mirror of
https://github.com/autc04/Retro68.git
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454 lines
12 KiB
Go
454 lines
12 KiB
Go
// Copyright 2009 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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/*
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* Line tables
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*/
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package gosym
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import (
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"encoding/binary"
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"sync"
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)
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// A LineTable is a data structure mapping program counters to line numbers.
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//
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// In Go 1.1 and earlier, each function (represented by a Func) had its own LineTable,
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// and the line number corresponded to a numbering of all source lines in the
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// program, across all files. That absolute line number would then have to be
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// converted separately to a file name and line number within the file.
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//
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// In Go 1.2, the format of the data changed so that there is a single LineTable
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// for the entire program, shared by all Funcs, and there are no absolute line
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// numbers, just line numbers within specific files.
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//
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// For the most part, LineTable's methods should be treated as an internal
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// detail of the package; callers should use the methods on Table instead.
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type LineTable struct {
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Data []byte
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PC uint64
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Line int
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// Go 1.2 state
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mu sync.Mutex
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go12 int // is this in Go 1.2 format? -1 no, 0 unknown, 1 yes
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binary binary.ByteOrder
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quantum uint32
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ptrsize uint32
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functab []byte
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nfunctab uint32
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filetab []byte
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nfiletab uint32
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fileMap map[string]uint32
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}
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// NOTE(rsc): This is wrong for GOARCH=arm, which uses a quantum of 4,
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// but we have no idea whether we're using arm or not. This only
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// matters in the old (pre-Go 1.2) symbol table format, so it's not worth
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// fixing.
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const oldQuantum = 1
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func (t *LineTable) parse(targetPC uint64, targetLine int) (b []byte, pc uint64, line int) {
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// The PC/line table can be thought of as a sequence of
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// <pc update>* <line update>
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// batches. Each update batch results in a (pc, line) pair,
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// where line applies to every PC from pc up to but not
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// including the pc of the next pair.
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//
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// Here we process each update individually, which simplifies
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// the code, but makes the corner cases more confusing.
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b, pc, line = t.Data, t.PC, t.Line
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for pc <= targetPC && line != targetLine && len(b) > 0 {
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code := b[0]
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b = b[1:]
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switch {
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case code == 0:
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if len(b) < 4 {
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b = b[0:0]
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break
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}
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val := binary.BigEndian.Uint32(b)
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b = b[4:]
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line += int(val)
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case code <= 64:
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line += int(code)
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case code <= 128:
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line -= int(code - 64)
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default:
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pc += oldQuantum * uint64(code-128)
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continue
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}
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pc += oldQuantum
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}
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return b, pc, line
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}
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func (t *LineTable) slice(pc uint64) *LineTable {
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data, pc, line := t.parse(pc, -1)
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return &LineTable{Data: data, PC: pc, Line: line}
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}
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// PCToLine returns the line number for the given program counter.
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// Callers should use Table's PCToLine method instead.
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func (t *LineTable) PCToLine(pc uint64) int {
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if t.isGo12() {
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return t.go12PCToLine(pc)
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}
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_, _, line := t.parse(pc, -1)
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return line
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}
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// LineToPC returns the program counter for the given line number,
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// considering only program counters before maxpc.
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// Callers should use Table's LineToPC method instead.
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func (t *LineTable) LineToPC(line int, maxpc uint64) uint64 {
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if t.isGo12() {
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return 0
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}
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_, pc, line1 := t.parse(maxpc, line)
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if line1 != line {
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return 0
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}
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// Subtract quantum from PC to account for post-line increment
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return pc - oldQuantum
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}
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// NewLineTable returns a new PC/line table
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// corresponding to the encoded data.
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// Text must be the start address of the
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// corresponding text segment.
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func NewLineTable(data []byte, text uint64) *LineTable {
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return &LineTable{Data: data, PC: text, Line: 0}
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}
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// Go 1.2 symbol table format.
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// See golang.org/s/go12symtab.
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//
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// A general note about the methods here: rather than try to avoid
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// index out of bounds errors, we trust Go to detect them, and then
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// we recover from the panics and treat them as indicative of a malformed
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// or incomplete table.
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//
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// The methods called by symtab.go, which begin with "go12" prefixes,
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// are expected to have that recovery logic.
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// isGo12 reports whether this is a Go 1.2 (or later) symbol table.
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func (t *LineTable) isGo12() bool {
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t.go12Init()
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return t.go12 == 1
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}
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const go12magic = 0xfffffffb
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// uintptr returns the pointer-sized value encoded at b.
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// The pointer size is dictated by the table being read.
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func (t *LineTable) uintptr(b []byte) uint64 {
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if t.ptrsize == 4 {
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return uint64(t.binary.Uint32(b))
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}
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return t.binary.Uint64(b)
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}
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// go12init initializes the Go 1.2 metadata if t is a Go 1.2 symbol table.
