to encode x+1. If x+1 takes one more
	// byte to encode than x, then we use opcode 255.
	//
	// In all other cases x and x+1 take the same number of bytes to encode,
	// so we use opcode 249, which may save us a byte in encoding deltaLC,
	// for similar reasons.
	switch deltaPC - PC_RANGE {
	// PC_RANGE is the largest deltaPC we can encode in one byte, using
	// DW_LNS_const_add_pc.
	//
	// (1<<16)-1 is the largest deltaPC we can encode in three bytes, using
	// DW_LNS_fixed_advance_pc.
	//
	// (1<<(7n))-1 is the largest deltaPC we can encode in n+1 bytes for
	// n=1,3,4,5,..., using DW_LNS_advance_pc.
	case PC_RANGE, (1 << 7) - 1, (1 << 16) - 1, (1 << 21) - 1, (1 << 28) - 1,
	(1 << 35) - 1, (1 << 42) - 1, (1 << 49) - 1, (1 << 56) - 1, (1 << 63) - 1:
	opcode = 255
	default:
	opcode = OPCODE_BASE + LINE_RANGE*PC_RANGE - 1 // 249
	}
	}
	}
	if opcode < OPCODE_BASE \|\| opcode > 255 {
	panic(fmt.Sprintf("produced invalid special opcode %d", opcode))
	}

	// Subtract from deltaPC and deltaLC the amounts that the opcode will add.
	deltaPC -= uint64((opcode - OPCODE_BASE) / LINE_RANGE)
	deltaLC -= (opcode-OPCODE_BASE)%LINE_RANGE + LINE_BASE

	// Encode deltaPC.
	if deltaPC != 0 {
	if deltaPC <= PC_RANGE {
	// Adjust the opcode so that we can use the 1-byte DW_LNS_const_add_pc
	// instruction.
	opcode -= LINE_RANGE * int64(PC_RANGE-deltaPC)
	if opcode < OPCODE_BASE {
	panic(fmt.Sprintf("produced invalid special opcode %d", opcode))
	}
	dctxt.AddUint8(s, dwarf.DW_LNS_const_add_pc)
	} else if (1<<14) <= deltaPC && deltaPC < (1<<16) {
	dctxt.AddUint8(s, dwarf.DW_LNS_fixed_advance_pc)
	dctxt.AddUint16(s, uint16(deltaPC))
	} else {
	dctxt.AddUint8(s, dwarf.DW_LNS_advance_pc)
	dwarf.Uleb128put(dctxt, s, int64(deltaPC))
	}
	}

	// Encode deltaLC.
	if deltaLC != 0 {
	dctxt.AddUint8(s, dwarf.DW_LNS_advance_line)
	dwarf.Sleb128put(dctxt, s, deltaLC)
	}

	// Output the special opcode.
	dctxt.AddUint8(s, uint8(opcode))
	}