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func (t *LineTable) go12Init() {
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t.mu.Lock()
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defer t.mu.Unlock()
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if t.go12 != 0 {
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return
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}
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defer func() {
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// If we panic parsing, assume it's not a Go 1.2 symbol table.
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recover()
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}()
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// Check header: 4-byte magic, two zeros, pc quantum, pointer size.
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t.go12 = -1 // not Go 1.2 until proven otherwise
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if len(t.Data) < 16 || t.Data[4] != 0 || t.Data[5] != 0 ||
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(t.Data[6] != 1 && t.Data[6] != 4) || // pc quantum
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(t.Data[7] != 4 && t.Data[7] != 8) { // pointer size
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return
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}
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switch uint32(go12magic) {
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case binary.LittleEndian.Uint32(t.Data):
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t.binary = binary.LittleEndian
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case binary.BigEndian.Uint32(t.Data):
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t.binary = binary.BigEndian
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default:
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return
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}
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t.quantum = uint32(t.Data[6])
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t.ptrsize = uint32(t.Data[7])
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t.nfunctab = uint32(t.uintptr(t.Data[8:]))
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t.functab = t.Data[8+t.ptrsize:]
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functabsize := t.nfunctab*2*t.ptrsize + t.ptrsize
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fileoff := t.binary.Uint32(t.functab[functabsize:])
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t.functab = t.functab[:functabsize]
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t.filetab = t.Data[fileoff:]
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t.nfiletab = t.binary.Uint32(t.filetab)
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t.filetab = t.filetab[:t.nfiletab*4]
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t.go12 = 1 // so far so good
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}
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// go12Funcs returns a slice of Funcs derived from the Go 1.2 pcln table.
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func (t *LineTable) go12Funcs() []Func {
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// Assume it is malformed and return nil on error.
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defer func() {
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recover()
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}()
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n := len(t.functab) / int(t.ptrsize) / 2
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funcs := make([]Func, n)
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for i := range funcs {
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f := &funcs[i]
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f.Entry = uint64(t.uintptr(t.functab[2*i*int(t.ptrsize):]))
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f.End = uint64(t.uintptr(t.functab[(2*i+2)*int(t.ptrsize):]))
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info := t.Data[t.uintptr(t.functab[(2*i+1)*int(t.ptrsize):]):]
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f.LineTable = t
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f.FrameSize = int(t.binary.Uint32(info[t.ptrsize+2*4:]))
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f.Sym = &Sym{
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Value: f.Entry,
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Type: 'T',
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Name: t.string(t.binary.Uint32(info[t.ptrsize:])),
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GoType: 0,
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Func: f,
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}
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}
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return funcs
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}
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// findFunc returns the func corresponding to the given program counter.
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func (t *LineTable) findFunc(pc uint64) []byte {
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if pc < t.uintptr(t.functab) || pc >= t.uintptr(t.functab[len(t.functab)-int(t.ptrsize):]) {
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return nil
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}
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// The function table is a list of 2*nfunctab+1 uintptrs,
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// alternating program counters and offsets to func structures.
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f := t.functab
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nf := t.nfunctab
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for nf > 0 {
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m := nf / 2
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fm := f[2*t.ptrsize*m:]
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if t.uintptr(fm) <= pc && pc < t.uintptr(fm[2*t.ptrsize:]) {
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return t.Data[t.uintptr(fm[t.ptrsize:]):]
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} else if pc < t.uintptr(fm) {
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nf = m
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} else {
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f = f[(m+1)*2*t.ptrsize:]
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nf -= m + 1
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}
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}
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return nil
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}
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// readvarint reads, removes, and returns a varint from *pp.
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func (t *LineTable) readvarint(pp *[]byte) uint32 {
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var v, shift uint32
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p := *pp
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for shift = 0; ; shift += 7 {
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b := p[0]
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p = p[1:]
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v |= (uint32(b) & 0x7F) << shift
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if b&0x80 == 0 {
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break
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}
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}
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*pp = p
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return v
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}
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// string returns a Go string found at off.
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func (t *LineTable) string(off uint32) string {
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for i := off; ; i++ {
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if t.Data[i] == 0 {
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return string(t.Data[off:i])
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}
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}
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}
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// step advances to the next pc, value pair in the encoded table.
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func (t *LineTable) step(p *[]byte, pc *uint64, val *int32, first bool) bool {
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uvdelta := t.readvarint(p)
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if uvdelta == 0 && !first {
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return false
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}
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if uvdelta&1 != 0 {
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uvdelta = ^(uvdelta >> 1)
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} else {
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uvdelta >>= 1
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}
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vdelta := int32(uvdelta)
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pcdelta := t.readvarint(p) * t.quantum
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*pc += uint64(pcdelta)
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*val += vdelta
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return true
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}
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// pcvalue reports the value associated with the target pc.
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// off is the offset to the beginning of the pc-value table,
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// and entry is the start PC for the corresponding function.
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func (t *LineTable) pcvalue(off uint32, entry, targetpc uint64) int32 {
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if off == 0 {
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return -1
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}
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p := t.Data[off:]
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val := int32(-1)
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pc := entry
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for t.step(&p, &pc, &val, pc == entry) {
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if targetpc < pc {
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return val
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}
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}
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return -1
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}
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// findFileLine scans one function in the binary looking for a
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// program counter in the given file on the given line.
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// It does so by running the pc-value tables mapping program counter
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// to file number. Since most functions come from a single file, these
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// are usually short and quick to scan. If a file match is found, then the
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// code goes to the expense of looking for a simultaneous line number match.
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func (t *LineTable) findFileLine(entry uint64, filetab, linetab uint32, filenum, line int32) uint64 {
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if filetab == 0 || linetab == 0 {
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return 0
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}
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fp := t.Data[filetab:]
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fl := t.Data[linetab:]
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fileVal := int32(-1)
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filePC := entry
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lineVal := int32(-1)
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linePC := entry
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fileStartPC := filePC
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for t.step(&fp, &filePC, &fileVal, filePC == entry) {
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if fileVal == filenum && fileStartPC < filePC {
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// fileVal is in effect starting at fileStartPC up to
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// but not including filePC, and it's the file we want.
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// Run the PC table looking for a matching line number
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// or until we reach filePC.
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lineStartPC := linePC
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for linePC < filePC && t.step(&fl, &linePC, &lineVal, linePC == entry) {
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// lineVal is in effect until linePC, and lineStartPC < filePC.
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if lineVal == line {
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if fileStartPC <= lineStartPC {
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return lineStartPC
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}
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if fileStartPC < linePC {
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return fileStartPC
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}
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}
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lineStartPC = linePC
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}
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}
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fileStartPC = filePC
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}
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return 0
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}
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// go12PCToLine maps program counter to line number for the Go 1.2 pcln table.
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func (t *LineTable) go12PCToLine(pc uint64) (line int) {
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defer func() {
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if recover() != nil {
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line = -1
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}
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}()
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f := t.findFunc(pc)
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if f == nil {
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return -1
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}
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entry := t.uintptr(f)
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linetab := t.binary.Uint32(f[t.ptrsize+5*4:])
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return int(t.pcvalue(linetab, entry, pc))
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}
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// go12PCToFile maps program counter to file name for the Go 1.2 pcln table.
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func (t *LineTable) go12PCToFile(pc uint64) (file string) {
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defer func() {
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if recover() != nil {
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file = ""
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}
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}()
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f := t.findFunc(pc)
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if f == nil {
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return ""
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}
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entry := t.uintptr(f)
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filetab := t.binary.Uint32(f[t.ptrsize+4*4:])
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fno := t.pcvalue(filetab, entry, pc)
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if fno <= 0 {
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return ""
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}
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return t.string(t.binary.Uint32(t.filetab[4*fno:]))
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}
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// go12LineToPC maps a (file, line) pair to a program counter for the Go 1.2 pcln table.
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func (t *LineTable) go12LineToPC(file string, line int) (pc uint64) {
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defer func() {
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if recover() != nil {
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pc = 0
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}
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}()
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t.initFileMap()
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filenum := t.fileMap[file]
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if filenum == 0 {
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return 0
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}
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// Scan all functions.
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// If this turns out to be a bottleneck, we could build a map[int32][]int32
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// mapping file number to a list of functions with code from that file.
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for i := uint32(0); i < t.nfunctab; i++ {
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f := t.Data[t.uintptr(t.functab[2*t.ptrsize*i+t.ptrsize:]):]
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entry := t.uintptr(f)
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filetab := t.binary.Uint32(f[t.ptrsize+4*4:])
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linetab := t.binary.Uint32(f[t.ptrsize+5*4:])
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pc := t.findFileLine(entry, filetab, linetab, int32(filenum), int32(line))
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if pc != 0 {
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return pc
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}
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}
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return 0
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}
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// initFileMap initializes the map from file name to file number.
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func (t *LineTable) initFileMap() {
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t.mu.Lock()
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defer t.mu.Unlock()
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if t.fileMap != nil {
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return
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}
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m := make(map[string]uint32)
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for i := uint32(1); i < t.nfiletab; i++ {
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s := t.string(t.binary.Uint32(t.filetab[4*i:]))
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m[s] = i
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}
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t.fileMap = m
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}
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// go12MapFiles adds to m a key for every file in the Go 1.2 LineTable.
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// Every key maps to obj. That's not a very interesting map, but it provides
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// a way for callers to obtain the list of files in the program.
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func (t *LineTable) go12MapFiles(m map[string]*Obj, obj *Obj) {
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defer func() {
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recover()
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}()
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t.initFileMap()
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for file := range t.fileMap {
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m[file] = obj
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}
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}
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